TEMS Investigation 11.0 IEs and Events
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TEMS™ Investigation 11.0 Information Elements and Events This manual is provided by Ascom Network Testing AB without any kind of warranty. Improvements and changes in this description due to typographical errors or inaccuracies in current information, or improvements to programs and/or equipment may be made by Ascom Network Testing AB at any time without notice. These changes will, however, be incorporated into new editions of this manual. No part of this publication may be reproduced, transmitted, stored in a retrieval system, nor translated into any human or computer language, in any form or by any means, electronic, mechanical, magnetic, optical, chemical, manual or otherwise, without the prior written permission of the copyrighted owner, Ascom Network Testing AB. TEMS is a trademark of Ascom. All other trademarks are the property of their respective holders. © Ascom 2010. All rights reserved. Publication number: LZT 138 0375 R1A Contents Contents 1. General 1 1.1. What’s In This Manual. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.2. Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2. Information Element Categories 3. Information Elements 2 4 3.1. GSM Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.2. WCDMA Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 3.3. LTE Information Elements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 3.4. TD-SCDMA Information Elements . . . . . . . . . . . . . . . . . . . . . . . . 130 3.5. CDMA Information Elements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146 3.6. iDEN Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178 3.7. WiMAX Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . 179 3.8. Data Service Testing Information Elements . . . . . . . . . . . . . . . . . 187 3.9. Uplink (MTR) Information Elements . . . . . . . . . . . . . . . . . . . . . . . 191 4. Information Element Support in Phones and Scanners 194 4.1. CDMA Information Elements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 194 4.2. GSM Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 195 4.3. WCDMA Information Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . 202 4.4. LTE Information Elements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 208 5. Notes on Plain-text Decoding of Mode Reports 209 5.1. TPC Info per Cell (Sony Ericsson) . . . . . . . . . . . . . . . . . . . . . . . . 209 LZT 138 0375 R1A i TEMS Investigation 11.0: Information Elements and Events 6. Predefined Events 210 210 212 231 236 237 6.1. General Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2. GSM/WCDMA/LTE/TD-SCDMA Events . . . . . . . . . . . . . . . . . . . . 6.3. CDMA Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.1. Algorithm for Pilot Pollution and Missing Neighbor Detection in CDMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.4. Data Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. Overview of Preconfigured Presentation Windows 239 239 239 239 240 241 241 242 242 242 244 244 244 244 245 245 245 246 246 247 247 248 248 250 250 250 250 251 251 251 7.1. Preconfigured Status Windows. . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.1. CDMA Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.1.1. Data Service Status Windows. . . . . . . . . . . . . . . . . 7.1.1.2. Other Status Windows . . . . . . . . . . . . . . . . . . . . . . 7.1.2. GSM Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.2.1. Data Service Status Windows. . . . . . . . . . . . . . . . . 7.1.2.2. Interference Status Windows . . . . . . . . . . . . . . . . . 7.1.2.3. Uplink Status Windows . . . . . . . . . . . . . . . . . . . . . . 7.1.2.4. Other GSM Status Windows . . . . . . . . . . . . . . . . . . 7.1.3. iDEN Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.4. LTE Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.4.1. Scanning Status Windows . . . . . . . . . . . . . . . . . . . 7.1.4.2. Other LTE Status Windows. . . . . . . . . . . . . . . . . . . 7.1.5. TD-SCDMA Status Windows . . . . . . . . . . . . . . . . . . . . . . . 7.1.5.1. Data Service Status Windows. . . . . . . . . . . . . . . . . 7.1.5.2. Scanning Status Windows . . . . . . . . . . . . . . . . . . . 7.1.5.3. TD-SCDMA Physical Channel Monitor . . . . . . . . . . 7.1.5.4. Other TD-SCDMA Status Windows . . . . . . . . . . . . 7.1.6. WCDMA Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.6.1. Data Service Status Windows. . . . . . . . . . . . . . . . . 7.1.6.2. Scanning Status Windows . . . . . . . . . . . . . . . . . . . 7.1.6.3. Other WCDMA Status Windows . . . . . . . . . . . . . . . 7.1.7. WiMAX Status Windows . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2. Preconfigured Event Counter Windows . . . . . . . . . . . . . . . . . . . . 7.3. Preconfigured Message Windows . . . . . . . . . . . . . . . . . . . . . . . . 7.3.1. Analysis Message Windows . . . . . . . . . . . . . . . . . . . . . . . 7.3.2. GSM Uplink Data Message Windows . . . . . . . . . . . . . . . . 7.3.3. iDEN Message Windows . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3.4. Signaling Message Windows . . . . . . . . . . . . . . . . . . . . . . . ii Contents 7.4. Video Monitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253 7.5. Preconfigured Line Charts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253 7.5.1. CDMA Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253 7.5.2. GSM Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253 7.5.3. iDEN Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 7.5.4. LTE Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 7.5.5. TD-SCDMA Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . 255 7.5.6. WCDMA Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 255 7.5.7. WiMAX Line Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256 7.6. Preconfigured Bar Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 257 7.6.1. CDMA Bar Charts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 257 7.6.2. GSM Bar Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 257 7.6.3. LTE Bar Charts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 258 7.6.4. TD-SCDMA Bar Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . 259 7.6.5. WCDMA Bar Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 259 7.6.6. WiMAX Bar Charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260 7.7. Preconfigured Maps . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261 7.8. GPS Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261 7.9. Presentation Window Templates. . . . . . . . . . . . . . . . . . . . . . . . . . 261 Appendix A. Abbreviations Index 263 271 LZT 138 0375 R1A iii TEMS Investigation 11.0: Information Elements and Events iv . page 194. 1. The TEMS Investigation Technical Reference is referred to as “TR”. General 1. • • Conventions For the sake of brevity the following conventions are used in this book: The TEMS Investigation User’s Manual is referred to as “UM”. LZT 138 0375 R1A 1 . Some information elements are presentable only with a subset of the connectable devices.Chapter 1. See the tables in chapter 4.2. General 1.1. What’s In This Manual This book catalogs all data presented in TEMS Investigation as well as all preconfigured presentation windows supplied in the application. Elements reported by GAN-capable GSM phones when connected to a GAN. • • WCDMA • 3. including GPRS/ EGPRS elements and (where applicable) WCDMA and TD-SCDMA neighbor measurements.2 • LTE • • TD-SCDMA • 3. Elements reported by LTE-capable phones. Elements from WCDMA scanning.1 Category GSM • Contents Elements reported by GSM-capable phones when in GSM mode. including (if applicable) GSM neighbor measurements. Elements reported by WCDMA-capable phones when in WCDMA mode.TEMS Investigation 11.0: Information Elements and Events 2.3 3. 3. Information Element Categories The information elements are divided into categories in the applications as follows: Section Ref. Elements from LTE scanning.4 • 2 . including HSPA elements and GSM neighbor measurements. Elements from GSM scanning. Elements from TD-SCDMA scanning. Elements reported by TD-SCDMA-capable phones when in TD-SCDMA mode. Elements reported by iDEN phones.Chapter 2. Elements originating from GSM uplink data files. Elements from WiMAX scanning.8 GSM Uplink • 3. Information Element Categories Category CDMA • • iDEN WiMAX Data • • • Contents Elements reported by CDMA phones (including EV-DO and Analog elements).5 3. 3. Elements from CDMA scanning.7 3.9 LZT 138 0375 R1A 3 . These are not reported by devices but calculated by the TEMS Investigation software. Elements relating to data service testing.6 3. Section Ref. alphabetically ordered list. since the number and diversity of the information elements are great.TEMS Investigation 11.0: Information Elements and Events 3. each category on the Info Element tab is still covered in one single. (Certain deviations from strict alphabetical order occur in the application in order to achieve more logical orderings and groupings.) However. Information Elements The tables below list all information elements that can be presented by TEMS Investigation. 4 . a special column with codes is used in some tables to distinguish important subgroups among the elements. For ease of reference. in one of the following ways: • • • g– ga h more values. GSM Information Elements Properties of Information Elements: The Asterisk Column In the column marked *. C/I Best values have a more complex meaning – e. the element is always valid (provided it is supported by the device). but in certain circumstances it is not (code ends in “–”) extended compared to the simplest GSM case: the element sometimes carries more information. Not valid for voice.g. Channel Type. The element is richer for (E)GPRS. Valid when running GPRS.e. Information Elements 3.Chapter 3. more arguments – e. Code c g g+ Valid if a cell file is loaded.g.g. for example when frequency hopping is used (code ends in “+”) If nothing is written in the asterisk column. C/I Hopping List (average over timeslots) larger range of possible values – e. LZT 138 0375 R1A 5 . a set of codes is used to state conditions under which an information element is • • • valid: a non-trivial condition must be fulfilled for the element to be valid not valid: the element is normally valid. Valid in GAN mode or for GAN-capable phones.1. Valid if frequency hopping is used. i. Meaning Not valid when running (E)GPRS. Valid when running HSCSD. GPRS: One value for each timeslot used on the channel (arguments 0 through 7). Not valid when running HSCSD. Not valid for voice. hc+ If frequency hopping is used. Exception: C/I Hopping List has only one value for each channel (arguments 0 through 63). 6 . C/I Best values have a more complex meaning – e.0: Information Elements and Events Code h+ Meaning The element is richer if frequency hopping is used.g. If frequency hopping is used. Channel Type. One value for each channel (arguments 0 through 63). C/I Hopping List (average over timeslots) larger range of possible values – e.TEMS Investigation 11. • • No GPRS connection: One single value (argument 0).e. Reported from GSM RSSI scanning. Example: C/I Hopping List. • • No GPRS connection: One value for each channel (arguments 0 through 63) GPRS: One value for each timeslot used on each channel (arguments 0 through 64 · 8 – 1 = 511). the element contains values for the single channel employed. i. Example: C/I Best. the element covers all channels in the hopping list.g.g. No separate values for each timeslot for a GPRS connection. The element is richer for HSCSD. Reported by positioning equipment. in one of the following ways: • • • hs– p s more values. more arguments – e. h– hs hs+ Not valid if frequency hopping is used. If frequency hopping is not used. the element covers all channels in the hopping list. –10 dBm 1 .. Adjacent RxLev (dBm) –120 ... 4 h– Same as Adjacent RxLev but in dBm. 100 GSM RxLev units Arg 1 . Argument: 1: Serving cell –2 (–400 kHz) 2: Serving cell –1 (–200 kHz) 3: Serving cell +1 (+200 kHz) 4: Serving cell +2 (+400 kHz) Invalid if frequency hopping is used. GSM RxLev Units GSM RxLev units are defined in 3GPP 45. ss “Full” and “Sub” Values Information elements with “Full” in their names are calculated on all blocks. Information Elements Code si Meaning (Reported from interference scanning with a Sony Ericsson GSM phone.4.) This function is no longer supported in any connectable phone. Information Element Table IE Name Adjacent RxLev Range/Unit –10 . section 8.. but the information elements are retained in this description since old logfiles with interference scan data can still be replayed in the application..Chapter 3. Reported from GSM spectrum scanning. 4 * h– Description Signal strength of adjacent channel. LZT 138 0375 R1A 7 .008. Invalid if frequency hopping is used....1. Information elements with “Sub” in their names are calculated only on the blocks known to be sent also when downlink DTX is active (in each 104multiframe. one TCH block with SID information and one SACCH block). 4.2 kbit/s rate”. AMR Active Set DL 0 .g.. C/I limit for codec change to lower bit rate.g. 35 dB – C/I value used as input to mode control in AMR.TEMS Investigation 11. etc. C/I limit for codec change to higher bit rate.. Current active set of AMR speech codecs on downlink. 8848 m Text – p Height above sea level in feet. “12.2.... Altitude (m) – p Height above sea level in meters. 3 AMR Active Set UL Text 0 . although the value should be similar.0: Information Elements and Events IE Name Adjacent Scan Range/Unit 0. This parameter is distinct from the ordinary C/I information elements. each codec being described by a text string.2 kbit/s rate”.. e.. 3 Current active set of AMR speech codecs on uplink. See UM section 16.. “12. 29028 ft –400 . 2 Arg – * Description Use of C/A measurements in phone... AMR C/I Hi Limit –5 .4. 35 dB – 8 . Argument: 0 gives the first member of the active set. 0: Not activated 2: Activated Altitude (ft) –1312 ... AMR C/I –5 . calculated from AMR Hysteresis and AMR Threshold.. calculated from AMR Hysteresis and AMR Threshold. e.. each codec being described by a text string. etc. 35 dB – AMR C/I Lo Limit –5 . Argument: 0 gives the first member of the active set. the members being ordered as in AMR Active Set DL.15 kbit/s 7: 4..90 kbit/s 6: 5.. Invalid if no call is ongoing.. Information Elements IE Name AMR Codec Call DL (%) Range/Unit 0 ..2 kbit/s 1: 10. Argument: See AMR Codec Call DL (%)...... 3 Current distribution of downlink AMR codec usage across the active set being used.. Argument: See AMR Codec Call DL (%). 100 % 0 .95 kbit/s 3: 7. 100 % 0 ..40 kbit/s 4: 6... 7 Distribution of downlink AMR codec usage since the phone started using the current serving cell..70 kbit/s 5: 5. 7 * Description Distribution of downlink AMR codec usage for the current call.. Argument: Indicates the AMR codec..75 kbit/s AMR Codec Call UL (%) 0 . 100 % 0 .Chapter 3. AMR Codec Cell UL (%) 0 . Argument: See AMR Codec Call DL (%). AMR Codec Cell DL (%) 0 . LZT 138 0375 R1A 9 .2 kbit/s 2: 7. AMR Codec DL (%) 0 .. 100 % 0 . 100 % Arg 0 . 7 Distribution of uplink AMR codec usage for the current call.. etc. 7 Distribution of uplink AMR codec usage since the phone started using the current serving cell.. Invalid if no call is ongoing. 0: 12. Argument: 0 gives the first member of the active set... . AMR Threshold 0 . etc. 15 1 .. 251 P-GSM 900: 1 .. 63 1 .. 124.. 3 * Description Current distribution of uplink AMR codec usage across the active set being used.... 100 % Arg 0 . Argument: 0 gives the first member of the active set. 810 – Absolute Radio Frequency Channel Number of Broadcast Control Channel....... 3 Hysteresis values in AMR mode switch mechanism. 293 GSM 850: 128 .TEMS Investigation 11... 124 E-GSM 900: 0 ... the members being ordered as in AMR Active Set UL. 10 . AMR Hysteresis 0 ... 3 Threshold values in AMR mode switch mechanism. Argument: See AMR Hysteresis..0: Information Elements and Events IE Name AMR Codec UL (%) Range/Unit 0 .. 885 GSM 1900: 512 .. Argument: One hysteresis value for each possible mode transition (a maximum of four AMR codecs can be active simultaneously). 1023 GSM 1800: 512 ... ARFCN BCCH GSM 450: 259 ... 975 . Valid for data services only. In dedicated mode: Same as ARFCN TCH.. 2 – – g Time from Attach Request to Attach Complete. 60000 ms 0. Not valid when frequency hopping is used.... Information Elements IE Name ARFCN Current Range/Unit See ARFCN BCCH Arg – * h– Description In idle mode: Same as ARFCN BCCH. BSIC Text – Base Station Identity Code as text string. 26 % 0 . etc. Use of band control function in phone.4...1.1.. 7 g hs BLER/Timeslot (%) 0 . Valid for voice only. calculated taking DTX into account. 7 g hs Block error rate for each timeslot used.2. etc.2.2. 16.. See UM sections 16.2. Attach Time (ms) Band Control 0 .Chapter 3. 100 % 0 . i.3.. and 16. Argument: 0 means the first used timeslot (not TS 0). 0: Not activated 2: Activated BER Actual (%) 0 . ARFCN TCH See ARFCN BCCH – h– Absolute Radio Frequency Channel Number of Traffic Channel. Bit error rate for each used timeslot. BER/Timeslot (%) 0 . Valid only in dedicated mode and only for channels where no frequency hopping is used.... Valid for data services only. LZT 138 0375 R1A 11 . the figure is based only on blocks actually transmitted. 26 % – g– hs– Bit error rate.e. Argument: 0 represents the first used timeslot (not TS 0). Normalized signal level received at the MS (normalization with running average filter). C/A +3 –100 .0: Information Elements and Events IE Name BSIC (Num) C Value Range/Unit 00 . “C/I” elements: General remark Sony Ericsson phones report C/I values for traffic channels. C/I Absolute –5 . 100 dB Arg – – * Description Base Station Identity Code in numeric format. If the BCCH is not used as traffic channel. Argument = ARFCN. the C/I Absolute element will be invalid for the BCCH ARFCN. See also notes on individual elements below. C/A –2 ... 100 dB – h– As C/A –3 but with adjacent channel at –400 kHz. 63 GSM RxLev units –100 . the adjacent channel’s frequency is 600 kHz below the serving cell’s. 35 dB See range of ARFCN BCCH Carrier-over-interference ratio for all channels.. Nokia phones report a single C/I value which is associated with the BCCH in the presentation. 12 .. i.TEMS Investigation 11. see UM chapter 33. Calculated as (RxLev for serving cell) – (Adjacent RxLev for –3).. C/A –3 – h– “Carrier over Adjacent”. +200 kHz... and +600 kHz respectively. 77 (octal) 0 . Concerning the range. +400 kHz...e. –200 kHz. Invalid if frequency hopping is used.... Information Elements IE Name C/I Best Range/Unit –5 . Argument: 0 gives the C/I of the best channel. For Nokia phones. 35 dB Arg 0 . a single C/I value is obtained which is an average over all hopping channels. etc... LZT 138 0375 R1A 13 . Argument: 0 represents the first used timeslot (not TS 0). one C/I value is obtained for each channel scanned. C/I Best: Timeslot 0 . etc.... 1 gives that of the second best. 7 g hs h+ C/I for the worst channel in the hopping list for each used timeslot. Argument: 0 gives the ARFCN of the channel with the best C/I. 511 (8·64–1) g hs h+ For multislot allocations: Timeslot list corresponding to the C/I Best element (which see). For PCTel scanners. this element gives C/I values for all hopping channels in all used timeslots. C/I Best: ARFCN See ARFCN BCCH 0 . 511 (8·64–1) * g+ hs+ h+ Description For Sony Ericsson phones. Argument: 0 gives the timeslot of the channel with the best C/I.... C/I For Worst ARFCN –5 . 511 (8·64–1) g+ hs+ h+ ARFCN list corresponding to the C/I Best element (which see).... 35 dB 0 . the BCCH ARFCN is given at argument 0.. That value is found at argument 0 of this element. 7 0 .Chapter 3. For Nokia phones. etc. The whole list is sorted by descending C/I... etc. . C/I Hopping List: ARFCN See ARFCN BCCH 0 . etc. Argument: 0 gives the C/I of the first channel in the hopping list.. etc.. For multislot channels. If frequency hopping is used.. If frequency hopping is not used.... the C/I for that channel is reported. then if the BCCH is equal to the TCH. C/I On BCCH Carrier –5 . the C/I for that channel is reported. Argument: 0 gives the ARFCN of the first channel in the hopping list. 35 dB Arg 0 . 35 dB – C/I on the current BCCH. the mean value across all used timeslots is given. 63 h+ ARFCNs of the channels in the hopping list (see C/I Hopping List).0: Information Elements and Events IE Name C/I Hopping List Range/Unit –5 . 14 . Invalid otherwise.TEMS Investigation 11.. 63 * g+ hs+ hc+ Description C/I values (unsorted) for the channels in the hopping list. then if the BCCH is used as hopping frequency. The whole list is sorted by ascending C/I.. Argument: 0 gives the ARFCN of the channel having the worst C/I. 1 gives that of the second worst.... C/I Worst: Timeslot 0 . one C/I value is obtained for each channel scanned.. 511 (8·64–1) g+ hs+ h+ ARFCN list corresponding to the C/I Worst element (which see). C/I Worst: ARFCN See ARFCN BCCH 0 . this element gives C/I values for all hopping channels in all used timeslots. 511 (8·64–1) g hs h+ For multislot allocations: Timeslot list corresponding to the C/I Worst element (which see). Argument: 0 gives the C/I of the worst channel.. 127 dB –127 . That value is found at argument 0 of this element. etc. C1 –127 .. Valid only in idle mode... 511 (8·64–1) * g+ hs+ h+ Description For Sony Ericsson phones. C2 – Cell reselection criterion C2. LZT 138 0375 R1A 15 .. 127 dB – Pathloss criterion C1. 35 dB Arg 0 .. For Nokia phones.. etc. the BCCH ARFCN is given at argument 0.. For Nokia phones. etc. 7 0 . a single C/I value is obtained which is an average over all hopping channels. Information Elements IE Name C/I Worst Range/Unit –5 .Chapter 3. Valid only in idle mode.. Argument: 0 gives the timeslot of the channel having the worst C/I. For PCTel scanners. Cell EGPRS Support Text: “Yes”/“No” – EDGE supported/not supported in the cell.. time from last dialed tone until alerting tone was generated in the MTU phone device.. Indicates whether GPRS is supported in the cell. C32 –127 ...0: Information Elements and Events IE Name C31 Range/Unit –127 . Valid both in packet idle and packet dedicated mode. 1 – This element tells whether the calling party’s phone number was identical with the number presented to the called party. 0 = False.. Caller Identification Success 0 . This element occurs only in logfiles from TEMS Automatic. Call Setup Time (Total. 60000 ms – For MTU mobile-terminated (MT) calls. MT) 0 . This information is available also to non-EDGE phones. Calling Phone Number Text – Phone number of the party that placed the call (whether mobileoriginated or mobileterminated).. 127 dB Arg – * g Description GPRS signal strength threshold criterion C31. This element occurs only in logfiles from TEMS Automatic. Cell GPRS Support Cell Id Text: “Yes”/“No” 0 .TEMS Investigation 11. Valid both in packet idle and packet dedicated mode. Cell Identity.. This element occurs only in logfiles from TEMS Automatic. 1 = True. 65535 – – 16 ... 127 dB – g GPRS cell ranking criterion C32.. Activity on channel: Signaling only. ARFCN. Consists of Mobile Country Code. “FFFF” Text Arg – * Description Same as Cell Id but coded as hexadecimal. MNC.Chapter 3. CGI Text – Cell Global Identity. 2: BSIC. Unique cell found matching these parameters within a 35 km radius. Calculated using a number of different algorithms: see Cell Name Algorithm. Cell Name – c Name of serving cell. Requires cell file.. Cell Name Algorithm 1 . Mobile Network Code. speech transmission. Several matching cells found within a 35 km radius. and CI used.. CGI (Hex) Channel Mode Text Text – – LZT 138 0375 R1A 17 . Same as CGI. ARFCN. Information Elements IE Name Cell Id (Hex) Range/Unit Text: “0000” . Location Area Code and Cell Identity.. or data transmission. closest cell selected. Requires cell file. but LAC and CI coded as hexadecimal. and position information used. Presented on the format “MCC MNC LAC CI”. and position information used. LAC. 3: BSIC. 3 – c Indicates the input used by the cell name determination algorithm and (for values 2 and 3) the result of the cell search: 1: MCC.. . EDGE: One of: “MCS-1” .. 18 . “MCS-6 (pad)”.. “MCS-9”. GPRS: One of “CS-1” . “MCS-6-9”. whether for circuit-switched or packetswitched. also indicating which speech coder is used. –10 dBm See range of ARFCN BCCH – g+ hs+ Channel Type Text Channel type. Ciphering Algorithm Text – Coding Scheme DL Text – g Modulation coding scheme used on downlink. etc..TEMS Investigation 11. “(pad)” means that an RLC block is retransmitted using MCS-3 and MCS-6 respectively. or “PDCH”. this element is also updated by scan reports.). Argument = ARFCN. 100 GSM RxLev units Arg See range of ARFCN BCCH * Description Measured signal strength level for all channels. GEA/1. A5/2.. Note: Unlike RxLev Full/RxLev Sub. MCS-5-7 and MCS-6-9 are explained in 3GPP 44. Channel RxLev (dBm) –120 .060. Currently used ciphering (A5/1. “MCS-3 (pad)”.0: Information Elements and Events IE Name Channel RxLev Range/Unit –10 . Same as Channel RxLev but in dBm. “CS-4”. “BCCH”. “TCH/F + FACCH/ F and SACCH/M”. For example. Argument = ARFCN. “MCS-5-7”.... 4 g Distribution of coding scheme usage on downlink (overall.. 4 * g Description Distribution of coding scheme usage on downlink (for own data only). not limited to own data)... etc.. Text – g Modulation coding scheme used on uplink. These elements contain the distribution of coding scheme usage (on the downlink and for own data only) for each timeslot. see Coding Scheme DL. 100 % 0 .. Information Elements IE Name Coding Scheme DL Usage (Own Data) (%) Coding Scheme DL Usage (Total) (%) Coding Scheme UL Range/Unit 0 . For the possible values. Modulation coding scheme currently used on uplink. 7 g Current CS DL Current CS UL Current MCS DL Current MCS UL Data Mode 1 . 100 % Arg 1 .. Modulation coding scheme currently used on downlink. 4 1 .. n = 1 .. 9 Text – – – – – g g g g Coding scheme currently used on downlink. 100 % 1 . or circuitswitched. 0 .. Argument: 0 represents the first used timeslot (not TS 0). etc.. 4 1 . Argument: 1 means CS-1...... Indicates whether the data transfer is performed over GPRS. 4 0 . Argument: 1 means CS-1.Chapter 3. 9 1 . Coding scheme currently used on uplink.. EGPRS. LZT 138 0375 R1A 19 ... CS-n DL Usage (Own Data) (%). etc..... . 45 – Initial value of Downlink Signalling Counter (DSC). 2 – Use of Disable Handover function in phone.4. Calculated as: number of blocks not sent ------------------------------------------------------------------total number of blocks ⋅ 100 2 mandatory blocks are always sent using DTX: 1 TCH (with SID information) and 1 SACCH.2.TEMS Investigation 11... section 8. 31 See Description – Mean value of bit error probability as reported in the Layer 3 message EGPRS Packet Downlink Ack/Nack. or circuitswitched.5. 45 – 0 . 0 . EGPRS BEP (Mean) 0 . 3 Arg – * Description Indicates whether the data transfer is performed over GPRS.0: Information Elements and Events IE Name Data Mode (Num) Range/Unit 1 .2... EGPRS. Current value of Downlink Signalling Counter (DSC).. 100 % – g– Use of DTX on downlink.8. Coded according to the table in 3GPP 45. 0 . 20 ..008. Valid only in idle mode. See UM section 16. Non-existent for packetswitched (no DTX).. Valid only in idle mode. 1: GPRS 2: EGPRS 3: CS Disable Handover Downlink Signalling Counter Current Downlink Signalling Counter Max DTX Rate DL 0... 008..2.. 1024 RLC blocks 64 . 31 See Description – Short-term mean value of bit error probability extracted from Layer 1. the figure is based only on blocks actually transmitted..e.2. EGPRS BEP Total (Variance) 0 . i. EGPRS BEP Total (Mean) 0 . 7 See Description – Short-term variance of bit error probability extracted from Layer 1. 64 . section 8.. calculated taking DTX into account.. 1024 RLC blocks 0 . g– hs– Frame erasure rate. Coded according to the table in 3GPP 45. Coded according to the table in 3GPP 45.2.. Coded according to the table in 3GPP 45. Retransmission buffer size on downlink (RLC protocol level). EGPRS Link Quality Control UL EGPRS Window Size DL EGPRS Window Size UL FER Actual (%) Text – Indicates whether Link Adaptation (LA) or Incremental Redundancy (IR) is used on the uplink.5. section 8. Valid for voice only.. 100 % – – – LZT 138 0375 R1A 21 .5.008. EDGE retransmission buffer size on uplink (RLC protocol level).008. Information Elements IE Name EGPRS BEP (Variance) Range/Unit 0 ....5. 7 See Description Arg – * Description Variance of bit error probability as reported in the Layer 3 message EGPRS Packet Downlink Ack/Nack.. section 8.Chapter 3.. .2 for details. FER Sub (%) 0 . 0: Not activated 2: Activated Not supported by any currently connectable phones. Forced Multislot Class 0. For the calculation. see section 4. Forced Power Class 0. Sub value. Full value..2 for details. 100 % Arg – * Description Frame erasure rate. Firmware Version Forced GPRS Class – – 22 .TEMS Investigation 11. 100 % Text 0. see section 4. 2 – g Use of GPRS multislot class forcing function in phone.0: Information Elements and Events IE Name FER Full (%) Range/Unit 0 .. see FER Full (%). 0: Not activated 2: Activated Not supported by any currently connectable phones. 2 – Frame erasure rate. see section 4.2 for details. Calculated as: number of erased blocks ---------------------------------------------------------------total number of blocks ⋅ 100 A block is erased when the parity check (CRC) fails. 0: Not activated 2: Activated Not supported by any currently connectable phones. 2 – Use of power class forcing function in phone.. Version number of device firmware. g Use of GPRS class forcing function in phone. 2 for details.. only appear in merged logfiles (see UM section 36.. 4 – Frequent AQM score for last speech sentence played on the downlink. Uplink Frequent AQM sentence index. 450 . see section 4. 1 .... uplink and downlink scores. Frequent AQM score for last speech sentence played on the uplink. Frequency Band Frequency Band (Num) Frequency Band For TCH Frequent AQM IEs: General remark Frequent AQM Score DL Frequent AQM Score UL Frequent AQM Sentence DL Frequent AQM Sentence UL GA-RC/GACSR State Text – Frequency band of BCCH carrier. Frequency band of BCCH carrier in numeric format. 5 MOS-PESQ 0 . “850”.. “850”. “900R”.2).g. 5 MOS-PESQ 1 .. “1800”. Downlink Frequent AQM sentence index. e..Chapter 3. 1: GA-RC Deregistered 2: GA-RC Registered 3: GA-CSR Idle 4: GA-CSR Dedicated – – – – LZT 138 0375 R1A 23 ..g.. Frequency band of current traffic channel or channels. 0: Not activated 2: Activated Not supported by any currently connectable phones. “1800”. 7 1 . e. 2 Arg – * g Description Use of PDP Context Request modification function in phone.. 7 0 . 1900 MHz Text – – These elements. Information Elements IE Name Forced Quality Of Service Range/Unit 0. “900E”. “900R”. “900E”.. ga State of GA-RC or GA-CSR protocol. 0: Normal service 1: Limited service 2: Phone has not found GERAN coverage 3: Phone has found GERAN coverage..TEMS Investigation 11... Service Set Identifier of connected WLAN access point. Location Area Code in the GSM network. 999 – ga 000 ... MAC address of connected WLAN access point (BSSID in IEEE 802.11 standard).. Mobile Country Code in the GSM network.. Included in Register and Discovery messages if the phone is in an area with GSM coverage and GSM-RR is the serving RR entity. Mobile Network Code in the GSM network. Retrieved from GSM System Information.0: Information Elements and Events IE Name GA-RC/GACSR State (Text) GAN Access Point MAC Address GAN Access Point SSID GAN GERAN Cell Id Range/Unit Text Arg – * ga Description Same as GA-RC/GA-CSR State but in text format. Cell Identity in the GSM EDGE Radio Access Network (GERAN). 999 – ga 0 . Used to indicate the presence of GERAN coverage in the phone’s current location. Retrieved from GSM System Information. service state unknown Text – ga Text 0 .. Retrieved from GSM System Information. Retrieved from GSM System Information. 65535 – ga 000 .. 65535 – – ga ga GAN GERAN LAC GAN GERAN MCC GAN GERAN MNC GAN GSM Coverage Indicator 0 .. 3 – ga 24 . 255 – ga GAN WLAN Quality Level 0 . 0: Unusable 1: Poor 2: Adequate 3: Good 4: Excellent 5: Not applicable 0 . “Ready”.... Indicates to the GANC the number of times the phone has been redirected (from one GANC to another) without obtaining service. Points to the default GANC the phone should use. WLAN received signal strength. Information Elements IE Name GAN GSM Coverage Indicator (Text) GAN Redirect Counter Range/Unit Text Arg – * ga Description Same as GAN GSM Coverage Indicator but in text format. Device model. State of GMM protocol: “Idle”. 360 degrees – – – – – g g p Direction of travel measured in degrees clockwise from north. Device IMEI. State of GRR protocol: “Packet Idle” or “Packet Transfer”.. 5 – ga GAN WLAN Quality Level (Text) GAN WLAN RSSI GANC IP Address GANC SEGW IP Address GMM State GRR State Hardware Hardware ID Heading (deg) Text – ga Same as GAN WLAN Quality Level but in text format. WLAN signal level.003.Chapter 3. –254 .. or “Standby”... 0 dBm Text Text – – – ga ga ga Text Text Text Text 0 . Points to the default GANC Security Gateway the MS should use. See 3GPP 23. LZT 138 0375 R1A 25 .. 4. 16.TEMS Investigation 11. Useful when replaying a logfile.3. 16.) Interference BCCH ARFCN See ARFCN BCCH – si The BCCH ARFCN of the serving cell locked on during interference scanning. for example “1. 16. Hopping Sequence Number.. Useful when replaying a logfile.4.1. See UM sections 16. 28”. 19. 10.4. h ARFCNs of the channels in the hopping frequency list.. Use of idle mode RxQual measurement function in phone.2. 2 – Use of ignore/reverse cell barred function in phone.5.) 26 . see section 4. HSN 0 . indicating which hopping frequency list to use. (Interference scanning is no longer supported by any connectable phones.3. 63 – h Idle Channel Quality 0.2. 2 – Ignore Cell Barred 0.2. 0: Not activated 2: Activated Interference Measured ARFCN See ARFCN BCCH – si The ARFCN scanned for interferers during interference scanning.2 for details.3. 0: Not activated 2: Activated Not supported by any currently connectable phones.2.0: Information Elements and Events IE Name Hopping Hopping List Range/Unit Text Text Arg – – * Description Use of frequency hopping (“YES”/”NO”). (Interference scanning is no longer supported by any connectable phones. .4. 90 degrees Text Arg – – * Description Location Area Code....4. Longitude Longitude (Text) LLC BLER DL (%) LLC BLER UL (%) LLC Bytes Received DL LLC Bytes Sent UL LLC Throughput DL (kbit/s) LLC Throughput UL (kbit/s) –180 . Longitude as text. 2 · 109 bytes 0 . Same as LAC. FFFF –90 .. Information Elements IE Name LAC LAC (Hex) Range/Unit 0 .. see TR section 2.. For the presentation format. Data throughput (including protocol headers. 180 degrees Text – – p p 0 . 400 kbit/s – g LZT 138 0375 R1A 27 . Number of bytes sent at the LLC protocol level since PS attach. Latitude as text. 100 % 0 ... 65535 Text: 0000 . see TR section 2. For the presentation format. but coded as hexadecimal. Latitude Latitude (Text) – – p p Latitude recorded by positioning equipment.. Percentage of LLC data blocks resent on uplink... but excluding retransmissions) on uplink at the LLC protocol level.. Data throughput (including protocol headers. Number of bytes received at the LLC protocol level since PS attach. but excluding retransmissions) on downlink at the LLC protocol level.... 2 · 109 bytes 0 ... Longitude recorded by positioning equipment. Percentage of LLC data blocks erroneously decoded on downlink..Chapter 3.. 100 % 0 . 400 kbit/s – g – – g g – g – g 0 . TEMS Investigation 11. 3 Arg – – – * Description LLC retransmission buffer size on downlink.... half duplex mode MAC Mode DL (Text) MAC Mode UL MAC Mode UL (Text) MAIO Text 0 ..0: Information Elements and Events IE Name LLC Window Size DL LLC Window Size UL MAC Mode DL Range/Unit 1 . Type of GPRS connection on uplink. LLC retransmission buffer size on uplink. 3 Text 0 .... 63 – – – – g g g h Same as MAC Mode DL but in text format.. 9 000 .. not half duplex mode 3: Fixed Allocation.. 7 28 . 255 LLC blocks 0 . Valid only if frequency hopping is used. Same as MAC Mode UL but in text format.... n = 1 .. etc.. 255 LLC blocks 1 .. Indicates where in the hopping frequency list to start. 100 % – 0 . Mobile Country Code. See MAC Mode DL. g Type of GPRS connection on downlink: 0: Dynamic Allocation 1: Extended Dynamic Allocation 2: Fixed Allocation. MCC MCS-n DL Usage (Own Data) (%).. Argument: 0 represents the first used timeslot (not TS 0).. These elements contain the distribution of modulation coding scheme usage (on the downlink and for own data only) for each timeslot. Mobile Allocation Index Offset. 999 0 . Same as “Mode (Num)” (which see) but in text format: “No service” etc.. Used for text-format logfile export only... 999 Text – – Mobile Network Code.Chapter 3. Information Elements IE Name Message Hex Dump Payload Range/Unit Text Arg – * Description Contains the hexadecimal string of a Layer 3 message or mode report. Mode (Num) 1 . MNC Mode 000 . Type of modulation on uplink.. May consist of two or three digits. 7 – Modulation DL Modulation UL Text Text – – LZT 138 0375 R1A 29 . 1: No service 2: Idle mode 3: Dedicated mode 4: Limited service mode 5: Scan mode 6: Packet mode 7: Packet Idle mode Type of modulation on downlink. MS Power Control Level 0 . Valid only in dedicated mode. 30 .. “G”. Any combination of these letters may appear. Empty string: No modification of phone behavior B: Modification of behavior not related to channel selection (the information elements Adjacent Scan. mapped to a number between 0 and 31 according to the tables in 3GPP 45. Serving Cell List Active..1. Forced Multislot Class. section 4. Band Control. Forced Quality Of Service). Most of what follows is applicable only to Sony Ericsson GSM phones.TEMS Investigation 11. Idle Channel Quality) C: Modification of channel selection behavior (the information elements Disable Handover.1. 31 See Description – Phone transmit power ordered by the base station. Prevent Handover List Active. “C”.0: Information Elements and Events IE Name MS Behavior Modified Range/Unit Text: “B”. Prevent Serving Cell List.005. Forced Power Class. or a combination of these letters (or empty string) Arg – * Description Indicates whether the phone’s behavior has been changed from the default. Target Handover) G: Modification of GPRS behavior (the information elements Forced GPRS Class. Ignore Cell Barred. Information Elements IE Name MS Tx Power (dBm) Range/Unit GSM 850: 5 . sorted by ARFCN... Neighbor BSIC Text 1 . 39 GSM 900: 5 . Band and SS ... Valid only in dedicated mode.. Argument: 1 gives the lowest ARFCN.. Argument: 1 represents the strongest neighbor. etc. etc.1.” elements. See ARFCN BCCH 1 ....Chapter 3. Neighbor IEs: General remark A number of elements have been left out of the table. the feature has been removed from TEMS Investigation. 32 ARFCNs of neighbor cells.. 33 dBm Arg – * Description Phone transmit power in dBm. 39 GSM 1800: 0 . sorted by ARFCN. 32 ARFCNs of neighbor cells.. Multiband Reporting 0. 2 – Not used. LZT 138 0375 R1A 31 . What differs is the sorting order: first by band and then. etc.. The element is retained in order to maintain compatibility with old logfiles. sorted by signal strength. Neighbor ARFCN Neighbor ARFCN (Sorted) See ARFCN BCCH 1 . 36 GSM 1900: 0 .... Argument: 1 represents the lowest ARFCN.. which are mere variants of the ordinary “Neighbor” elements and are used in the status window Serving + Neighbors By Band (see section 7. by signal strength. These are the “Neighbor .. within each band. 32 Base Station Identity Codes for neighbor cells (in text format)..2). . etc. etc. Argument: 1 represents the lowest ARFCN. etc. sorted by signal strength... etc.. sorted by signal strength. Neighbor C1 (Sorted) –127 . 127 dB 1 . 127 dB 1 .. etc.. Neighbor C1 –127 . 32 Pathloss parameter C1 for neighbor cells.TEMS Investigation 11. 127 dB 1 . Neighbor BSIC (Num) (Sorted) 00 . 77 (octal) 1 .0: Information Elements and Events IE Name Neighbor BSIC (Num) Range/Unit 00 ... Argument: 1 represents the strongest neighbor.. 32 Cell reselection parameter C2 for neighbor cells..... sorted by signal strength.. sorted by ARFCN. 77 (octal) Arg 1 . Argument: 1 represents the strongest neighbor. Neighbor C2 –127 ... etc. Neighbor C2 (Sorted) –127 . sorted by ARFCN. etc. 32 Base Station Identity Codes for neighbor cells (in numeric format).. 32 * Description Base Station Identity Codes for neighbor cells (in numeric format). 127 dB 1 .. Argument: 1 represents the lowest ARFCN. Argument: 1 represents the strongest neighbor. sorted by signal strength.. 32 . 32 Base Station Identity Codes for neighbor cells (in text format). sorted by ARFCN... 32 Cell reselection parameter C2 for neighbor cells... Neighbor BSIC (Sorted) Text 1 . 32 Pathloss parameter C1 for neighbor cells. Argument: 1 represents the lowest ARFCN. Argument: 1 represents the strongest neighbor.... . sorted by signal strength. sorted by ARFCN. Hexadecimal format.. Decimal format. Argument: 1 represents the lowest ARFCN. Information Elements IE Name Neighbor C31 Range/Unit –127 . 65535 1 . “FFFF” 1 . etc.. 127 dB 1 .... 127 dB 1 . LZT 138 0375 R1A 33 . etc. 32 Cell identities of neighbor cells.... 127 dB Arg 1 . Neighbor Cell Id 0 . 32 Cell identities of neighbor cells. etc... Argument: 1 represents the strongest neighbor. Neighbor C32 (Sorted) –127 . sorted by signal strength.. 32 g GPRS signal strength threshold criterion C31 for neighbor cells. Argument: 1 represents the lowest ARFCN. 32 Cell identities of neighbor cells.. Argument: 1 represents the lowest ARFCN... Argument: 1 represents the lowest ARFCN... 65535 1 .Chapter 3.. 32 g GPRS cell ranking criterion C32 for neighbor cells. Neighbor C32 –127 . Decimal format. etc... Argument: 1 represents the strongest neighbor. Neighbor Cell Id (Sorted) 0 . sorted by ARFCN. sorted by ARFCN. 32 g GPRS cell ranking criterion C32 for neighbor cells.. Neighbor C31 (Sorted) –127 .. 127 dB 1 .. Neighbor Cell Id (Hex) Text: “0000” .. Argument: 1 represents the strongest neighbor... etc. sorted by signal strength. etc.. sorted by ARFCN. 32 * g Description GPRS signal strength threshold criterion C31 for neighbor cells.. etc. sorted by signal strength.... Requires cell file.. 32 * Description Cell identities of neighbor cells. 32 c Names of neighbor cells. sorted by signal strength. Argument: 1 represents the strongest neighbor... etc. 32 c Names of neighbor cells. Neighbor Cell Name Text 1 .. etc. sorted by ARFCN. Neighbor Cell Name (Sorted) Text 1 . Argument: 1 represents the lowest ARFCN. “FFFF” Arg 1 .0: Information Elements and Events IE Name Neighbor Cell Id (Hex) (Sorted) Range/Unit Text: “0000” . Argument: 1 represents the strongest neighbor. Hexadecimal format.TEMS Investigation 11. 34 . etc.. Requires cell file. this neighbor identified as a cell appearing in the serving cell’s neighbor list and having matching BSIC and ARFCN. the input used by the algorithm determining the neighbor cell name. closest cell selected. LZT 138 0375 R1A 35 . 6: Serving cell found with the method denoted by Cell Name Algorithm = 3.. Information Elements IE Name Neighbor Cell Name Algorithm Range/Unit 1 . this neighbor identified as a cell appearing in the serving cell’s neighbor list and having matching BSIC and ARFCN.Chapter 3. ARFCN. etc. Several matching cells found within a 35 km radius. Neighbors are sorted by ARFCN. this neighbor identified as a cell appearing in the serving cell’s neighbor list and having matching BSIC and ARFCN.. CI used. 2: BSIC. Unique cell found matching these parameters within a 35 km radius. and position information used. – Requires cell file. for each neighbor cell. Argument: 1 represents the lowest ARFCN.. 5: Serving cell found with the method denoted by Cell Name Algorithm = 2. 4: Serving cell found with the method denoted by Cell Name Algorithm = 1.. MNC. LAC. 3: BSIC. 32 * c Description Indicates. and the result of the cell search (where applicable): 1: MCC. ARFCN. 6 Arg 1 . and position information used. Decimal format. 65535 1 . 32 Location Area Codes for neighbor cells. “FFFF” 1 . Neighbor LAC (Sorted) 0 . 32 * c Description Same as Neighbor Cell Name Algorithm but sorted by signal strength.. Neighbor RxLev –10 . etc. Argument: 1 represents the lowest ARFCN. etc. Neighbor RxLev (Sorted) –10 . Argument: 1 represents the strongest neighbor.. etc.. 32 Location Area Codes for neighbor cells... 32 Location Area Codes for neighbor cells. Neighbor LAC 0 .... Neighbor LAC (Hex) Text: “0000” .. sorted in descending order... sorted by signal strength.0: Information Elements and Events IE Name Neighbor Cell Name Algorithm (Sorted) Range/Unit 1 .. Decimal format.. Argument: 1 represents the strongest neighbor. 100 GSM RxLev units 1 . Hexadecimal format... Argument: 1 represents the lowest ARFCN. “FFFF” 1 . Hexadecimal format. Argument: 1 represents the strongest neighbor. 32 Received signal strength of neighbors.. Argument: 1 represents the lowest ARFCN. sorted by ARFCN. etc. etc. etc. 32 Received signal strength of neighbors.. sorted by ARFCN. 100 GSM RxLev units 1 ... 36 . etc.. sorted by ARFCN. Argument: 1 represents the strongest neighbor. 6 Arg 1 . 32 Location Area Codes for neighbor cells. 65535 1 ..TEMS Investigation 11. sorted by signal strength. Neighbor LAC (Hex) (Sorted) Text: “0000” ........ .... 18. Number Of Hopping Frequencies 0 . –10 dBm –120 . 32 1 . Network Control Order Text – g Cell reselection behavior of phone. –10 dBm Text Arg 1 . Gs signaling interface present II: All paging on PCH. The list is given in text format.. section 10.008.1. 64 – h Number of frequencies in hopping list. for example: “[ARFCN: 17.4. no Gs III: All circuit-switched paging on PCH. The data within square brackets pertains to the strongest cell.. no Gs. “NC2”: NC0: MS reselection.. LZT 138 0375 R1A 37 . measurement reports NC2: Network reselection See 3GPP 45..Chapter 3. all packet-switched paging on PPCH. 32 * Description Same as Neighbor RxLev but in dBm. “NC1”. Information Elements IE Name Neighbor RxLev (dBm) Neighbor RxLev (dBm) (Sorted) Neighbor (SI) ARFCN Range/Unit –120 . no measurement reports NC1: MS reselection. Network Mode Of Operation Text – g Handling of paging in the network.. 32”. – s Neighbor list (obtained from System Information) of strongest cell scanned.. Same as Neighbor RxLev (Sorted) but in dBm. BSIC: 3-2] 7. and the neighbor ARFCNs follow. One of “NC0”. I: All paging on GPRS channels. Percentage of the available uplink PDCH capacity currently used for control signaling.... That is.... Timeslot used for PBCCH/ PCCCH. 38 .. 0 . 7 g 0 . Percentage of the available uplink PDCH capacity currently used for own data. 7 g 0 .. 100 % 0 ... 7 g 0 . 7 g Percentage of downlink PDCH capacity currently used for control signaling.. 100 % 0 .. 8 – 0 .. 100 % 0 . the argument value does not equate to the corresponding timeslot index.. 1 the second. 0 .. refers to a PDP context index. 100 % 0 . 0 ..... Number of timeslots in use on uplink.TEMS Investigation 11.. Percentage of the downlink PDCH capacity currently used for own data. 7 g 0 ... etc... or not used at all.. Percentage of the available uplink PDCH capacity that is currently unused. 7 g The argument. 100 % 0 .0: Information Elements and Events IE Name Number Of Used Timeslots DL Number Of Used Timeslots UL PBCCH Timeslot PDCH IEs: General remark PDCH Utilization Control DL (%) PDCH Utilization Control UL (%) PDCH Utilization Other Data DL (%) PDCH Utilization Own Data DL (%) PDCH Utilization Own Data UL (%) PDCH Utilization Free Data UL (%) PDP IEs: General remark Range/Unit 0 . 0 represents the first used timeslot.. where present.. if any. 7 – The argument represents a timeslot but is just a sequence number.... 8 Arg – * g hs g hs g Description Number of timeslots in use on downlink. 100 % 0 . Percentage of the downlink PDCH capacity currently used for other users’ data.. 11 g g Uplink PESQ scores only appear in merged logfiles.... 11 – * g g g Description Host name or network address for each active PDP context.2. 11 1 . Information Elements IE Name PDP Access Point Name PDP Address PDP Context Time (ms) PDP Contexts Active PDP Delay Class PDP LLC SAPI PDP Mean Throughput PDP NSAPI PDP Peak Throughput PDP Precedence Class PDP Radio Priority PDP Reliability Class PESQ IEs: General remark Range/Unit Text Text 0 . Network SAPI (Service Access Point Identifier)... PESQ Echo Attenuation LZT 138 0375 R1A 39 . User address (IPv4/IPv6). However.. Number of active PDP contexts. appear in merged as well as unmerged logfiles.. 11 1 .. – 1 .... 11 Text 3 ... Reliability class as defined by subscription.. Radio priority level as defined by subscription. prior to merging. Peak throughput as defined by subscription. 11 1 ... all such data lags behind other data in the logfile. 11 1 .. 11 Text 5 .2... as well as the remaining AQM measurements (all other elements prefixed with “PESQ” below)... Mean throughput as defined by subscription. LLC Service Access Point Identifier. 15 Text Text Arg 1 .. 11 1 . 11 1 .. 0 . Precedence class as defined by subscription. 60000 ms 0 .. Delay class as defined by subscription. Time from PDP Context Activation Request to PDP Context Activation Accept.... Downlink PESQ scores. 11 1 .. 11 g g g g g g g Text Text 1 .Chapter 3. See UM section 36.. 100 dB – AQM: Echo attenuation on downlink.. AQM: Volume on downlink.) See UM section 16. 0: No 2: Yes –100 .TEMS Investigation 11..2. AQM: Downlink PESQ sentence index.0: Information Elements and Events IE Name PESQ Echo Correlation PESQ Echo Delay PESQ Echo Power PESQ Score DL PESQ Score UL PESQ Sentence DL Range/Unit 0 . (At the outset no option is selected... 0: Sentences 0 + 1 1: Sentences 2 + 3 2: Sentences 4 + 5 3: Sentences 6 + 7 – – PESQ Sentence UL PESQ Volume Preferred GAN Mode 0 .4.. 5 MOS-PESQ 0 .... AQM: PESQ score for last two speech sentences played on the downlink.. AQM: PESQ score for last two speech sentence played on the uplink. 20 dB 0.5. 5 0 .. 100 dB 1 . Each index represents the two sentences over which the corresponding PESQ score was calculated.. AQM: Echo delay on downlink. Same meaning as PESQ Sentence DL (which see). 3 – AQM: Uplink PESQ sentence index.. 5 MOS-PESQ 1 . AQM: Echo power on downlink... 2 – – 40 . 3 Arg – – – – * Description AQM: Echo correlation on downlink. ga Indicates whether a selection has been made on the GAN Mode Selection tab of the phone’s property page.... 1000 ms 0 . 4. 8..2. section 10.4. but coded as hexadecimal.. 255 Text: “00” .g. Valid only in dedicated mode.2.. 64 – – – Radio Link Timeout Max 4..4. RAC RAC (Hex) Radio Link Timeout Current 0 . See UM section 16. The call is terminated when the counter drops to 0... Uses the “leaky bucket” principle. . Each decoded block increases the counter by 1 (if it is not already at max) and each failed block decreases the counter by 2. “Above –74 dBm”.. “FF” 0 . See UM section 16.. Valid only in dedicated mode. 0: Not activated 2: Activated Q Search Power Text – GPRS signal level criterion governing when to search for 3G cells (e. 64 – Initial value of Radio Link Timeout counter. Current value of Radio Link Timeout counter. g g Routing Area Code (8 bits). “Below –54 dBm”. 2 – Use of “prevent cell selection” function in phone (camping on selected cells prevented in idle mode). 2 Arg – * Description Use of prevent handover function in phone (handover to certain cells prevented in dedicated mode). 0: Not activated 2: Activated Prevent Serving Cell List 0. “Never”).. LZT 138 0375 R1A 41 . Information Elements IE Name Prevent Handover List Active Range/Unit 0. Same as RAC. See 3GPP 45.8. “Always”.008.6.Chapter 3. ..0: Information Elements and Events IE Name RLA_P Range/Unit –10 . RLA_P (dBm) RLC BLER DL (%) RLC BLER UL (%) RLC Block BSN elements – – g g – 0 . 23 g RLC/MAC block header as hex string (e. 42 .TEMS Investigation 11.. 100 % 0 . “80 1a 20”). Used for text-format logfile export only. 100 % 0 . Same as RLA_P but in dBm.. Used for text-format logfile export only.. Argument: Points to an individual GPRS radio block. Percentage of RLC data blocks resent on uplink.. 23 g g RLC Block Dump elements Text 0 .. One element for each timeslot on downlink and uplink.. Argument: Points to an individual GPRS radio block. One element for each timeslot on downlink and uplink... for both data and control blocks. 100 GSM RxLev units –120 .. –10 dBm 0 . RLC/MAC Block Sequence Number from header of data blocks.. 127 Arg – * g Description Received Level Average (GPRS signal strength measure).. Percentage of RLC data blocks erroneously decoded on downlink.g.. RLC Bytes Received DL RLC Bytes Sent UL RLC Throughput DL (kbit/s) 0 .. Data throughput (including protocol headers. “Data Block to other MS”. RLC Block Type elements Text 0 . One element for each timeslot on downlink and uplink. 31 Arg 0 . – g – g LZT 138 0375 R1A 43 .... 23 g RLC/MAC block type as string. 400 kbit/s – g Number of bytes received at the RLC protocol level since GPRS attach. One element for each timeslot on downlink and uplink... Argument: Points to an individual GPRS radio block. 23 * g Description RLC/MAC Temporary Flow Identifier from header of control and data blocks. 2 · 109 bytes 0 .. Information Elements IE Name RLC Block TFI elements Range/Unit 0 . Number of bytes sent at the RLC protocol level since GPRS attach. or “Forbidden”. or “Control Block”. Used for text-format logfile export only... Downlink: “Data Block to this MS”.. 2 · 109 bytes 0 . “Data block sent”. Argument: Points to an individual GPRS radio block.. Used for text-format logfile export only. “Control Block sent”.. Uplink: “Allowed but no data sent”. but excluding retransmissions) on downlink at RLC protocol level.Chapter 3. Data throughput (including protocol headers. but excluding retransmissions) on downlink at RLP protocol level.. Data throughput (as defined above) on downlink at RLP protocol level. 100 % Arg – * g Description Data throughput (as defined above) on downlink at RLC protocol level. Percentage of RLP data blocks resent on uplink. relative to theoretical maximum for current channel setup (coding scheme. RLC Throughput UL (kbit/s) RLC Throughput UL (%) 0 . Percentage of RLP data blocks erroneously decoded on downlink. relative to theoretical maximum for current channel setup (coding scheme.. Data throughput (as defined above) on uplink at RLC protocol level. Data throughput (including protocol headers.0: Information Elements and Events IE Name RLC Throughput DL (%) Range/Unit 0 .TEMS Investigation 11. 100 % – g RLP BLER DL (%) RLP BLER UL (%) RLP Bytes Received DL RLP Bytes Sent UL RLP Throughput DL (kbit/s) RLP Throughput DL (%) 0 ... Number of bytes sent at the RLP protocol level since dialup. number of timeslots).... but excluding retransmissions) on uplink at RLC protocol level..... number of timeslots).. 60 kbit/s – hs – – hs hs – hs – hs 0 .. 100 % 0 . 100 % 0 .. number of timeslots). relative to theoretical maximum for current channel setup (coding scheme... 100 % – hs 44 . 2 · 109 bytes 0 .. Number of bytes received at the RLP protocol level since dialup.. 2 · 109 bytes 0 . 400 kbit/s – g 0 . Not valid when in limited service or no service mode. Received signal strength (Full value) expressed in GSM RxLev units. Not valid when in limited service or no service mode. 100 GSM RxLev units –120 . 0 .. –10 dBm –10 . relative to theoretical maximum for current channel setup (coding scheme.. –10 dBm – RxLev Sub (dBm) – LZT 138 0375 R1A 45 .. 100 GSM RxLev units –120 . –10 dBm – RxLev Sub –10 . Received signal strength (Full value) expressed in dBm.. Information Elements IE Name RLP Throughput UL (kbit/s) RLP Throughput UL (%) Range/Unit 0 . or packet dedicated mode.. or packet dedicated mode. packet idle. Received signal strength (Sub value) expressed in GSM RxLev units.. dedicated. Data throughput (as defined above) on uplink at RLP protocol level.... but excluding retransmissions) on uplink at RLP protocol level.. 100 % – hs RxLev Full –10 ..... Same as RxLev Full (dBm) but valid only when the phone is in idle.. packet idle. 60 kbit/s Arg – * hs Description Data throughput (including protocol headers. Received signal strength (Sub value) expressed in dBm. dedicated.. Same as RxLev Full but valid only when the phone is in idle. 100 GSM RxLev units – RxLev Full (dBm) RxLev Full In Service – – RxLev Full In Service (dBm) –120 . number of timeslots).Chapter 3. section 8.. 7 See Description – – RxQual Sub (%) Scanned Adjacent ARFCN –2 0 .. calculated from the bit error rate according to the table in 3GPP 45. Same as RxLev Sub (dBm) but valid only when the phone is in idle. RxLev Sub In Service (dBm) –120 . Bit error rate in percent (%) corresponding to RxQual Full...2. or packet dedicated mode. or packet dedicated mode... Bit error rate in percent (%) corresponding to RxQual Sub. 26 % 0 . 63 h+ Same as Scanned Adjacent ARFCN –2 but for the channels at –200 kHz.. –10 dBm – RxQual Full 0 . Not valid when in limited service or no service mode. 46 .. Argument: 0 means the channel adjacent to the first channel in the hopping list.4. calculated from the bit error rate according to the table in 3GPP 45.008.2.. dedicated.0: Information Elements and Events IE Name RxLev Sub In Service Range/Unit –10 . Received signal quality (Full value). 7 See Description – RxQual Full (%) RxQual Sub 0 ..008.. dedicated.. Scanned Adjacent ARFCN –1 See ARFCN BCCH 0 . 26 % See ARFCN BCCH – 0 . Received signal quality (Sub value)..4. etc. 100 GSM RxLev units Arg – * Description Same as RxLev Sub but valid only when the phone is in idle. section 8. 63 h+ C/A measurement: ARFCNs of channels at –400 kHz.. packet idle.. packet idle.. Not valid when in limited service or no service mode.TEMS Investigation 11. .. That is.... C/A measurement: Scanned signal strength of the channels at –400 kHz.. 63 h+ LZT 138 0375 R1A 47 .. Note that this element does not itself refer to an adjacent channel but to the C0... 63 h+ Same as Scanned Adjacent ARFCN –2 but for the channels at +200 kHz. Information Elements IE Name Scanned Adjacent ARFCN C0 Range/Unit See ARFCN BCCH Arg 0 . –120 . –10 dBm 0 .. –10 dBm 0 .. Scanned Adjacent ARFCN +1 Scanned Adjacent ARFCN +2 Scanned Adjacent RxLev –2 (dBm) See ARFCN BCCH See ARFCN BCCH –120 . 0 .. Note that this element does not itself refer to an adjacent channel but to the C0. etc. 63 * h+ Description C/A measurement: ARFCNs used by current serving cell. Argument: 0 means the first channel in the hopping list. 63 h+ C/A measurement: Same as Scanned Adjacent RxLev –2 (dBm) but applies to channels at –200 kHz. TCHs in dedicated mode.. Same as Scanned Adjacent ARFCN –2 but for the channels at +400 kHz..... BCCHs in idle mode and TCHs in dedicated mode. BCCHs are shown in idle mode. 63 h+ Scanned Adjacent RxLev –1 (dBm) Scanned Adjacent RxLev C0 (dBm) –120 . Argument: 0 gives the RxLev of the first channel in the hopping list. etc. 63 h+ 0 .Chapter 3. etc. –10 dBm 0 . C/A measurement: Scanned signal strength of the channels used by the current serving cell. Argument: 0 gives the RxLev of the channel adjacent to the first channel in the hopping list.. . C/A measurement: C/A values corresponding to Scanned Adjacent RxLev +1 (dBm). Scanned BSIC On ARFCN 00 . (not ARFCN). 846 s BSICs of scanned channels. Argument: 0 points to the channel with the lowest frequency. 846 s Scanned Band 450 . 63 h+ 0 . 63 h+ See ARFCN BCCH 0 . 77 (octal) See range of ARFCN BCCH 0 ... 1900 MHz 0 ... (not ARFCN)... –10 dBm 0 .. Argument: ARFCN. etc.. ARFCNs of scanned channels. Scanned C/A –2 (dB) Scanned C/A –1 (dB) Scanned C/A +1 (dB) –100 ... Argument: 0 gives the BSIC of the channel with the lowest frequency.. 100 dB –100 . Scanned BSIC 00 . C/A measurement: Same as Scanned Adjacent RxLev –2 (dBm) but applies to channels at +400 kHz.... Argument: 0 points to the channel with the lowest frequency.... (not ARFCN). 63 s BSICs of scanned channels.0: Information Elements and Events IE Name Scanned Adjacent RxLev +1 (dBm) Scanned Adjacent RxLev +2 (dBm) Scanned ARFCN Range/Unit –120 . 846 s Frequency bands of scanned channels in numeric format... –120 .. C/A measurement: C/A values corresponding to Scanned Adjacent RxLev –1 (dBm).. 100 dB h+ C/A measurement: C/A values corresponding to Scanned Adjacent RxLev –2 (dBm).TEMS Investigation 11. 0 .. 100 dB –100 .... 63 h+ 48 .... –10 dBm Arg 0 . etc. 77 (octal) 0 .. etc... 63 * h+ Description C/A measurement: Same as Scanned Adjacent RxLev –2 (dBm) but applies to channels at +200 kHz. etc.. –10 dBm 0 .. (not that with the lowest ARFCN). Obtained only if both ARFCN and BSIC are scanned. LZT 138 0375 R1A 49 . 846 c s Cell names for scanned channels. 846 See range of ARFCN BCCH See range of ARFCN BCCH s s Same as Scanned RxLev but in dBm.. 847 – s Number of channels currently scanned. 846 s Scanned Cell Name Text 0 .. Argument: 0 points to the channel with the lowest frequency..... Received signal strength of scanned channels..Chapter 3. 0 . Received signal strength of scanned channels. Argument: 0 points to the channel with the lowest frequency.. Argument: 0 points to the channel with the lowest frequency.. 100 GSM RxLev units –120 ... (not ARFCN). 63 * h+ Description C/A measurement: C/A values corresponding to Scanned Adjacent RxLev +2 (dBm). C/I values for scanned channels. 846 s Scanned RxLev (dBm) Scanned RxLev On ARFCN Scanned RxLev On ARFCN (dBm) –120 . Information Elements IE Name Scanned C/A +2 (dB) Scanned C/I Range/Unit –100 . (not ARFCN). 35 dB Arg 0 . 100 GSM RxLev units 0 ... Argument: ARFCN. Scanned Channels No Of Scanned RxLev 0 . 100 dB –5 . etc. –10 . –10 dBm –10 ...... s Same as Scanned RxLev On ARFCN but in dBm. etc... Requires cell file... 16.4. which is an average over all channels in the hopping list.TEMS Investigation 11. 1. This element thus gives more information than RxLev.1.1. 16. 2 Arg – * Description Use of “lock on channel” function in phone.6. 63 h+ Signal strength of each channel in the hopping list.4. but not yet activated 2: Activated Signal Strength Hopping List –120 . –10 dBm 0 .0: Information Elements and Events IE Name Serving Cell List Active Range/Unit 0. 50 . Argument: 0 means the first channel in the hopping list..1..2. 16.3.4...2. etc. 0: Not activated 1: Ordered by user.2. See UM sections 16.2. Information Elements IE Name Signal Strength On BCCH Carrier Range/Unit –120 . Neighbor list..”. 3. SNDCP BLER DL (%) SNDCP BLER UL (%) SNDCP Bytes Received DL SNDCP Bytes Sent UL 0 .. Invalid if no value is found in any of the above steps. The following steps are used to find a value for the element: 1... 2 · 109 bytes – g Percentage of SNDCP data blocks erroneously decoded on downlink. Idle mode.. Number of bytes received at the SNDCP protocol level since GPRS attach. 100 % 0 . If frequency hopping is not used... Especially useful for obtaining a correct measure of the cell size when frequency hopping is used and power control is applied to the TCHs.. If the BCCH frequency is in the neighbor list. 2 · 109 bytes 0 .. report its signal strength. – – g g – g LZT 138 0375 R1A 51 . 2. report RxLev (dBm). Percentage of SNDCP data blocks resent on uplink. step 2 becomes “If BCCH = TCH . If the phone is in idle mode. report its signal strength. Number of bytes sent at the SNDCP protocol level since GPRS attach.Chapter 3.. Hopping list.. If the BCCH is used as hopping frequency (in dedicated mode). –10 dBm Arg – * Description Signal strength on the current BCCH. 100 % 0 .. 2). Speed in mph.. 930 . 250 km/h 0 . 155 mph – – p p Speed in km/h. but excluding retransmissions) on downlink at SNDCP protocol level..g. 800 ms 1 . AQM: The length of time it takes for the speech to travel from the Call Generator to the MTU and back to the Call Generator again... Spectrum analysis: The number of downlink frequencies swept by the scan. Spectrum analysis: RSSI of downlink frequencies scanned. Spectr Ana Sc DL Freq Spectr Ana Sc DL No of Freq Spectr Ana Sc DL RSSI (dBm) Speech Codec Speech Path Delay ss –130 . Data throughput (including protocol headers. 52 . but excluding retransmissions) on uplink at SNDCP protocol level.. This element only appears in merged logfiles (see UM section 36. 2560 – – ss Speed (km/h) Speed (mph) 0 ..... –20 dBm Text 0 .. 400 kbit/s – g These elements are obtained from spectrum analysis. e.0: Information Elements and Events IE Name SNDCP Throughput DL (kbit/s) SNDCP Throughput UL (kbit/s) Spectr Ana IEs: General remark Range/Unit 0 ... 2560 – ss Spectrum analysis: Scanned frequencies on downlink in ascending order... 400 kbit/s Arg – * g Description Data throughput (including protocol headers... 960 MHz 0 .. Currently used speech codec. where present. 0 . The argument.. “EFR”. is simply a sequence number pointing to scanned frequencies as indicated by the “Spectr Ana Sc DL Freq” element...TEMS Investigation 11. 2560 1 . 90 kbit/s: 24 dBQ 5.15 kbit/s: 21 dBQ 4..2 kbit/s: 28 dBQ 7. 5 MOS See ARFCN BCCH – 0 . Information Elements IE Name SQI Range/Unit –20 ...70 kbit/s: 27 dBQ 5. 22 dBQ EFR (Enhanced Full Rate): –20 . 30 dBQ AMR: Dependent on codec mode. etc. When neighbor list scanning is performed..2 kbit/s: 30 dBQ 10. The maximum SQI values are as follows: 12. and then all other channels follow. Argument: Except in the case of neighbor list scanning. 0 means the strongest channel of those currently scanned. all neighbors come first.75 kbit/s: 19 dBQ Non-existent for GPRS (no voice data in packets). 30 dBQ Arg – * g– Description Speech Quality Index.. See UM chapter 29. See UM chapter 29. The range depends on the speech codec used: HR (Half Rate): –20 ...95 kbit/s: 28 dBQ 7.. LZT 138 0375 R1A 53 . SQI MOS Strongest Scanned ARFCN 1 . 17 dBQ FR (Full Rate): –19 . 846 g– s SQI expressed on the MOS scale..40 kbit/s: 27 dBQ 6. ARFCNs of scanned channels sorted by decreasing signal strength.. both channel sets being sorted internally by decreasing signal strength..Chapter 3.. 846 c s Names of scanned channels sorted by decreasing signal strength. 846 s C/I for scanned channels sorted by decreasing signal strength. Argument: See Strongest Scanned ARFCN. For the significance of the parameter value. Strongest Scanned RxLev (dBm) –120 ... Strongest Scanned C/I –5 . 0 .. Sub Channel Number TA 0 . Strongest Scanned BSIC Text 0 .. Argument: See Strongest Scanned ARFCN. Strongest Scanned Cell Name Text 0 .. 63 See Description – 54 . 1900 MHz Arg 0 ... 846 s Signal strength of scanned channels in descending order...010. 846 * s Description Frequency bands of scanned channels sorted by decreasing signal strength. see 3GPP 45.0: Information Elements and Events IE Name Strongest Scanned Band Range/Unit 450 .... Argument: See Strongest Scanned ARFCN...TEMS Investigation 11.. 7 – Number of subchannel used in SDCCH or TCH half-rate channel.. 35 dB 0 . Requires cell file. –10 dBm 0 .. Argument: See Strongest Scanned ARFCN. Timing Advance.. 846 s BSICs of scanned channels sorted by decreasing signal strength.. Obtained only if both ARFCN and BSIC are scanned. Argument: See Strongest Scanned ARFCN. Valid only in dedicated mode.. .. –116 . Used to identify a one-block flow. 127 1 . Argument: Neighbors sorted by signal strength in descending order. 31 – g Time Text – LZT 138 0375 R1A 55 .. –25 dBm 0 . but not yet activated 2: Activated TD-SCDMA Neighbor Cell Parameter ID 0 .Chapter 3.2..mm... UARFCN of each TD-SCDMA neighbor measured in GSM mode. Current time in text format: HH:MM:SS.... where mm = decimal seconds. see UM section 16.. 31 1 . Information Elements IE Name Target Handover Range/Unit 0....4. 1.8).. Received signal code power of each TD-SCDMA neighbor measured in GSM mode. 2 Arg – * Description Use of lock handover function in phone (handover restricted to a chosen set of cells. 32 Neighbor Cell Parameter Identity of TD-SCDMA cells measured by TD-SCDMA capable phone while in GSM mode. TFI UL 0 ... 32 – Number of TD-SCDMA neighbors measured in GSM mode. 0: Not activated 1: Ordered by user.. 16383 (frequency band dependent) 0 . 32 TFI DL – g Temporary Flow Id on uplink.. Temporary Flow Id on downlink. TD-SCDMA Neighbor No Of TD-SCDMA Neighbor RSCP TD-SCDMA Neighbor UARFCN 1 . Used to identify a one-block flow. 32 1 . . 7 Text – 0 . 0 represents the first used timeslot. Valid only in dedicated mode.. Timeslots used on uplink. This element occurs only in logfiles from TEMS Automatic.. Same as TLLI. Type of channel in each timeslot on downlink. Text 0 .... See Channel Type... etc.. g Uplink State Flags. 7 – – – Training Sequence Code Uplink State Flag 0 . 7 0 . 7 Text Text 0 .. represents a timeslot but is just a sequence number. Temporary Logical Link Identifier. 0 . 0 . 7 0 . Identifier of tone event in TEMS Automatic configuration database (table tToneTemplate). but coded as hexadecimal. indicating to the phone when it is allowed to send...0: Information Elements and Events IE Name Timeslot IEs: General remark Timeslot Timeslot Channel Type DL Timeslot Channel Type UL Timeslot Used DL Timeslot Used UL TLLI TLLI (Hex) Tone Event Range/Unit Arg * Description The argument. That is. 60000 0 . 7 g hs g hs g hs g hs g g Timeslot used for current call. See Channel Type.. 7 – Current training sequence code... where present. the argument value does not equate to the corresponding timeslot index. Type of channel in each timeslot on uplink. 7 56 . 1 the second.. Timeslots used on downlink.. Argument: Timeslot sequence number (compare Timeslot IEs: General remark).. 232 – 1 Text 0 ..TEMS Investigation 11.. one for each timeslot.. . Argument: See WCDMA Neighbor CPICH Ec/No.. WCDMA Neighbors No Of Weakest Scanned ARFCN – Number of measured WCDMA neighbors. 846 LZT 138 0375 R1A 57 . 32 * Description CPICH Ec/No of measured WCDMA neighbors. 16383 (frequency band dependent) 0 . 0 means the weakest channel of those currently scanned. etc.. (The “Weakest” element serves no purpose in this context. WCDMA Neighbor UARFCN 0 ... Argument: Except in the case of neighbor list scanning. When neighbor list scanning is performed.. 32 CPICH RSCP of measured WCDMA neighbors. 32 1 . 32 ARFCNs of measured WCDMA neighbors... 0 . Argument: See WCDMA Neighbor CPICH Ec/No... Argument: See WCDMA Neighbor CPICH Ec/No.Chapter 3. 0 dB Arg 1 . 32 Scrambling codes of measured WCDMA neighbors....) See ARFCN BCCH 0 .. etc. –15 dBm 1 .. WCDMA Neighbor CPICH RSCP (dBm) WCDMA Neighbor SC –140 . channels are sorted exactly in the opposite order to Strongest Scanned ARFCN.. Argument: 1 gives the neighbor with the highest signal strength. Information Elements IE Name WCDMA Neighbor CPICH Ec/No (dB) Range/Unit –34 . 511 1 .. s ARFCNs of scanned channels sorted by increasing signal strength.... Weakest Scanned C/I –5 .. 846 s BSIC of scanned channels sorted by increasing signal strength. Weakest Scanned BSIC Text 0 . Argument: See Weakest Scanned ARFCN. 846 * s Description Frequency bands of scanned channels sorted by increasing signal strength. 1900 MHz Arg 0 .. Argument: See Weakest Scanned ARFCN. Weakest Scanned RxLev (dBm) –120 . –10 dBm 0 ...TEMS Investigation 11.. 846 s Signal strength of scanned channels in ascending order.. 846 c s Names of scanned channels sorted by increasing signal strength. Argument: See Weakest Scanned ARFCN. 58 ...0: Information Elements and Events IE Name Weakest Scanned Band Range/Unit 450 . 35 dB 0 .... Weakest Scanned Cell Name Text 0 . Requires cell file. Argument: See Weakest Scanned ARFCN. 846 s C/I for scanned channels sorted by increasing signal strength.. Obtained only if both ARFCN and BSIC are scanned. Argument: See Weakest Scanned ARFCN..... Notes on Quantities Denoting Signal Power Below is a list of the signal power and power ratio quantities that appear in the names of information elements. LZT 138 0375 R1A 59 . Reported from network search scanning. Information Elements 3.215. or requires positioning data to make sense. Es: Scrambling code energy per chip (as measured by a scanning device during the SCH timeslot scan). Compare No above. WCDMA Information Elements Properties of Information Elements: The Asterisk Column In the column marked *. Ec/No: Signal-to-noise ratio (as measured by a UE).5. a set of codes is used to identify certain groups of information elements: Code c dv ne ns p pi rs ss ts Meaning Requires that a cell file has been loaded.1. Ec: Scrambling code energy per chip.2. Io: Total energy per chip (as measured by a scanning device). Reported when running DVB-H. section 5. No: Total energy per chip (as measured by a UE). See 3GPP 25. Reported from pilot scanning. • • • • • • Eb: Scrambling code energy per bit. GSM neighbor measurements reported by the UE while in WCDMA mode. Reported from SCH timeslot scanning. Reported from RSSI scanning. Reported from spectrum scanning. Reported by positioning equipment.Chapter 3. 60 . 8848 m Arg – * p Description Height above sea level in feet.1). section 5. Information Element Table IE Name Altitude (ft) Range/Unit –1312 .2. SIR: Signal-to-interference ratio as measured on the DPCCH. The corresponding IEs without a suffix are populated in the single-antenna case. “Sum”. “AMR Codec” IEs: General remark These elements are valid also in GSM mode. RSCP: Received signal code power. identical with Ec: see 3GPP 25.1. identical with No: see 3GPP 25.5.1. Multiple-antenna vs. Eb and Ec are related by the equation that is. section 5..0: Information Elements and Events • • • • Ec/Io: Signal-to-noise ratio (as measured by a scanning device).5. and the suffixes refer to the use of multiple antennas in the MIMO technology..TEMS Investigation 11.2.215. 29028 ft –400 .. RSSI: Received signal strength indicator. “Antenna 1”. “Antenna 2”. See 3GPP 25. where they appear side by side with the more elaborate GSM-specific elements relating to AMR (see section 3. Such IEs are populated for MIMO. Altitude (m) – p Height above sea level in meters..215. Compare Io above. section 5. Single-antenna Information Elements Certain information elements occur in variants with one of the suffixes “per Antenna” (with argument).215. AMR Codec Usage (UL) 0 . Requires cell file. AS CPICH Ec/No –34 . 8 * Description Names of AMR codecs..... AS CPICH RSCP –140 .... –15 dBm 1 ..75 kbit/s AMR Codec Usage (DL) 0 . Argument: See AMR Codec Name.70 kbit/s 6: 5..95 kbit/s 4: 7. 100 % 1 . Argument: Active set ID identifying an active set member... 6 CPICH Ec/No of each active set member... LZT 138 0375 R1A 61 . Argument: Identifies the AMR codec. 6 CPICH received signal code power of each active set member. Argument: Active set ID. Also occurs in MIMO variants: Antenna 1.Chapter 3. Antenna 2....40 kbit/s 5: 6. 1: 12. 8 Current distribution of AMR codec usage on uplink. 0 dB 1 .15 kbit/s 8: 4. 8 Current distribution of AMR codec usage on downlink.. 100 % 1 . Information Elements IE Name AMR Codec Name Range/Unit Text Arg 1 ...90 kbit/s 7: 5. AS Cell Name Text 1 . 6 c Cell name of each active set member..2 kbit/s 3: 7. Argument: See AMR Codec Name. Argument: Active set ID. Sum.2 kbit/s 2: 10. 0: Information Elements and Events IE Name AS No Of Members AS SC Range/Unit 0 . 16383 (frequency band dependent) 0 . Argument: Active set ID. 100 % – – 62 .4.. overriding BLER target set by network... 0 .. 100 % 1 . Averaged BER (%) – Bit error rate.12). Averaged over reporting period... 6 Arg – * Description The number of base stations in the active set.2... Scrambling code of each active set member. Same as BLER Target Control but in text format. 511 1 ... Reported in Q11 format. A 100% error figure means 2047 detected errors. Calculated as: # ends / (# blocks + # drops + # ends) where blocks = Blocked Call events drops = Dropped Call events ends = Call End events Only events occurring in WCDMA mode are counted...TEMS Investigation 11. Argument: Active set ID. BLER Target Control (Text) Call Event Success Rate Text 0 . 6 AS UARFCN DL 0 . BLER Target Control 0 .. 6 Downlink UARFCN of each active set member.. Valid only in state Cell_DCH... 63 – BLER Target value set on phone property page (UM section 16. measured using either the pilot bits or the TPC bits on the DPCCH channel (choice depends on slot format). 1 – Use of cell barring related functions in phone.. 16.3. 16.3.11.2. Use of compressed mode. MT) Range/Unit 0 .Chapter 3. 1 = True. 60000 ms Arg – * Description For MTU mobile-terminated (MT) calls.2.1. This element occurs only in logfiles from TEMS Automatic.2.. This element occurs only in logfiles from TEMS Automatic. Information Elements IE Name Call Setup Time (Total. 255 – rs RSSI scanning: Number of UARFCNs scanned.2. CW Sc No of UARFCNs 0 . This element occurs only in logfiles from TEMS Automatic.4.4. 16. Caller Identification Success 0 . Same as Cell Barred Control but in text format... Calling Phone Number Text – Phone number of the party that placed the call (whether mobileoriginated or mobileterminated)..4. 0: False 1: True Cell Barred Control (Text) Compressed Mode Text 0. time from last dialed tone until alerting tone was generated in the MTU phone device. See UM sections 16.4. 1 – This element tells whether the calling party’s phone number was identical with the number presented to the called party. LZT 138 0375 R1A 63 . 0 = False. See UM section 10. Cell Barred Control 0. 1 – – CW scanning: Synonymous with RSSI scanning..3. ... Argument: Neighbor identity. CW Sc UARFCN 0 . 16383 (frequency band dependent) 1 .0: Information Elements and Events IE Name CW Sc RSSI Range/Unit –130 .. 64 .TEMS Investigation 11. Antenna 2. 6 CPICH received signal code power of each detected neighbor... Argument: Neighbor identity.. Det Neigh CPICH RSCP –140 .. Sum. –20 dBm Arg 1 .. 255 * rs Description RSSI scanning: RSSI of UARFCNs scanned. Argument: 0 gives the first channel currently scanned.. 0 dB 1 . 6 CPICH Ec/No of each detected neighbor. sorted in ascending order. Requires cell file. 6 CPICH transmit power of each detected neighbor. Argument: Neighbor identity. Also occurs in MIMO variants: Antenna 1. 255 rs RSSI scanning: UARFCNs of channels scanned. Det Neigh Cell Name Text 1 ... Argument: The channels are sorted by ascending UARFCN.. –15 dBm 1 ... The argument 1 gives the channel with the lowest UARFCN..... Argument: Neighbor identity. Det Neigh CPICH Ec/No –34 . 0 . Det Neigh CPICH Tx Power Det Neigh No Of Members –31 ... 50 dBm 1 .... etc. 1 the second. 6 c Cell name of each detected neighbor. 6 – Number of detected neighbors. 3. See ETSI TR 102 377 V1. 100 % –5 .. Information Elements IE Name Det Neigh Pathloss Range/Unit 30 .. 165 dB Arg 1 . Calculated as Primary CPICH Tx Power – CPICH RSCP. 16383 (frequency band dependent) –135 .1. DPCCH ISCP DL DPCCH Power UL DPCCH RSCP DL DTX Rate DL DVB-H BER DVB-H C/N DVB-H MFER – – – – – – – dv dv dv DPCCH interference signal code power on downlink. DVB-H carrier-to-noise ratio.. DVB-H Rx Power –128 . Use of DTX on downlink for the voice service. Det Neigh SC 0 .1... 511 1 ... section 10. DVB-H received signal power. DVB-H frame error rate after MPE-FEC decoding.. DPCCH transmit power on uplink. 100 % 0 . 6 * Description Pathloss of each detected neighbor. DPCCH received signal code power on downlink.. Argument: Neighbor identity.. 33 dBm –135 . 6 Downlink UARFCN of each detected neighbor...... –20 dBm – dv LZT 138 0375 R1A 65 ...2... 100 % 1 .. –15 dBm –50 . 35 dB 0 .. DVB-H bit error rate. Argument: Neighbor identity.. Argument: Neighbor identity. –15 dBm 0 .Chapter 3...2.. 6 Scrambling code of each detected neighbor.... Det Neigh UARFCN DL 0 . Argument: Rake finger number.. These elements are provided for bar chart plotting.. – 1 ...... 511 1 . Argument: Rake finger number.. Argument: Rake finger number. Ec/No Finger . Finger . Argument: Rake finger number....TEMS Investigation 11.0: Information Elements and Events IE Name “Finger” IEs: General remarks Range/Unit Arg * Description The Rake fingers are not sorted by signal strength. 15 1 ...) refers to a UMTS frequency. The Finger Slot Pos element is of course not needed in the Finger Position series and is consequently absent from it... etc..... 0 dB 0 . The “Finger” and “Finger Position” series of elements contain the same data. Slot Pos 1 . The latter series consists of arrays of size 2560 corresponding to the sequence of chips in a radio frame timeslot. SC 1 .. RSCP for each Rake finger. 48 Position (chip index) of each Rake finger within the radio frame timeslot... –20 dBm 0 . Slot 0 . No Of Finger .. Finger . 48 Radio frame timeslot index for each Rake finger.... Finger . Position Type). Argument: Rake finger number. 48 –140 ..... with the received finger information positioned at the correct indices.. Finger . The Motorola E1000 may report finger measurements on a number of different channels (see the elements Finger . 1 .. Separate sets of Finger elements are provided for the full number of UMTS frequencies that can be scanned simultaneously.. the other devices that support finger measurements always report them on the CPICH.. 48 Scrambling code for each Rake finger. –15 dBm –130 .. Argument: Rake finger number. they come in the order they are reported... 48 Ec/No for each Rake finger. RSCP Finger . 2560 1 ... The ordinal (“1st”. 66 .... 48 Total number of Rake fingers. RSSI –34 . 48 RSSI for each Rake finger. Argument: Rake finger number.. 2560 Same as Finger .. 16383 (frequency band dependent) Text 1 . Argument: Chip index. 2560 Same as Finger .. 48 UARFCN for each Rake finger... Argument: Chip index. 0 dB 1 . –15 dBm 1 ..... Finger ...... RSCP (see general remarks)... Position RSSI –130 . RSSI (see general remarks). Finger . 16383 (frequency band dependent) –34 . Position RSCP –140 ... Argument: Chip index. 48 * Description Type of channel on which each Rake finger is reported (e... Slot (see general remarks).. Argument: Chip index. SC (see general remarks). Argument: Rake finger number... 2560 Same as Finger .... Finger . Argument: Chip index.g... Position UARFCN 0 . Information Elements IE Name Finger . Ec/No (see general remarks).... Argument: Chip index.. Finger . Argument: Chip index..... 2560 Same as Finger . UARFCN (see general remarks)... UARFCN 0 .. CPICH)...Chapter 3.. 2560 Same as Finger . Type (see general remarks).. Position Type Text 1 . Finger ... –20 dBm 1 .. LZT 138 0375 R1A 67 .. Firmware Version – Version number of device firmware..... Position SC 0 . 15 1 . Position Ec/No 1 .. Position Slot 0 ... 2560 Same as Finger . Finger . 511 1 . 2560 Same as Finger .. Type Range/Unit Text Arg 1 .... Finger ...... Finger .. ..... etc. 6 – – – p Device model.. because no cell file loaded) 1: Soft 2: Softer 3: Hard 4: Handover to UTRAN 5: Handover from UTRAN 6: GSM HO Event Type (Text) Text – Same as HO Event Type but in text format. Type of latest handover.. GSM Neigh BSIC Text GSM Neigh No Of GSM Neigh RxLev 0 . 32 ne ARFCNs of measured GSM neighbors. Argument: 1 gives the neighbor with the highest signal strength. page 23.0: Information Elements and Events IE Name Frequent AQM elements GSM Neigh ARFCN Range/Unit Arg * Description See the description (cellular technology independent) under GSM.. –10 dBm – 1 .. 360 degrees 0 . Received signal strength of measured GSM neighbors. Argument: See GSM Neigh ARFCN. 32 ne ne Number of measured GSM neighbors. Hardware Heading (deg) HO Event Type Text 0 .g. Argument: See GSM Neigh ARFCN. 32 –120 .1 under “ARFCN BCCH” 1 . Direction of travel measured in degrees clockwise from north. 68 .. 32 ne Base Station Identity Codes (in text format) of measured GSM neighbors. See section 3.... 1 . 0: Unknown (e..TEMS Investigation 11. The maximum value of the CQI (Channel Quality Indicator) during the latest reporting period. Argument: Carrier index. HS CQI (Min) 0 ..... The definition of the CQI values is given in 3GPP 25. 30 0 . Arg 1 is used only for dual carrier sessions. Argument: Carrier index.2. Arg 1 is used only for dual carrier sessions.. see general remarks on these. section 6A. Compare HS CQI (Max). 0 ..... expressed as a percentage of time. 100 % 0 . HS 16-QAM Modulation Rate HS 64-QAM Modulation Rate HS CQI (Max) – 0 .. Information Elements IE Name “HS” IEs: General remark Range/Unit Arg * Description All elements starting with “HS” (including channel names in HS-) relate to HSPA. Use of 64-QAM as modulation method... 100 % 0 . 1 HS CQI (Median) 0 . 30 See Description – Use of 16-QAM as modulation method. 1 The minimum CQI value during the latest reporting period.. Arg 1 is used only for dual carrier sessions. Special subgroups are “HS MIMO” and “HS UL”.Chapter 3.. 30 0 . expressed as a percentage of time.. 1 The median CQI value during the latest reporting period. Argument: Carrier index. LZT 138 0375 R1A 69 .214. Compare HS CQI (Max).. . A value of zero means that the UE shall not transmit any CQI information..214.TEMS Investigation 11. Same as HS-DSCH BLER Residual but for each active HARQ process separately. section 6A... Residual block error rate on the HS-DSCH (decoding unsuccessful after maximum number of retransmissions)..2). Arg 1 is used only for dual carrier sessions. Argument: Carrier index.. 16 HS-DSCH DTX Rate 0 . Argument: Carrier index. controlling how often the UE transmits new CQI information on the uplink (see 3GPP 25..... 100 % 0 . 0 ...2). 100 % – – Block error rate on the HSDSCH for first transmission. ACK / (NACK + ACK) ratio on the HS-DSCH. 1 DTX rate on the HS-DSCH: Percentage of TTIs estimated by the phone as “not used” on downlink...1.. Argument: HARQ process index.. 1 HS-DSCH BLER 1st HS-DSCH BLER Residual HS-DSCH BLER Residual Per Process 0 .1.214. HS-DSCH Error Blocks 1st No Of 0 . Arg 1 is used only for dual carrier sessions.. HS CQI Repetition Factor HS-DSCH ACK Rate 0 .. section 6A. 15 – 0 . 255 ms * 2 Arg – * Description CQI feedback cycle.. 100 % 0 . 70 . 100 % 0 . 100 % 0 .. CQI repetition factor.. 100 – Number of block errors on the HS-DSCH (first transmission).0: Information Elements and Events IE Name HS CQI Feedback Cycle Range/Unit 0 .. controlling how often the UE repeats CQI information on the uplink (see 3GPP 25. . 0 . NACK / (NACK + ACK) ratio on the HS-DSCH. Argument: HARQ process index. 100 % 0 . Retransmission rate on the HSDSCH. Same as HS-DSCH Error Blocks Residual No Of but for each active HARQ process separately. Arg 1 is used only for dual carrier sessions... 100 Arg – * Description Number of residual block errors on the HS-DSCH (decoding unsuccessful after maximum number of retransmissions). 100 0 . 16 New transmission rate on the HS-DSCH for each active HARQ process.. 100 % 0 . 0 .... Information Elements IE Name HS-DSCH Error Blocks Residual No Of HS-DSCH Error Blocks Residual No Of Per Process Range/Unit 0 . 0 ... 16 – Number of active HARQ (Hybrid Automatic Repeat Request) processes on the HS-DSCH. 100 % – LZT 138 0375 R1A 71 .. 100 % – HS-DSCH Retransmission Rate 0 . 1 HS-DSCH New Transmission Rate Per Process HS-DSCH Post Rate 0 .. Argument: HARQ process index. Argument: Carrier index... 16 HS-DSCH HARQ Processes No Of HS-DSCH NACK Rate 0 .Chapter 3...... 100 % – Rate of use of postamble indicator after TTI where data is sent.. notifying the Node B of the fact that the ACK/NACK sequence ends. HS-DSCH Pre Rate 0 ... notifying the Node B of the fact that a sequence of ACKs/NACKs will be sent. Rate of use of preamble indicator prior to TTI where data is sent.. . 1 – Text – HS H-RNTI HS MAC Queue ID DL 0 . 16 * Description Same as HS-DSCH Retransmission Rate but for each active HARQ process separately.. Argument: HARQ process index. 65535 0 . 100 – Number of retransmitted blocks on the HS-DSCH... Argument: MAC-hs priority queue index.. Indicates whether the current HS session is a dual carrier session.. the string is blank. Indicates whether the current HS session is a dual carrier session. the text string reads “Active”... HS-DSCH Radio Network Temporary Identity. if not.0: Information Elements and Events IE Name HS-DSCH Retransmission Rate Per Process Range/Unit 0 . HS-DSCH Retransmissions HS-DSCH Throughput (kbit/s) 0 . 32 72 . from all HARQ processes taken together... Throughput on the HS-DSCH: The rate at which data is received by the MAC-hs reordering queue distribution layer (as defined in 3GPP 25. 100 % Arg 0 .. MAC-hs priority queue identity. 0 .. If so.321)....TEMS Investigation 11. 80000 kbit/s – HS Dual Carrier Session HS Dual Carrier Session (Text) 0 .. 127 – 1 . 0 .. expressed as a percentage of time. 100 % 1 .... 30 1 .. The definition of the CQI values is given in 3GPP 25. HS MIMO 16QAM Modulation Rate HS MIMO 64QAM Modulation Rate HS MIMO CQI (Max) 0 .214. 30 1 ... where present. Compare HS MIMO CQI (Max). 2 LZT 138 0375 R1A 73 . However. expressed as a percentage of time..2. certain other HS elements of a general nature are updated also during MIMO activity. The argument.. Compare HS MIMO CQI (Max). 2 The median CQI value during the latest reporting period....214.. Regarding the designation “MIMO Type A”. 100 % 1 .. Use of 64-QAM as modulation method. The maximum value of the CQI (Channel Quality Indicator) during the latest reporting period. has the following significance: • • Arg = 1 means MIMO Type A with one transport block..2. 2 The minimum CQI value during the latest reporting period.. 2 0 . see 3GPP 25. Non-MIMO IEs which have a counterpart among MIMO IEs (such as the CQI elements) are not updated while MIMO is being used.. HS MIMO CQI (Median) 0 .. 100 % 1 . Information Elements IE Name “HS MIMO” IEs: General remark Range/Unit Arg * Description These IEs are populated when MIMO is in use on the downlink. 2 ACK / (NACK + ACK) ratio on the HS-DSCH. section 6A..1.. HS MIMO DSCH ACK Rate 0 .2.. Arg = 2 means MIMO Type A with two transport blocks... HS MIMO CQI (Min) 0 . 2 Use of 16-QAM as modulation method. section 6A..Chapter 3. 30 See Description 1 . Residual block error rate on the HS-DSCH (decoding unsuccessful after maximum number of retransmissions).... 2 1 .. 100 % Arg 1 ..0: Information Elements and Events IE Name HS MIMO DSCH BLER HS MIMO DSCH BLER Residual HS MIMO DSCH Error Block 1st No Of HS MIMO DSCH Error Block Residual No Of HS MIMO DSCH NACK Rate HS MIMO Multi TB Rate Range/Unit 0 .. 2 1 . 0 . 100 % 1 . 2 * Description Block error rate on the HSDSCH for first transmission. Number of block errors on the HS-DSCH (first transmission). 80000 kbit/s 1 . Argument = 2: Percentage of TTIs with two transport blocks used.. The element gives an estimate of the throughput on the assumption that all blocks were successfully transferred. 74 ... and the CRC indication does not matter... 2 0 .. 100 % 1 .. 100 % 1 ..TEMS Investigation 11.. 2 Calculated as: (sum of TBSs for non-DTX blocks) / (total TTI time for non-DTX blocks) Only blocks sent to this phone are considered in the calculation..... 2 Number of residual block errors on the HS-DSCH (decoding unsuccessful after maximum number of retransmissions). 0 . 100 % 0 . Argument = 1: Percentage of TTIs with one transport block used.. 2 HS MIMO Phy Scheduled Throughput (kbit/s) 0 ..... NACK / (NACK + ACK) ratio on the HS-DSCH.... 100 % 0 .. . Block counts for all possible HSPA transport block sizes in the primary MIMO stream. The element reflects the actual physical channel throughput. 295 Block counts for HSPA transport block sizes currently in use in the primary MIMO stream. accumulated over the current session. 2 * Description Calculated as: (sum of TBSs for blocks with CRC OK) / (reporting period) Only blocks sent to this phone are considered in the calculation. collected over the latest report period.. 65535 1 . 65535 1 . Information Elements IE Name HS MIMO Phy Served Throughput (kbit/s) Range/Unit 0 . 65535 1 . 295 Block counts for HSPA transport block sizes currently in use in the primary MIMO stream... HS MIMO QPSK Modulation Rate HS MIMO Transport Block Count Primary (Abs) 0 . and the CRC must be OK. 0 . Argument: The transport block size itself in bits (not an index). 100 % 1 ... 2 Use of QPSK as modulation method.Chapter 3. Argument: Transport block size sequence number.. 80000 kbit/s Arg 1 ...... expressed as a percentage of time. LZT 138 0375 R1A 75 .... accumulated over the current session.. 42192 HS MIMO Transport Block Count Primary (Accu) 0 ... HS MIMO Transport Block Count Primary (Curr) 0 ... Argument: Transport block size sequence number. Argument: Transport block size sequence number. HS MIMO Transport Block Count Secondary (Accu) 0 .... collected over the latest report period.. 0 .. 295 Number of HSPA transport block sizes currently in use in the primary MIMO stream.. Argument: Transport block size sequence number. HS MIMO Transport Block Size Primary HS MIMO Transport Block Size Secondary HS MIMO Transport Block Sizes Primary No Of 0 ... Argument: Transport block size sequence number.... 0 .. 295 HS-DSCH transport block sizes in the secondary MIMO stream. 42192 bits 1 .TEMS Investigation 11. 65535 1 .. 65535 Arg 1 . Argument: The transport block size itself in bits (not an index). 76 .. accumulated over the current session... Argument: Transport block size sequence number..0: Information Elements and Events IE Name HS MIMO Transport Block Count Secondary (Abs) Range/Unit 0 .. 295 Block counts for HSPA transport block sizes currently in use in the secondary MIMO stream. Argument: Transport block size sequence number. 42192 * Description Block counts for all possible HSPA transport block sizes in the secondary MIMO stream. accumulated over the current session... 295 HS-DSCH transport block sizes in the primary MIMO stream. 295 Block counts for HSPA transport block sizes currently in use in the secondary MIMO stream. 65535 1 . HS MIMO Transport Block Count Secondary (Curr) 0 .. 42192 bits 1 . 295 1 .... 2. Argument = 2: Percentage of TTIs with MIMO Type A CQI and two transport blocks used. 100 % – Percentage of TTIs with MIMO Type B CQI... so that values are computed as percentages of all blocks. HS MIMO Type (Text) HS MIMO Type A CQI Rate Text 0 .. 0 .214. Argument: Channelization code index. Information Elements IE Name HS MIMO Transport Block Sizes Secondary No Of HS MIMO Type Range/Unit 0 . Argument: Transport block size sequence number.Chapter 3. section 6A.1.1.. 295 * Description Number of HSPA transport block sizes currently in use in the secondary MIMO stream.2. See 3GPP 25. 295 Arg 1 .. section 6A. 100 % 1 .....2. 1 – 0: MIMO Type A with one transport block 1: MIMO Type A with two transport blocks Same as HS MIMO Type but in text format.2.. 15 Distribution of channelization code usage on the HS-PDSCH for the whole of the HSPA session. 100 % – 1 . whether used or unused. LZT 138 0375 R1A 77 .... This element does not take DTX into account.. Argument = 1: Percentage of TTIs with MIMO Type A CQI and one transport block used.. See 3GPP 25..214. HS-PDSCH Code Usage (Accu) % 0 . 2 HS MIMO Type B CQI Rate 0 . Calculated as: (sum of TBSs for non-DTX blocks) / (total TTI time for non-DTX blocks) Only blocks sent to this phone are considered in the calculation.. The element gives an estimate of the throughput on the assumption that all blocks were successfully transferred. 100 % Arg 1 . 0 .0: Information Elements and Events IE Name HS-PDSCH Code Usage (Curr) % Range/Unit 0 .. Argument: Channelization code index. Tables 7a–7i. The element reflects the actual physical channel throughput.. See 3GPP 25.. and the CRC indication does not matter. 80000 kbit/s – Calculated as: (sum of TBSs for blocks with CRC OK) / (reporting period) Only blocks sent to this phone are considered in the calculation..214. 78 ...TEMS Investigation 11.. 80000 kbit/s – Calculated as: (Average requested transport block size based on CQI) / (TTI length). and the CRC must be OK. 80000 kbit/s – HS Phy Served Throughput (kbit/s) 0 . 15 * Description Current distribution of channelization code usage on the HSPDSCH. so that values are computed as percentages of the total number of used blocks. This element takes DTX into account.. HS Phy Requested Throughput (kbit/s) HS Phy Scheduled Throughput (kbit/s) 0 .. Requires cell file. 80000 kbit/s Arg 0 .. Channelization codes used on the HS-SCCH. For the decoding to count as a success. 31 – Use of QPSK as modulation method. 1 Decode success rate on the HSSCCH... 100 % 0 .. 8 – Number of channelization codes used on the HS-SCCH. 100 % 0 .. expressed as a percentage of time.Chapter 3... Argument: Carrier index... 0 .... LZT 138 0375 R1A 79 .. Text – List of HS-SCCH channelization codes in text format. Arg 1 is used only for dual carrier sessions. HS QPSK Modulation Rate HS-SCCH Channelisation Code 0 . Name of HSPA serving cell. 511 Text – – c The scrambling code index of the HSPA serving cell.. 1 . HS Serving Cell HS Serving Cell Name 0 . arranged in ascending order. Argument: HARQ process index. Information Elements IE Name HS Phy Served Throughput (kbit/s) Per Process Range/Unit 0 . 8 HS-SCCH Channelisation Codes No Of HS-SCCH Channelisation Codes (Text) HS-SCCH Decode Success Rate 0 . 16 * Description Same as HS Phy Served Throughput (kbit/s) but for each active HARQ process separately. Argument: Channelization code index.... both the first and the second parts must have been completed successfully.. 1 Arg – * Description Indicates whether the session is an HSPA session (as opposed to a WCDMA R99 session).. the argument value does not equate to the corresponding TBS index. accumulated over the current session.... HS Transport Block Count (Accu) HS Transport Block Count (Curr) 0 . 295 Block counts for HSPA transport block sizes currently in use. accumulated over the current session.. 0 ... Argument = “Transport block size index” means that the argument represents the TBS index with this value.. Argument = “Transport block size sequence number” means that 0 represents the first TBS used. 295 Block counts for HSPA transport block sizes currently in use. 65535 1 .... collected over the latest report period. 295 Block counts for HSPA transport block sizes currently in use. 0: No 1: Yes HS Session (Text) “HS Transport Block” IEs: General remark Text – Same as HS Session but in text format. Argument: Transport block size index. 65535 1 .. Argument: Transport block size index. collected over the latest report period. 65535 1 . etc.0: Information Elements and Events IE Name HS Session Range/Unit 0. Argument: Transport block size sequence number. 80 .. 65535 1 . HS Transport Block Count By Index (Curr) 0 .TEMS Investigation 11. Argument: Transport block size sequence number.. 295 Block counts for HSPA transport block sizes currently in use... HS Transport Block Count By Index (Accu) 0 .. 295 – Number of HSPA transport block sizes currently in use. 0 . Average value of serving grant index. These elements pertain to HSUPA (EUL) and are updated primarily when that technology is in use. Block error rate on the E-DCH for first transmission.. This is a measure of serving grant utilization..... 100 % – LZT 138 0375 R1A 81 . HS Transport Block Size By Index 0 ....Chapter 3.. even if only HSDPA is available in the network... 800 – Average value of serving grant (maximum allowed E-DPDCH/ E-DPCCH power ratio). 295 * Description Transport block sizes on the HSDSCH.. 40 – 0 ... Average value of: (transport block size on E-DCH) divided by (maximum transport block size on E-DCH as dictated by current E-TFCI).. 42192 bits 1 .. HS UL Average Serving Grant HS UL Average Serving Grant Index HS UL Average TBS HS UL Average TBS / TBS Max E-TFCI 0 . 100 % – – Average transport block size on E-DCH. Information Elements IE Name HS Transport Block Size Range/Unit 0 . Argument: Transport block size index. uplink activity occurring in the course of running HSDPA may still cause some of the HS UL elements to be populated. 295 Transport block sizes on the HSDSCH.... HS UL BLER 1st 0 .. 42192 bits Arg 1 . 23000 bits 0 . Argument: Transport block size sequence number. HS Transport Block Sizes No Of “HS UL” IEs: General remark 0 . However. 100 % 0 . Argument: E-TFCI. 100 % 0 . 100 % Arg – * Description Residual block error rate on the E-DCH (decoding unsuccessful after maximum number of retransmissions).. 0 . 100 % – – – – – 0 .. 82 . Argument: E-TFCI.TEMS Investigation 11.... 100 % 0 ..... 0 . 127 Current E-TFC usage distribution.0: Information Elements and Events IE Name HS UL BLER Residual Range/Unit 0 .. 100 % 0 ..... 127 E-DPCCH transmit power. 80000 kbit/s –50 ..... HS UL E-TFC Retransmissions (Curr) % HS UL E-TFC Usage (Accu) % HS UL E-TFC Usage (Curr) % 0 . Percentage of TTIs where nothing was sent on the EDPCCH/E-DPDCH... HS UL Buffer Limited Tx Rate HS UL DTX Rate HS UL E-DCH Throughput (kbit/s) HS UL EDPCCH Power HS UL EDPDCH Power HS UL E-TFC Retransmissions (Accu) % 0 . Retransmission rate for each ETFC (Transport Format Combination)... E-DPDCH transmit power.. Percentage of time the transmission on the E-DCH was buffer limited. Argument: E-TFCI. Argument: E-TFCI. 33 dBm –50 . 33 dBm 0 .. averaged over the current session. 100 % 0 . 127 E-TFC usage distribution for the whole of the current session. 127 Current retransmission rate for each E-TFC (Transport Format Combination).. Throughput on the E-DCH.... 100 – 0 . 100 Arg – * Description Number of block errors for the first (second. 3rd. Number of non-serving cells in E-DCH active set. Number of retransmissions on E-DPCCH/E-DPDCH divided by the number of TTIs.... Number of new transmissions on E-DPCCH/E-DPDCH divided by the number of TTIs... 100 % 0 . 4th) HS UL Error Blocks Residual No Of HS UL Happy Rate HS UL HICH ACK Rate HS UL HICH NACK Rate HS UL New Transmission Rate HS UL NonServing Cells No Of HS UL NonServing ERGCH Down No Of HS UL Number Of TTIs HS UL Power Limited Tx Rate HS UL Retransmission Rate Range/Unit 0 ... Number of times a non-serving cell in the E-DCH active set was ordered to lower its transmit power (relative grant = “Down”)... Number of TTIs (transmission time intervals) in log report.321.. See 3GPP 25.. NACK rate on the E-HICH. ACK rate on the E-HICH (HARQ Acknowledgement Indicator Channel).1... 100 % 0 . 4 – – – – – 0 . third. 100 % – – – LZT 138 0375 R1A 83 . Percentage of TTIs where the UE was happy. 0 . fourth) transmission on the E-DCH. Information Elements IE Name HS UL Error Blocks No Of 1st (2nd.. 100 – 0 ... 100 % 0 .. 100 % 0 . 100 0 .. 100 % 0 ..5...8. Percentage of time the transmission was limited by the available Tx power. section 11.Chapter 3.. Number of residual block errors on the E-DCH after maximum number of retransmissions. Each IE value is a percentage of the total number of transmission attempts.. 100 % 1 .TEMS Investigation 11.. Argument: 1: First transmission 2 ..... Percentage of TTIs where the UE received an absolute grant on the E-AGCH. 100 % 0 . fifteenth retransmission 17: Residual 84 . 100 % Arg – * Description Percentage of time the transmission was limited by the current serving grant. fifteenth retransmission 17: Residual – 0 .. Percentage of TTIs where the first transmission was successful....... 100 % – 1 . 17 Same as “HS UL Transmission Distribution (Accu) %” but for the latest reporting period.. Distribution of transmission attempts with respect to the sequence number of the attempt.. The residual case (no success after maximum number of retransmissions) is itself counted as an attempt.... 16: First . 17 HS UL Transmission Distribution (Curr) % 0 . Argument: 1: First transmission 2 . 16: First . 100 % 0 ...0: Information Elements and Events IE Name HS UL Serving Grant Limited Tx Rate HS UL Successful EAGCH Rate (All TTIs) HS UL Successful First Tx Rate HS UL Transmission Distribution (Accu) % Range/Unit 0 . This IE is averaged over the whole of the current session... 10 Inter-freq Event Name Text 1 .. See 3GPP 25.. Event criteria governing when the UE should send interfrequency measurement reports... See 3GPP 23. “e2d”. LZT 138 0375 R1A 85 . There may be multiple criteria for the same event. and “e2f”. Inter-RAT Event Criteria Text 1 .Chapter 3. 5 Event criteria governing when the UE should send inter-RAT measurement reports. 10 Names of events governing sending of inter-frequency measurement reports by the UE. Argument: One argument for each event criterion.309. 31 dB Arg – * Description UE transmission power headroom. IMEI Text – Inter-freq Event Criteria Text 1 . Other inter-frequency events are not extracted. defined as the ratio of the UE maximum transmission power to the current DPCCH transmission power. The events extracted to this element are “e2a”...003. Argument: One argument for each event criterion. Argument: One argument for each event criterion. International Mobile Equipment Identity. the unique equipment identity of the UE..215 and 25.. Information Elements IE Name HS UL UE Transmission Power Headroom Range/Unit 0 . “e1b”. Other intra-frequency events are not extracted. and “e1d”. Event criteria governing when the UE should send intrafrequency measurement reports.. Argument: One argument for each event criterion.TEMS Investigation 11. “e1c”.. 5 * Description Names of events governing sending of inter-RAT measurement reports by the UE. 180 degrees – p 86 ... Other interRAT events are not extracted. Intra-freq Cells Text – Cells on which the UE has been ordered to perform intrafrequency measurements.. 10 Intra-freq Event Name Text 1 . Intra-freq Event Criteria Text 1 .0: Information Elements and Events IE Name Inter-RAT Event Name Range/Unit Text Arg 1 . Argument: One argument for each event criterion. Latitude Latitude (Text) –90 . The only event extracted to this element is “e3a”.. The events extracted to this element are “e1a”... Argument: One argument for each event criterion. Latitude as text. There may be multiple criteria for the same event. Longitude recorded by positioning equipment.. There may be multiple criteria for the same event. 90 degrees Text – – p p Latitude recorded by positioning equipment. For the presentation format. 10 Names of events governing sending of intra-frequency measurement reports by the UE. see TR section 2.. Longitude –180 .4. Requires cell file. For the presentation format... Mon Neigh CPICH Ec/No –34 . 0 dB 1 . Mon Neigh CPICH RSCP –140 .System (Text) Mon Neigh Cell Name Text Text – 1 . Argument: Neighbor identity.. 6 c Same as Mode .System but in text format. Relevant values: 1: No service 2: Idle mode 3: Dedicated (Connected) mode Mode .. LZT 138 0375 R1A 87 . 0 .System 1 .. Information Elements IE Name Longitude (Text) MCC Message Hex Dump Payload Range/Unit Text Arg – * p Description Longitude as text.. Argument: Neighbor identity. 999 Text – – MNC Mode (Num) 0 ...Chapter 3.. –15 dBm 1 . 6 CPICH Ec/No of each monitored neighbor.. Argument: Neighbor identity.4. Also occurs in MIMO variants: Antenna 1. Contains the hexadecimal string of a Layer 3 message or mode report.. 999 1 . Mobile Country Code.. Cell name of each monitored neighbor.. see TR section 2... May consist of two or three digits. 8 – Relevant values: 1: WCDMA 2: GSM Mode . 7 – – Mobile Network Code. Sum.. 6 CPICH received signal code power of each monitored neighbor... Antenna 2. Used for text-format logfile export only. MS Behavior Modified (Text) – Indicates whether the UE behavior has been changed from the default. Mon Neigh UARFCN DL 0 . 6 30 . Calculated as Primary CPICH Tx Power – CPICH RSCP. Argument: Neighbor identity.. 6 Number of monitored neighbors. Mon Neigh SC 0 .. 88 . RAT Control) C: Modification of UE reselection behavior: (information elements Cell Barred Control... Network Search No of UARFCNs 0 .TEMS Investigation 11. or a combination of these letters (or empty string) 1 .... Argument: Neighbor identity....0: Information Elements and Events IE Name Mon Neigh CPICH Tx Power Mon Neigh No Of Members Mon Neigh Pathloss Range/Unit –31 .. 16383 (frequency band dependent) Text: “B”...... 0 . Argument: Neighbor identity.. Pathloss of each monitored neighbor.. 50 dBm Arg 1 .. 6 * Description CPICH transmit power of each monitored neighbor. 6 Downlink UARFCN of each monitored neighbor. 800 – ns Network scanning: The number of UARFCNs scanned. 6 Scrambling code of each monitored neighbor. Empty string: No modification of UE behavior B: Modification of UE behavior in network (information elements BLER Target Control. 511 1 . 165 dB – 1 . Sector Control) Combinations of these letters may appear.. “C”. Argument: Neighbor identity. ..7 for a full description. See UM section 10... Max 1 SC except that the active set is assumed to have at most two possible members. Argument: Position in list of scanned UARFCNs. Information Elements IE Name Network Search SC Range/Unit 0 .7 for a full description. Max 1 SC 0 .. See UM section 10. 10 dB 1 . Argument: Power threshold (in dB) relative to the power of the strongest scrambling code. Applies to the first UMTS frequency scanned (lowest UARFCN). 800 * ns Description Network scanning: Scrambling code detected on each UARFCN scanned... Network Search UARFCN 410 . used to identify possible active set members.Chapter 3.. Applies to the first UMTS frequency scanned.. 10 dB pi Pilot scanning (UM section 10. 511 Arg 1 .. 10 dB 0 .. Argument: Position in list of scanned UARFCNs.2. 10 dB pi As Other/Own.2): Estimated ratio between polluting signal power and desired signal power on a CPICH control channel. 10840 (frequency band dependent) 0 . 800 ns Network scanning: UARFCNs scanned. Other/Own.. based on the assumption that there is only one possible member in the active set. Other/Own..2... Max 2 SCs 0 .. LZT 138 0375 R1A 89 . See UM section 10. Applies to the first UMTS frequency scanned. 11 Text 3 .. 11 1 .. 11 1 .. 10 dB 0 . Max 1 SC except that the active set is assumed to have at most four possible members..)” elements PDP IEs: General remark PDP Access Point Name PDP Address PDP Contexts Active PDP Delay Class PDP LLC SAPI PDP Mean Throughput 0 . Delay class as defined by subscription. Applies to the first UMTS frequency scanned.0: Information Elements and Events IE Name Other/Own... 10 dB pi Same as “Other/Own.7 for a full description.” but for the second (etc... Mean throughput as defined by subscription. User address (IPv4/IPv6). 11 – 1 .7 for a full description. “Other/Own 2nd (etc. Max 3 SCs Range/Unit 0 ...2. LLC Service Access Point Identifier. Number of active PDP contexts. 90 .. 11 Text 1 . The argument..) UMTS frequency scanned.. ..... Max 4 SCs 0 ... refers to a PDP context index.2. See UM section 10... 11 Host name or network address for each active PDP context.TEMS Investigation 11. where present... Other/Own.. 10 dB 0 . 10 dB pi As Other/Own.. Max 1 SC except that the active set is assumed to have at most three possible members.. 10 dB Arg 0 .. 10 dB * pi Description As Other/Own.. 11 1 . Text Text 0 . 11 1 .)” elements 0 . Reliability class as defined by subscription... Precedence class as defined by subscription.7 for a full description. page 39.) UMTS frequency scanned. 11 1 . Peak throughput as defined by subscription. Argument: Power threshold (in dB) relative to the power of the strongest scrambling code.. 10 0 ... 11 See the description (cellular technology independent) under GSM. Radio priority level as defined by subscription... 10 dB pi Same as Poss No of AS Members but for the second (etc... Text Text 1 .... 11 * Description Network SAPI (Service Access Point Identifier)... Applies to the first UMTS frequency scanned (lowest UARFCN).. 10 0 . “Poss No of AS Members 2nd (etc. 15 Text Text Arg 1 .Chapter 3. Information Elements IE Name PDP NSAPI PDP Peak Throughput PDP Precedence Class PDP Radio Priority PDP Reliability Class PESQ elements Poss No of AS Members Range/Unit 5 . See UM section 10. LZT 138 0375 R1A 91 .. 0 .... 11 1 ..2. 10 dB pi Pilot scanning: The estimated number of possible members in the active set. 34 dBm 0 . • • Power Control Indication UL –1. 16.5.3.. Maximum number of preambles in one preamble ramping cycle.2.1. Number of preambles used in this preamble ramping cycle. and 16. 1 Arg – * Description Inner loop power control indication pertaining to the downlink. Transmit power of first RACH preamble in dBm... 64 –50 . 0. The value 0 means that the upward and downward power adjustments have canceled out exactly. 1 – Inner loop power control indication on uplink. The value +1 means that the power has been adjusted predominantly upward.1. 34 dBm 0 . Use of Lock to RAT function in UE. Based on the recent history of power control decisions: • The value –1 means that the power has been adjusted predominantly downward. 0... 0: Lock to RAT disabled 1: Locked to GSM 900/1800 2: Locked to GSM 850/1900 3: Locked to WCDMA RACH Initial TX RACH Max Preambles RACH Message TX RACH Transmitted Preambles RAT Control –50 .4. which see.. Works the same way as Power Control Indication DL.. 16..2.0: Information Elements and Events IE Name Power Control Indication DL Range/Unit –1.4. See UM sections 16.. 3 – 92 .3. Transmit power of last RACH preamble in dBm..TEMS Investigation 11.2. 64 – – – – 0 . . Since the PDU throughput includes RLC headers. Radio Link Control (Acknowledged Mode): Type of downlink logical channel. 80000 kbit/s 1 . “DCCH”. e. of PDUs Argument: Logical channel index.. of NACKed PDUs ⋅ 100 -------------------------------------------------------------------------total no... downlink). RB Setup UL DPCH SC RLC AM DL Log Ch Type 0 . Argument: Logical channel index. Information Elements IE Name RAT Control (Text) Range/Unit Text Arg – * Description Use of Lock to RAT function in UE. it will be slightly higher than the SDU throughput where such headers are absent. Argument: Logical channel index... RLC AM DL PDU Thr 0 ... 80000 kbit/s 1 . Argument: Logical channel index.. 4 RLC AM DL PDU Retran (%) 0 . LZT 138 0375 R1A 93 . The scrambling code of the uplink Dedicated Physical Channel..Chapter 3.. 108 – Text 1 . downlink): PDU retransmission percentage. “Active” when lock to RAT has been activated. counting both control PDUs and AM PDUs. 4 Radio Link Control SDU throughput (Acknowledged Mode... Blank when no lock is engaged. downlink). 100 % 1 . 4 Radio Link Control PDU throughput (Acknowledged Mode... 4 Radio Link Control (Acknowledged Mode. Calculated as: no. RLC AM DL SDU Thr 0 .g.. . uplink). Argument: RLC entity. 80000 kbit/s 1 . of PDUs Argument: Logical channel index.... it will be slightly higher than the SDU throughput where such headers are absent.. 32 Downlink RLC entity data mode: Transparent Mode. Calculated as: no. RLC DL Entity Data Mode Text: “TM”. RLC AM UL PDU Retran (%) 0 . Argument: Logical channel index. Unacknowledged Mode. or Acknowledged Mode.. 80000 kbit/s 1 . Argument: Logical channel index. Argument: Logical channel index..0: Information Elements and Events IE Name RLC AM UL Log Ch Type Range/Unit Text Arg 1 .TEMS Investigation 11. counting both control PDUs and AM PDUs. 4 Radio Link Control PDU throughput (Acknowledged Mode. Since the PDU throughput includes RLC headers..... RLC AM UL PDU Thr 0 . 4 * Description Radio Link Control (Acknowledged Mode): Type of uplink logical channel.g. 4 Radio Link Control SDU throughput (Acknowledged Mode.. of NACKed PDUs ⋅ 100 -------------------------------------------------------------------------total no. uplink). uplink): PDU retransmission percentage.. “DCCH”. 4 Radio Link Control (Acknowledged Mode.. 94 ... 100 % 1 . RLC AM UL SDU Thr 0 . or “AM” 1 . e. “UM”. Highest uplink throughput for all RLC entities/transport channels. Information Elements IE Name RLC DL Throughput RLC No Of Entities RLC UL Entity Data Mode Range/Unit 0 . 32 * Description Total RLC downlink throughput. 80000 kbit/s 0. 32 Total RLC uplink throughput. 80000 kbit/s 0 . – Highest downlink throughput for all RLC entities/transport channels....331. LZT 138 0375 R1A 95 . or Acknowledged Mode.31.. RLC UL Throughput RLC/Trsp DL Throughput (Best) RLC/Trsp UL Throughput (Best) RRC Connection Reject Cause 0 . 0: Congestion 1: Unspecified See 3GPP 25. Argument: RLC entity... Argument: RLC entity. 32 Total number of RLC entities on uplink and downlink.. or “AM” Arg 1 . – – RRC Connection Reject Wait Time 0 .3.3. Argument: RLC entity... See 3GPP 25... 32 Text: “TM”..3.. 1 1 .331. section 10... Uplink RLC entity data mode: Transparent Mode. section 10..Chapter 3. 16 s – The time the UE has to wait before repeating the rejected RRC procedure.. – 1 .50. Unacknowledged Mode. 80000 kbit/s 0 ..3. “UM”. Cause for rejection of RRC connection establishment request. 80000 kbit/s 0 . SAN Cell Id (CI Part Hex) Text: “0000” . 38 Cell Identity part of SAN Cell Id: bits 12 through 27 (in decimal).. RRC State (Text) SAN Cell Id Text 0 . See 3GPP 25..331. 216 – 1 1 . 228 – 1 – 1 . Serving/Active Set + Neighbors window: Cell identity of each cell listed.. 212 – 1 1 .. Argument: See SAN Cell Id. whereas in other modes the serving cell is found on row 1....TEMS Investigation 11. SAN Cell Id (CI Part) 0 ... 38 Cell Identity part of SAN Cell Id: bits 12 through 27 in hexadecimal. the active set is on top (max 4 rows)... “FFFF” 1 . 5 Arg – * Description State of RRC protocol: 0: No service 1: Idle mode 2: Connected_Cell_FACH 3: Connected_Cell_DCH 4: Connected_Cell_PCH 5: Connected_URA_PCH The state is set to idle when the UE registers. and the information element is then updated each time the state changes... 96 . 38 RNC part of SAN Cell Id: bits 0 through 11 (in decimal). Argument: See SAN Cell Id. Argument: Indicates the row in the window.0: Information Elements and Events IE Name RRC State Range/Unit 0 .. 38 Same as RRC State but in text format.... In Cell_DCH mode. In either case the neighbors follow directly beneath.. SAN Cell Id (RNC Part) 0 . chapter 7. Argument: See SAN Cell Id. . 4 1 . 38 c Same as SAN Cell Type but with text strings indicating the type of cell: SC: Serving cell AS: Active set member MN: Monitored neighbor DN: Detected neighbor Argument: Window row. Argument: See SAN Cell Id. 38 c Serving/Active Set + Neighbors window: Type of cell for each cell listed.. Antenna 2.. SAN CPICH RSCP –140 .. 38 * Description RNC part of SAN Cell Id: bits 0 through 11 in hexadecimal. Argument: Window row....... Sum. 38 Serving/Active Set + Neighbors window: CPICH RSCP for each cell listed. SAN Cell Type Abbr Str Text 1 . Requires cell file. 38 Serving/Active Set + Neighbors window: CPICH Ec/No for each cell listed. Also occurs in MIMO variants: Antenna 1. Argument: Window row. “FFF” Text Arg 1 . Argument: Window row.. Argument: Window row. 38 c Serving/Active Set + Neighbors window: Name of each cell listed.Chapter 3. 1 . –15 dBm 1 . 1: Serving cell 2: Active set member 3: Monitored neighbor 4: Detected neighbor Requires cell file. SAN Cell Type 1 ..... Information Elements IE Name SAN Cell Id (RNC Part Hex) SAN Cell Name Range/Unit Text: “000” ... LZT 138 0375 R1A 97 .. SAN CPICH Ec/No –34 ... 0 dB 1 . 0: Information Elements and Events IE Name SAN CPICH Tx Power Range/Unit –31 . 16383 (frequency band dependent) 0 . SAN HS Cell Type 1. SAN UARFCN DL 0 . 38 Serving/Active Set + Neighbors window: Downlink UARFCN for each cell listed... 1: Serving cell 2: Non-serving cell SAN HS Cell Type Abbr Str SAN No of Members SAN Pathloss Text 0 ...... Argument: Window row... 38 Serving/Active Set + Neighbors window: Cell type for each cell in HSPA active set.. Serving/Active Set + Neighbors window: Pathloss for each cell listed. 38 Serving/Active Set + Neighbors window: URA identity of each cell listed. 38 Serving/Active Set + Neighbors window: Scrambling code for each cell listed. 38 – Same as SAN HS Cell Type but in text format: “SC” or “N-SC”. 38 1 . 38 * Description Serving/Active Set + Neighbors window: Primary CPICH transmit power for each cell listed. SAN URA Id 1 . Argument: Window row. Serving/Active Set + Neighbors window: Total number of cells listed..... 30 . 511 1 .. 228 – 1 1 . Argument: Window row. 98 .... Calculated as Primary CPICH Tx Power – CPICH RSCP. 50 dBm Arg 1 ... Argument: Window row.... 165 dB 1 . 2 1 ... Argument: Window row.TEMS Investigation 11.. 38 SAN SC 0 . .. 512 pi Pilot scanning: The aggregate code power of the scrambling code (Eb.. 512 pi Sc Best AggrPeak Ec (dB) 0 . Sc Best Aggr Ec (dBm) –130 ..2.. Information Elements IE Name “Sc Best” IEs: General remark Range/Unit Arg * Description These elements combine scrambling codes from all scanned UMTS frequencies. Pilot scanning: The aggregate code power (energy per chip) of each scanned scrambling code..... Argument (where present): 1 is the scrambling code with the highest Aggr Ec/Io. 0 dB 1 .. energy per bit) relative to the total signal power in the channel (Io).. The aggregate code power is a measure of the total signal power (distributed around the main peak due to multipath propagation) that is above the PN threshold (see UM section 10. etc. –25 dBm 1 . sorted by descending Aggr Ec/Io. 90 dB 1 .2. Pilot scanning: The aggregate code power of the scrambling code (Ec.Chapter 3.11. Pilot scanning: The difference between the aggregate code power and peak code power.. energy per chip) relative to the total signal power in the channel (Io).2).. see UM section 10.1). Sc Best Aggr Eb/Io (dB) –10 . 512 pi LZT 138 0375 R1A 99 . 21 dB 1 . 512 pi Sc Best Aggr Ec/Io (dB) –30 .2.. The sorting order within the “Best” elements is not affected by the settings in the General window (see UM section 10. Regarding pilot scanning in general... 0: Information Elements and Events IE Name Sc Best Cell Name Range/Unit Text Arg 1 .. 512 * pi c p Description Pilot scanning: Deduced name of the cell that uses each scanned scrambling code. and the position reported.TEMS Investigation 11. so there will be one “1” with associated “2”s for each frequency. 100 . Requires cell file.. Sc Best Cell Type 1 . this categorization is applied for each UMTS frequency.. 1: The cell with the strongest Aggr Ec. 3 1 . In the “Sc Best” element. If multiple matches are found.. The algorithm in this case simply picks the first cell in the cell file with matching SC number and UARFCN... It searches the cell file for cells with matching SC number and UARFCN within a 50 km radius. as indicated by the cell file. The algorithm determining the cell name takes as input the SC number. 2: All neighbors of the “1” cell. the cell closest to the position is selected. If no positioning data is available. 3: All other cells. 512 pi c p Pilot scanning: Categorization of the cells that use the scanned scrambling codes. Requires cell file. the UARFCN. but the cell names may then of course be wrong. the information element will still be presented. 255 chips Arg 1 .Chapter 3. 21 dB – – 1 . Sc Best Io Sc Best No of SCs Sc Best Peak Eb/Io (dB) –115 .... –25 dBm 1 .. the difference between them in dB. Pilot scanning: The peak code power of each scanned scrambling code (Ec. energy per chip) relative to the total signal power in the channel (Io). 512 pi Sc Best P-SCH Ec (dBm) –130 . –25 dBm 1 . The peak code power of each scanned scrambling code on the primary synchronization channel (P-SCH)... This is a measure of the signal spreading due to multipath propagation.. 512 * pi Description Pilot scanning: Time in chips between the first and last Ec/Io peak that is above the PN threshold (see UM section 10.e. Information Elements IE Name Sc Best Delay Spread Range/Unit 0 .... energy per bit) relative to the total signal power in the channel (Io). energy per chip) in dBm.. Pilot scanning: The peak code power of each scanned scrambling code (Ec. 0 dB 1 ...e. i.2). the difference between them in dB.... 512 –10 . 512 pi pi pi Sc Best Peak Ec (dBm) –130 .... Pilot scanning: The number of scrambling codes scanned.. 512 pi Sc Best Peak Ec/Io (dB) –30 . 512 pi LZT 138 0375 R1A 101 .. Pilot scanning: The peak code power of each scanned scrambling code (Eb.2. i... –25 dBm 0 .. Pilot scanning: The total signal power in the channel. 512 * pi Description The peak code power (Ec) of each scanned scrambling code on the primary synchronization channel (P-SCH)..... 511 0 . The peak code power of each scanned scrambling code on the secondary synchronization channel (S-SCH).... 7 1 ... –25 dBm 1 . Pilot scanning: Equal to (Sc Best Time Offset mod 2560) + 1. 51 1 . 0 dB 1 . 512 pi Sc Best SC Sc Best SC Group 0 ........400 chips) for each scanned scrambling code... relative to the total signal power in the channel (Io).. 512 pi –30 .. relative to the total signal power in the channel (Io). 512 pi 102 . Pilot scanning: The time offset of the radio frame (10 ms = 38. 38399 chips 1 ... Pilot scanning: The number of the group to which each scanned scrambling code belongs...0: Information Elements and Events IE Name Sc Best P-SCH Ec/Io (dB) Range/Unit –30 .... 512 pi pi Sc Best SIR (dB) Sc Best S-SCH Ec (dBm) Sc Best S-SCH Ec/Io (dB) –25 . 512 pi Sc Best Time Offset Slot Pos 1 .. 512 pi Sc Best Time Offset 0 . Pilot scanning: The number of Ec/Io peaks (multipath components) that are above the PN threshold. Pilot scanning: The number of each scanned scrambling code. The peak code power (Ec) of each scanned scrambling code on the secondary synchronization channel (S-SCH).. 2560 1 . Pilot scanning: Received SIR (in dB) for scanned scrambling codes. 512 pi 1 ... Sc Best Rake Finger Count 0 .. 0 dB Arg 1 .. 512 1 ..TEMS Investigation 11.. 30 dB –130 .. etc. What scrambling code is the first depends on the sorting order set in the General window: see UM section 10. Sc Best UL Interference Sc 1st (etc.Chapter 3. – pi “Sc 1st (etc. Argument: The sorting order within each element depends on the General window setting: see UM section 10.2. extracted from SIB type 7. 5”.) scanned UMTS frequency is considered.) scanned UMTS frequency.11. third. Information Elements IE Name Sc Best UARFCN Range/Unit 410 . Obtained from SIB.. 10840 (frequency band dependent) Arg – * pi Description Pilot scanning: The UARFCN of the CPICH currently scanned.2. since that would be pointless. etc. LZT 138 0375 R1A 103 . 3. third.11.. “1..1. e. Pilot scanning: Neighbor list for the first scrambling code on the first (second.1. Given as a comma-separated string of scrambling codes. –70 dBm Text – pi Pilot scanning: Interference on uplink.)” elements (except Intrafreq Cells) Same as “Sc Best” elements except that only the first (second.) Intra-freq Cells –110 . Note: More IEs are provided for frequencies 1–4 than for frequencies 5–12. No “Sc Best” version is provided for these elements.g.. for “Every 4”. 4. 2560/2... SCH TS Sc No Of Segm 0 .e.2560 (max.. SCH timeslot scanning: Position of each timeslot segment scanned.. 2560 chips – ts SCH timeslot scanning: The time separation in chips between the strongest peak and the second strongest. the argument range is 1 . the range is 1 . 640. 4. for “Every 8”. 2.. 1280. expressed as a chip index.. 640... see Descr. 2. for “Every 8”.) * ts Description SCH timeslot scanning (UM section 10... 320.3): Power in each segment (1. SCH timeslot scanning: The time separation in chips between the second strongest peak and the third strongest. If “Every 2” has been chosen. 2560/2.. 0 dB Arg 1. 320...TEMS Investigation 11. 2560 chips – ts 104 . Argument: Index of timeslot segment (not chip index).. the range is 1 .... the argument range is 1 . the range is 1 . 1 . or 8 chips depending on setup).0: Information Elements and Events IE Name SCH TS Sc Es/Io (dB) Range/Unit –24 . 2560 1.. 2560 – ts SCH timeslot scanning: Number of scanned timeslot segments (each with length 1. SCH TS Sc Segm 1 . for “Every 4”. 1 .. 1280.. Argument: Index of timeslot segment (not chip index). the range is 1 . SCH TS Sc Time Diff 2-3 1 . i.) ts SCH TS Sc Time Diff 1-2 1 .. or 8 chips depending on setup) of the scanned timeslot...e..2560 (max... see Descr. The first chip has number 1... If “Every 2” has been chosen. i... RNC part of Serving Cell Id: bits 0 through 11 (in decimal). Information Elements IE Name SCH TS Sc UARFCN Range/Unit 410 .. “FFFF” 0 .4. 1 – Use of Lock to Sector/Cell Selection function in UE in idle mode: 0: Lock to Sector disabled 1: Lock to Sector enabled See UM sections 16...1. Sector Control 0.Chapter 3.. “FFFF” – – – – – LZT 138 0375 R1A 105 ..3.2..4. 10840 (frequency band dependent) Arg – * ts Description SCH timeslot scanning: UARFCN scanned. 228 – 1 0 . RNC part of Serving Cell Id: bits 0 through 11 in hexadecimal. 16. Cell Identity part of Serving Cell Id: bits 12 through 27 in hexadecimal. 16...2... 65535 Text: “0000” ... 16.3.2. Text: “0000” . 212 – 1 Text: “000” . These elements are not valid in Cell_DCH mode.4..1. “FFF” 0 . LAC of serving cell. Sector Control (Text) “Serving” IEs: General remark Serving Cell Id Serving Cell Id (CI Part) Serving Cell Id (CI Part Hex) Serving Cell Id (RNC Part) Serving Cell Id (RNC Part Hex) Serving Cell LAC Serving Cell LAC (Hex) Text – Same as Sector Control but in text format. LAC of serving cell in hexadecimal format.4. 216 – 1 – – Cell identity of the serving cell..13. Cell Identity part of Serving Cell Id: bits 12 through 27 (in decimal).. 0 .. Also occurs in MIMO variants: Per Antenna. 255 Text: “00” . and URA_PCH mode... Spreading factor on downlink. 16383 (frequency band dependent) 0 . 0 ..... 0 dB –140 . Pathloss of the serving cell. – – Serving UARFCN DL 0 . RAC of serving cell in hexadecimal format.. Cell_FACH.. Cell_PCH.. Requires cell file... Cell_PCH. Spreading factor on uplink... CPICH received signal code power of the serving cell.. 512 – Serving URA Id SF DL SF UL – – – 106 .0: Information Elements and Events IE Name Serving Cell Name Serving Cell RAC Serving Cell RAC (Hex) Serving CPICH Ec/No Serving CPICH RSCP Range/Unit Text Arg – * c Description Name of the serving cell. Scrambling code of the serving cell in idle. Sum. Serving CPICH Tx Power Serving Pathloss Serving SC –31 . Calculated as Primary CPICH Tx Power – CPICH RSCP.. 228 – 1 1 . 50 dBm 30 . 512 1 . 165 dB 0 .. 511 – CPICH transmit power of the serving cell.. Cell_FACH. Downlink UARFCN of the serving cell in idle.. URA identity of the serving cell. –15 dBm – – – – RAC of serving cell. and URA_PCH mode. “FF” –34 ... CPICH Ec/No of the serving cell..TEMS Investigation 11.. SHO Event Success Rate 0 .. 100 % – Soft handover success rate. Information Elements IE Name SHO Event Rate Range/Unit 0 ... Regarding the events.2. Calculated as: (# add + # rem + # repl) / # all where add = Radio Link Addition events rem = Radio Link Removal events repl = Radio Link Replacement events all = All radio link events... 50 Arg 0 .Chapter 3.. including failures Regarding the events. 3600 * Description Number of radio link events (both failures and successes) over the last arg seconds. see section 6. see section 6. LZT 138 0375 R1A 107 . Argument: See above.2. where arg is the value of the argument. Argument = 0 means that the events are counted from the beginning of the logfile. . About the events. 0: Unknown (no cell data loaded) 1: Soft handover 2: Softer handover Requires that a cell file with Node B information has been loaded. 2 – c Soft handover state. SHO State 0 . Invalid when AS No Of Members < 2.TEMS Investigation 11. and Radio Link Replacement.0: Information Elements and Events IE Name SHO Percent Softer Range/Unit 0 . otherwise the element is invalid.. 108 .2. 100 % Arg – * c Description A measure of the amount of softer handover. Calculated as: # softer / (# softer + # soft) where softer = Radio link event indicating success occurs while in softer handover (and with more than one member in active set) soft = Radio link event indicating success occurs while in soft handover (and with more than one member in active set) A radio link event is one of Radio Link Addition.. otherwise the value will always be = 0. Requires that a cell file with Node B information has been loaded.. Radio Link Removal. see section 6. Spectrum analysis: The number of downlink frequencies swept by the scan. 2560 1 . measured on DPCCH. or “Unknown”...2. 2560 ss Spectrum analysis: Scanned frequencies on downlink in ascending order. 2170 MHz 1 . 2170 MHz Spectr Ana Sc DL Freq 1 . The argument.. “Softer”. Invalid when AS No Of Members < 2.. 30 dB –20 ..Chapter 3. Information Elements IE Name SHO State (Text) Range/Unit Text Arg – * c Description Soft handover state as plain text: “Soft”. Requires that a cell file has been loaded (otherwise the value will always be “Unknown”). SIR –20 . SIR target governing SIR.. SIR Target Spectr Ana IEs: General remark – These elements are obtained from spectrum analysis. is simply a sequence number pointing to scanned frequencies as indicated by the “Spectr Ana Sc DL Freq” or “Spectr Ana Sc UL Freq” element. section 5. See 3GPP 25.. where present... 30 dB – Signal-to-interference ratio.215..2..... Spectrum analysis: RSSI of downlink frequencies scanned..... Spectrum analysis: Scanned frequencies on uplink in ascending order. Spectr Ana Sc DL No of Freq Spectr Ana Sc DL RSSI (dBm) Spectr Ana Sc UL Freq 0 ..... Spectrum analysis: The number of uplink frequencies swept by the scan. 2560 – ss –130 . 2560 – ss LZT 138 0375 R1A 109 . 1990 or 2110 . 1990 or 2110 .. 1930 . See SHO State. –20 dBm 1930 .. 2560 ss ss Spectr Ana Sc UL No of Freq 0 . . AQM: The length of time it takes for the speech to travel from the Call Generator to the MTU and back to the Call Generator again. –20 dBm 0 . See UM chapter 29.. Speed (km/h) Speed (mph) SQI 0 .. 155 mph –20 . 5 MOS – SQI expressed on the MOS scale.95 kbit/s: 28 dBQ 7. Speed in mph.TEMS Investigation 11. 250 km/h 0 .0: Information Elements and Events IE Name Spectr Ana Sc UL RSSI (dBm) Speech Path Delay Range/Unit –130 . The maximum SQI values are as follows: 12....2).2 kbit/s: 28 dBQ 7. 800 ms Arg 1 .70 kbit/s: 27 dBQ 5. Speech Quality Index for WCDMA... 30 dBQ – – – p p Speed in km/h.90 kbit/s: 24 dBQ 5.. 2560 – * ss Description Spectrum analysis: RSSI of uplink frequencies scanned....2 kbit/s: 30 dBQ 10.75 kbit/s: 19 dBQ SQI MOS 1 . This element only appears in merged logfiles (see UM section 36.40 kbit/s: 27 dBQ 6.. 110 .15 kbit/s: 21 dBQ 4. The range is different depending on the AMR speech codec mode.. Str Neigh Type 3. Argument: 1 is the strongest neighbor. The types are: 3: Monitored neighbor 4: Detected neighbor Argument: 1 is the strongest neighbor. etc.. 511 1 ... Argument: 1 is the strongest neighbor. Str Neigh CPICH RSCP –140 ..Chapter 3. 6 Scrambling codes of neighbors (monitored as well as detected) sorted by signal strength in descending order. Requires cell file.. Argument: 1 is the strongest neighbor. etc... Str Neigh CPICH Ec/No –34 . Str Neigh SC 0 . LZT 138 0375 R1A 111 . 6 CPICH RSCP of neighbors (monitored as well as detected) sorted by signal strength in descending order.. Information Elements IE Name Str Neigh Cell Name Range/Unit Text Arg 1 .. 6 * c Description Cell names of neighbors (monitored as well as detected) sorted by signal strength in descending order. 0 dB 1 . 6 CPICH Ec/No of neighbors (monitored as well as detected) sorted by signal strength in descending order..... Sum. etc. 6 Types of neighbors (monitored as well as detected) sorted by signal strength in descending order. etc. Antenna 2. Also occurs in MIMO variants: Antenna 1. –15 dBm 1 . Argument: 1 is the strongest neighbor. etc. 4 1 .... but only an average over all of them (arg = 1).10.331.. 63 See Description – Block error rate on the worst downlink transport channel (DCH only) in percent. converted to logarithmic value... etc. 1 . 6 * Description CPICH UARFCNs of neighbors (monitored as well as detected) sorted by signal strength in descending order. Identifier of tone event in TEMS Automatic configuration database (table tToneTemplate). see 3GPP 25. Block error rate on each downlink transport channel (DCH only). section 10... DL (Log) 0 .. Regarding the conversion. Tone Event 0 . 100 % 0 . Time (Text) Text – Current time in text format: HH:MM:SS. 60000 – Trsp Ch BLER (%. Worst) Trsp Ch BLER. This element occurs only in logfiles from TEMS Automatic.5.. Argument: Transport channel index. where mm = decimal seconds..TEMS Investigation 11. 16383 (frequency band dependent) Arg 1 ..mm...3. Note: Nokia UEs do not deliver separate values for each transport channel..0: Information Elements and Events IE Name Str Neigh UARFCN DL Range/Unit 0 . 32 112 . Argument: 1 is the strongest neighbor. 4095 – – 1 . DL (Log)”. Argument: Transport channel index. Argument: Transport channel index. Information Elements IE Name Trsp Ch BLER......) Compare “Trsp Ch BLER.Chapter 3. Trsp Ch BLER Target (%) 0 . The channel type is indicated by the element Trsp Ch Type DL. Number of uplink transport channels. LZT 138 0375 R1A 113 . DL (%) Range/Unit 0 . 32 0 . Trsp Ch No Of DL Trsp Ch No Of UL Trsp Ch No Of Error Blocks 0 . 32 * Description Block error rate on each downlink transport channel (DCH only) in percent...1.. See 3GPP 25. Argument: Transport channel index.. Argument: Transport channel index. 32 0 . Trsp Ch Id DL 1 . 32 Number of downlink transport channels.. section 5. 32 Identity of each downlink transport channel. 32 Block error rate target for each downlink transport channel (DCH only) in percent... 100 % 1 ..215.. Number of erroneous blocks on each transport channel.. Compare “Trsp Ch BLER. 32 1 . (The number of reports over which this is summed varies between phones. DL (Log)”.6..... 100 % Arg 1 .. Argument: Transport channel index.... Trsp Ch Type UL Text 1 . 4095 Arg 1 . Argument: Transport channel index. 32 Downlink transport channel type: DCH or FACH.... Trsp Ch Throughput UL (kbit/s) 0 .TEMS Investigation 11.) Argument: Transport channel index. 80000 kbit/s 1 . Argument: Transport channel index. 114 .0: Information Elements and Events IE Name Trsp Ch Rec Blocks Range/Unit 0 .. 44 dBm – UE initial transmit power in dBm. Trsp Ch Throughput DL (kbit/s) 0 ... 32 Uplink transport channel type: DCH or RACH... UE Initial Transmit Power –60 . 80000 kbit/s – Total uplink throughput on all transport channels. 80000 kbit/s 1 . 32 Uplink throughput on each transport channel. Argument: Transport channel index.... 32 Downlink throughput on each transport channel.... Trsp Ch Type DL Text 1 ... Argument: Transport channel index. Trsp Ch Throughput UL Total (kbit/s) 0 ... (The number of reports over which this is summed varies between phones. Argument: Transport channel index.. 80000 kbit/s – Total downlink throughput on all transport channels. Trsp Ch Throughput DL Total (kbit/s) 0 . 32 * Description Number of blocks received on each transport channel. .. Information Elements IE Name UE Tx Power UL Interference Serving UTRA Carrier RSSI Range/Unit –60 . 44 dBm –110 .. Also occurs in MIMO variants: Per Antenna.. – VTQI 1 . Total energy measured by the UE within the downlink bandwidth. extracted from SIB type 7.Chapter 3. Interference on uplink.. –70 dBm –130 .. see UM chapter 31. 5 MOS – Video Telephony Quality Index.. Sum. LZT 138 0375 R1A 115 .. Valid only in connected mode. –20 dBm Arg – – * Description UE transmit power in dBm. Identity number of each EPS bearer. always points to an LTE cell unless otherwise stated. 11 5 ..4. Information Element Table IE Name Altitude (ft) Range/Unit –1312 . Guaranteed uplink bit rate for each EPS bearer. 256000 kbit/s 1 . 11 116 . The party that initiated each EPS bearer: UE or network. 11 1 .. see 3GPP 24. 11 The default EPS bearer that each dedicated EPS bearer is associated with.... LTE Information Elements Elements in this category are supported by both DRT and PCTel scanners unless otherwise noted in section 4. Altitude (m) Bearer elements: General remark Bearer Default EPS Bearer ID The argument points to an EPS bearer. Guaranteed downlink bit rate for each EPS bearer. – Height above sea level in meters.3.007.9. Reported by positioning equipment.3.0: Information Elements and Events 3. 15 Text 1 .301. 29028 ft –400 . Invalid if the bearer is itself a default bearer. 11 1 .... Regarding the EPS bearer identity..4..TEMS Investigation 11.301. See 3GPP 24. 5 ..9.... where present..4. 256000 kbit/s 1 .. See 3GPP 24. i. only valid for dedicated bearers. section 9. 15 1 .3. section 9..e. Bearer Guaranteed Bitrate DL (kbit/s) Bearer Guaranteed Bitrate UL (kbit/s) Bearer ID Bearer Initiator 1 . The argument. Reported by positioning equipment.. 8848 m Arg – Description Height above sea level in feet..... ... 256000 kbit/s 1 .. 11 1 . 11 – – – These elements originate from enhanced power scanning. Dedicated. See 3GPP 24. See 3GPP 24. 15 Text 1 . 11 0 . Argument: Points to a frequency as specified by the EPower Ana Sc DL Freq (kHz) element...213. section 7. Number of frequencies scanned.3.... Information Elements IE Name Bearer Maximum Bitrate DL (kbit/s) Bearer Maximum Bitrate UL (kbit/s) Bearer Number Of Bearer PDN Connection Index Bearer QCI Bearer Status Bearer Type CQI Antenna 1 CQI Antenna 2 EMM State EPower IEs: General remark EPower Ana Sc DL Freq (kHz) EPower Ana Sc DL No Of Freq Range/Unit 1 .. 11 0 .4... 15 0 . Status of each EPS bearer. Type of each EPS bearer. section 9. 11 Description Maximum downlink bit rate for each EPS bearer. section 7.301..4.. Used. 11 1 . See 3GPP 24.9... 2559 – List of frequencies scanned. The PDN connection that each EPS bearer is associated with.3. EPS Mobility Management state.. See 3GPP 36. Channel Quality Indicator for antenna Rx1. 256000 kbit/s Arg 1 . 6 · 106 kHz 0 .. Channel Quality Indicator for antenna Rx2. 11 1 ..9. See 3GPP 36. One of: Undefined.2. Not found. 8 – 1 .. section 9. One of: Free.. 0 .301.9.Chapter 3...3.. QoS Class Indicator. LZT 138 0375 R1A 117 . 2560 1 .213..4... Maximum uplink bit rate for each EPS bearer.2. Number of EPS bearers for the UE..3. Default.301.. 9 Text Text 0 . 1 . section 9...3.. 180 degrees Text Text – – – Text Text 1 .4. Longitude in decimal degrees. 8 – – – – 118 . Not used. Hardware identification string.4.. see TR section 2.. 7 1 . Version number of device firmware. “2TX SFBC”. 90 degrees Text Text Arg 1 . Not used. Reported by positioning equipment.. see TR section 2. Not used.. For the presentation format.0: Information Elements and Events IE Name EPower Ana Sc DL RSSI (dBm) ESM State Firmware Version Hardware Hardware ID Heading (deg) Range/Unit –140 .. Scanner model. For the presentation format. Latitude in decimal degrees..TEMS Investigation 11.. Longitude recorded by positioning equipment.. Latitude as text.. EPS Session Management state. presented as text. “SIMO”.System – – – –180 .. MIMO mode. 360 degrees –90 . Direction of travel measured in degrees clockwise from north.. presented as text.. Longitude as text. for example “SISO”.. 2559 – – – – – Description RSSI for each frequency scanned. 25 dBm Text Text Text Text 0 . Latitude Latitude (Text) Latitude Decimal Degrees (Text) Longitude Longitude (Text) Longitude Decimal Degrees (Text) MIMO Mode Mode Mode (Num) Mode .. Latitude recorded by positioning equipment. 1.. –140 .. see 3GPP 36.. Regarding EARFCN numbering. Equivalent to scanned RSRP Tx2.. 8 – 1 ....101.. 8 Received signal strength on the EARFCN each neighbor is using.. 8 1 . Number of neighbors in the neighbor list of the current serving cell.... RSRP contribution from antenna Tx1 as received on antenna Rx1. 8 1 .. 8 –140 .. Distance to each neighbor cell. 25 dBm –140 . Description The argument points to an LTE cell.. since the scanner has only one antenna [Rx1].... Reference Signal Received Power of each neighbor (sum of contributions from antennas Rx1 and Rx2)..System (Text) Neighbor IEs: General remark Neighbor Cell Channel RSSI (dBm) Neighbor Cell Distance (m) Range/Unit Text Arg – Not used. Requires cell file and UE positioning data.. see 3GPP 36. 8 Downlink EARFCN of each neighbor. (No equivalent scanner IE.Chapter 3. 29649 0 .. 0 . 25 dBm 1 .... The sorting order depends on the setting in the General window: see UM section 11.5. 8 LZT 138 0375 R1A 119 . 8 –140 .. 100000 m 1 .. Cell Identity (equal to 3 × PCIG + PCI) of each neighbor. 1 . 503 1 ... 25 dBm 1 .. 25 dBm 1 .) RSRP contribution from antenna Tx2 as received on antenna Rx1. Regarding EARFCN numbering.. RSRP contribution from antenna Tx1 as received on antenna Rx2...2. Equivalent to scanned RSRP Tx1.. Information Elements IE Name Mode ..101. 25 dBm –140 . 8 Neighbor Cell DL EARFCN Neighbor Cell Identity Neighbor Cell Number Of Neighbor Cell RSRP (dBm) Neighbor Cell RSRP Tx1 Rx1 (dBm) Neighbor Cell RSRP Tx1 Rx2 (dBm) Neighbor Cell RSRP Tx2 Rx1 (dBm) 0 . 8 These IEs relate to packet data network (PDN) connections.301..... (No equivalent scanner IE...2. 9 Aggregate maximum bit rate on downlink. 0 .4. 25 dBm –40 . 8 1 .. 8 1 . section 9...) Reference Signal Received Quality of each neighbor (sum of contributions from antennas Rx1 and Rx2).. RSRQ contribution from antenna Tx1 as received on antenna Rx1. 40 dB –40 .9. 8 Description RSRP contribution from antenna Tx2 as received on antenna Rx2. 40 dB –40 ..... 8 1 ... See 3GPP 24. 40 dB –40 . 8 1 . either IPv4 or IPv6. 80000 kbit/s 1 .4. Aggregate maximum bit rate on uplink..301. 40 dB –40 .. Text 1 .. 40 dB Arg 1 . 9 Address type: IPv4 or IPv6. (No equivalent scanner IE... 0 .) 1 . See 3GPP 24...) RSRQ contribution from antenna Tx2 as received on antenna Rx1... Equivalent to scanned RSRQ Tx1. Text 1 .9. 9 120 . 80000 kbit/s 1 . section 9... Equivalent to scanned RSRQ Tx2.. 9 User address.. RSRQ contribution from antenna Tx2 as received on antenna Rx2..0: Information Elements and Events IE Name Neighbor Cell RSRP Tx2 Rx2 (dBm) Neighbor Cell RSRQ (dBm) Neighbor Cell RSRQ Tx1 Rx1 (dBm) Neighbor Cell RSRQ Tx1 Rx2 (dBm) Neighbor Cell RSRQ Tx2 Rx1 (dBm) Neighbor Cell RSRQ Tx2 Rx2 (dBm) PDN Connection IEs: General remark PDN Connection Address PDN Connection Address Type PDN Connection AMBR DL (kbit/s) PDN Connection AMBR UL (kbit/s) Range/Unit –140 .TEMS Investigation 11....2.... RSRQ contribution from antenna Tx1 as received on antenna Rx2. Argument: Just a sequence number pointing to a PDN connection. (No equivalent scanner IE. . 8 – LZT 138 0375 R1A 121 . 31 0 .213. See 3GPP 36. section 7..1.Chapter 3. 31 – – Frame error rate on the PDSCH..1. 100 % 0 .7.. PDSCH. Name of modulation method used for modulation of downlink Transport Block 0. EPS Default Bearer associated with each PDN connection. section 7.7.. 0 .. Information Elements IE Name PDN Connection APN PDN Connection Default Bearer ID PDN Connection Index PDN Connection Number Of PDSCH IEs: General remark PDSCH FER (%) PDSCH MCS0 Range/Unit Text Arg 1 . PDSCH MCS1 PDSCH Modulation TB0 (bits) PDSCH Modulation TB0 (Text) PDSCH Modulation TB1 (bits) 0 .1. 9 Description Host name or network Access Point Name.7.. 5 . The number of bits used for modulation of downlink Transport Block 0. 9 – Number of active PDN connections.. 15 1 . 8 – – Text – 0 .... 8 1 . The number of bits used for modulation of downlink Transport Block 1.213. section 7. Modulation Coding Scheme index for downlink Transport Block 0.1.213... 0 ..1.... These elements concern the Physical Downlink Shared Channel.... See 3GPP 36. 9 PDN connection index. Modulation Coding Scheme index for downlink Transport Block 1..1. 9 0 .. See 3GPP 36. See 3GPP 36. Throughput on the PUSCH.1. Precoding Matrix Indicator.213. Name of modulation method used for modulation of the uplink transport block.1. See 3GPP 36.7.. PUSCH Modulation (bits) PUSCH Modulation (Text) PUSCH Phy Throughput (kbit/s) PUSCH Resource Blocks 0 . Modulation Coding Scheme index for the uplink transport block. section 7..213.213.1.0: Information Elements and Events IE Name PDSCH Modulation TB1 (Text) PDSCH Number Of Used Transport Blocks PDSCH Phy Throughput (kbit/s) PDSCH Resource Blocks PMI PUSCH IEs: General remark PUSCH FER (%) PUSCH MCS Range/Unit Text Arg – Description Name of modulation method used for modulation of downlink Transport Block 1.7. 0 . 0 . equal to N_PRB in 3GPP 36. 8 – Text – 0 . 110 – Throughput on the PDSCH.... 31 – – Frame error rate on the PUSCH.. PUSCH..TEMS Investigation 11. section 7... 2 – 0 ... 1 . – Number of PDSCH resource blocks. Number of used downlink transport blocks.. 80000 kbit/s 1 .7. equal to N_PRB in 3GPP 36. The number of bits used for modulation of the uplink transport block.. section 7.7.. section 7. 100 % 0 ..1. 15 – These elements concern the Physical Uplink Shared Channel..1.1.. 122 .213.. 110 – – Number of PUSCH resource blocks. 80000 kbit/s 1 . 100000 m 0 .. Cell search. Name of each cell. See 3GPP 36. Obtained from DRT only.... 0 ..212. 503 Center Frequency Offset of each cell scanned. 25 dBm 0 ... RRC State Text – “Sc 1st” IEs: General remark These elements derive from LTE Signal scanning. Ready. Initial activation... LZT 138 0375 R1A 123 .Chapter 3. Connected. RRC connected. 25 dBm 0 . –10000 . Argument: Refers to an LTE cell.. Await next best cell... 503 Distance from scanning device to each cell scanned. Connecting. Sc 1st Channel RSSI (dBm) – The power in the entire LTE channel bandwidth. Information Elements IE Name RI RRC Cell Selection State Range/Unit 1 .. Requires cell file.. 4 Text Arg – – Description Rank Indication.2.. 503 Cell Identity (equal to 3 × PCIG + PCI) for each cell scanned. 503 BCH RSSI for each cell scanned. The ordinal “1st” means that these IEs pertain to the first EARFCN scanned. One of: Deactivated. RRC state. 503 0 . Sc 1st Cell Identity Sc 1st Cell Name Sc 1st CFO (Hz) 0 . The sorting order within each element depends on the setting in the General window: see UM section 11.. RRC cell selection state..5.. 503 Text 0 . One of: Deactivated. No service. Sc 1st BCH RSSI (dBm) Sc 1st Cell Distance (m) –140 . Releasing. Obtained from PCTel only. Camping.1. 10000 Hz –140 .. Obtained from DRT only. Await cell evaluation. Requires cell file and GPS positioning data for the scanning device... Camping.. . 503 0 . P-SCH received power for each cell scanned.. Reference Signal CINR for each cell scanned. 503 0 .... 25 dBm –140 .. Reference Signal RSSI for Tx port 3 for each cell scanned.. 503 0 .... 25 dBm –40 . Reference Signal Received Quality for Tx port 2 for each cell scanned..... 503 0 .. Reference Signal RSSI for Tx port 2 for each cell scanned.. for each cell scanned... 1023 samples Arg 0 . 25 dBm –40 .... 25 dBm –140 ... 503 Description Delay spread. Reference Signal RSSI (sum total over all Tx ports) for each cell scanned..552 ns. Sc 1st EARFCN Sc 1st No Of Cell Identities Sc 1st P-SCH RP (dBm) Sc 1st RS CINR (dB) Sc 1st RSRP (dBm) Sc 1st RSRP Tx1 (dBm) Sc 1st RSRP Tx2 (dBm) Sc 1st RSRP Tx3 (dBm) Sc 1st RSRP Tx4 (dBm) Sc 1st RSRQ (dB) Sc 1st RSRQ Tx1 (dB) Sc 1st RSRQ Tx2 (dB) Sc 1st RSRQ Tx3 (dB) 0 .... 40 dB –40 ..... 40 dB 0 . 29649 0 ..... 503 0 . Reference Signal Received Quality (sum total over all Tx ports) for each cell scanned. 503 0 . EARFCN of each cell scanned..0: Information Elements and Events IE Name Sc 1st Delay Spread Range/Unit 0 . 40 dB –40 . 25 dBm –140 . 25 dBm –140 . 503 – 0 . Reference Signal RSSI for Tx port 1 for each cell scanned.. 503 0 . expressed as a number of sample times Ts.72 MHz) or 32. 60 dB –140 . 503 0 . 503 0 ... Reference Signal Received Quality for Tx port 1 for each cell scanned.... Total number of detected Cell Identities on this EARFCN.. equal to 1 / (30...TEMS Investigation 11.. 503 0 . Reference Signal Received Quality for Tx port 3 for each cell scanned.. Reference Signal RSSI for Tx port 4 for each cell scanned...... 504 –140 . 503 124 . 40 dB –40 ... Ts is the shortest time interval defined in the LTE system. . Sc 1st S-SCH RP (dBm) Sc 1st Time Offset (μs) –140 ... 503 DRT: Synch Channel (not specified as P-SCH or S-SCH) Received Quality for each cell scanned. sorted by descending RSRQ (Es/Io). 503 0 . The argument...1). 60 dB Arg 0 . 40 dB –40 . Note: More IEs are provided for frequencies 1–4 than for frequencies 5–12... where present.5.....) EARFCN scanned.. “Sc 2nd (etc.. unless otherwise indicated..)” IEs: General remark These elements are analogous to “Sc 1st” but pertain to the second (etc. PCTel: P-SCH Received Quality for each cell scanned. the offset is the time from the last one-second tick modulo 10.Chapter 3. “Sc Best” IEs: General remark “Sc RSSI” IEs: General remark These elements derive from RSSI scanning. –140 . 25 dBm 0 .. In other words.000 μs (= 10 ms). 1000 RSSI for each scanned cell... 107 μs 0 . is a sequence number pointing to scanned frequencies as specified by the “Sc RSSI Frequency (MHz)” element. 503 0 .. 503 S-SCH Received Power for each cell scanned. Sc 1st SCH RQ (dB) –40 .. 25 dBm 1 . Note: Fewer IEs are provided than for any individual EARFCNs.2.. DRT: Synch Channel (not specified as P-SCH or S-SCH) CINR for each cell scanned.. 503 Description Reference Signal Received Quality for Tx port 4 for each cell scanned.. Sc RSSI (dBm) LZT 138 0375 R1A 125 . 40 dB 0 . Time offset (in μs) from the beginning of the current frame. adjusted so that a frame begins at the GPS one-second tick epoch.. The sorting order within the “Best” elements is not affected by the settings in the General window (see UM section 11. Information Elements IE Name Sc 1st RSRQ Tx4 (dB) Sc 1st SCH CINR (dB) Range/Unit –40 . PCTel: P-SCH CINR for each cell scanned. These elements combine cells from all scanned EARFCNs.. Distance from UE to the serving cell. 1000 1 . see 3GPP 36... Band to which each scanned cell belongs... 6 · 106 MHz These elements pertain to the current serving cell.4 MHz. 10 MHz. 1000 1 ... Bandwidth used for each scanned cell. 1000 0 . 29649 1 ..101.TEMS Investigation 11. Regarding EARFCN numbering. Regarding EARFCN numbering.. Cell Identity of serving cell. Frequency of each cell scanned. 25 dBm 0 . – Serving Cell DL Bandwidth Serving Cell DL EARFCN Serving Cell DL Pathloss (dB) Serving Cell Identity Text – Downlink bandwidth of serving cell... One of: 1. –140 .0: Information Elements and Events IE Name Sc RSSI (dBm) [EARFCN] Sc RSSI Band Sc RSSI Bandwidth Sc RSSI Count Sc RSSI EARFCN Sc RSSI Frequency (MHz) “Serving Cell” IEs: General remark Serving Cell Channel RSSI (dBm) Serving Cell Distance (m) Range/Unit –140 . 29649 – –140 . 1000 – 1 .... Number of cells scanned. 5 MHz. 503 – – 126 . see 3GPP 36. 0 . Requires cell file and UE positioning data... Downlink EARFCN of serving cell... equal to 3 × PCIG + PCI. 1000 Description RSSI for each scanned cell. EARFCN of each scanned cell.. 15 MHz. 3 MHz. 29649 Arg 0 .. Downlink pathloss for serving cell.. 0 .. Argument: EARFCN. 25 dBm Text Text 0 ... 50000 m – Received signal strength on the EARFCN the serving cell is using. 25 dBm 0 .... 20 MHz...101. 25 dBm –140 .. (No equivalent scanner IE..Chapter 3..) RSRP contribution from antenna Tx2 as received on antenna Rx1.. 40 dB –40 . (No equivalent scanner IE. Requires cell file. RSRQ contribution from antenna Tx1 as received on antenna Rx1...) Reference Signal Received Quality. Name of serving cell. RSRP contribution from antenna Tx1 as received on antenna Rx1. 25 dBm – – CINR for serving cell Reference Signal..... RSRQ contribution from antenna Tx1 as received on antenna Rx2.... 65535 0 . (No equivalent scanner IE. 65535 Text Arg – – – Description MCC of serving cell.... MNC of serving cell. RSRP contribution from antenna Tx1 as received on antenna Rx2. Information Elements IE Name Serving Cell MCC Serving Cell MNC Serving Cell Name Serving Cell RS CINR (dB) Serving Cell RSRP (dBm) Serving Cell RSRP Tx1 Rx1 (dBm) Serving Cell RSRP Tx1 Rx2 (dBm) Serving Cell RSRP Tx2 Rx1 (dBm) Serving Cell RSRP Tx2 Rx2 (dBm) Serving Cell RSRQ (dB) Serving Cell RSRQ Tx1 Rx1 (dB) Serving Cell RSRQ Tx1 Rx2 (dB) Range/Unit 0 ... Equivalent to scanned RSRP Tx2. Equivalent to scanned RSRP Tx1. Equivalent to scanned RSRQ Tx1.) – – –140 . since the scanner has only one antenna [Rx1].. 40 dB –40 . Reference Signal Received Power. 60 dB –140 . 40 dB – – – – – LZT 138 0375 R1A 127 .. –40 .. RSRP contribution from antenna Tx2 as received on antenna Rx2. 25 dBm –140 . Sum of contributions from antennas Rx1 and Rx2. Sum of contributions from antennas Rx1 and Rx2. 25 dBm –40 . 25 dBm –140 .. .. Speed in mph.. 6 · 106 kHz 0 .. 250 km/h 0 . 40 dB –40 . 128 ... RSRQ contribution from antenna Tx2 as received on antenna Rx2.. 3001 – – Scanned frequencies in ascending order. The argument. The same elements are used for both uplink and downlink bands.. where present. RSSI of frequencies scanned. 40 dB Text 0 . 3001 –140 . 16 1 . Uplink EARFCN of serving cell.. –140 . Speed in km/h. Argument: The frequencies are sorted by decreasing RSSI. The number of frequencies swept by the scan... 0 . – – – These elements are populated by spectrum analysis scanning... 3001 – 1 .....0: Information Elements and Events IE Name Serving Cell RSRQ Tx2 Rx1 (dB) Serving Cell RSRQ Tx2 Rx2 (dB) Serving Cell TAC Serving Cell UL EARFCN “Spectr Ana” IEs: General remark Range/Unit –40 .. Equivalent to scanned RSRQ Tx2.TEMS Investigation 11.. Regarding EARFCN numbering.) Tracking Area Code of serving cell.101... (No equivalent scanner IE. see 3GPP 36. 16 Received signal strength. Spectr Ana Sc Freq (kHz) Spectr Ana Sc No Of Freq Spectr Ana Sc RSSI (dBm) Speed (km/h) Speed (mph) “Strongest Sc RSSI” IEs: General remark Strongest Sc RSSI (dBm) Strongest Sc RSSI Band These elements contain RSSI scan data. 25 dBm 0 . 25 dBm Text 1 .... Scanned frequency band. 160 mph 1 . is a sequence number pointing to scanned frequencies as indicated by the “Spectr Ana Sc Freq (kHz)” element... 29649 Arg – Description RSRQ contribution from antenna Tx2 as received on antenna Rx1. .... 16 Description Scanned EARFCN. Time (ms) 0 ... Information Elements IE Name Strongest Sc RSSI EARFCN Strongest Sc RSSI Frequency (kHz) Time Range/Unit 0 . 29649 0 . 86400000 ms –140 .Chapter 3.... LZT 138 0375 R1A 129 . Current time in ms.mm. where mm = decimal seconds.. 25 dBm – UE TxPower (dBm) – UE transmit power.. Scanned frequency.. Text – Current time in text format: HH:MM:SS. 6 · 106 kHz Arg 1 . 16 1 . Reported by positioning equipment. as well as many that also make an appearance in the GSM and/or WCDMA categories. DPCH C/I for worst timeslot.. –25 dBm – – – – Average DPCH C/I taken over all timeslots.. – – – Cell Radio Network Temporary Identity..4.. 20 dB –20 .. 8848 m 0 .TEMS Investigation 11.. Information Element Table IE Name Altitude (ft) Range/Unit –1312 . 60 dB –30 . TD-SCDMA Information Elements This category includes a large number of elements that are not TDD-specific. –30 . SIR target ordered for DCH. Altitude (m) C-RNTI DCH SIR (dB) DCH SIR Target (dB) DPCH IEs: General remark DPCH C/I Average (dB) DPCH C/I Best (dB) DPCH C/I Worst (dB) DPCH ISCP Average (dBm) All of these elements are calculated over the phone’s latest reporting period. Reported by positioning equipment. See 3GPP 36.321. 60 dB –30 .0: Information Elements and Events 3. see section 4. 130 .. 29028 ft –400 .. The latter elements relate to parts of the 3GPP specifications that TD-SCDMA shares with GSM and/or WCDMA.... Average DPCH ISCP taken over all timeslots.. – Height above sea level in meters. 20 dB Arg – Description Height above sea level in feet..2 for specifics... Signal-to-interference ratio measured on the DCH... 65535 –20 .. DPCH C/I for best timeslot. 60 dB –116 . Note that dual mode TD-SCDMA/GSM terminals also populate elements in the GSM category. ARFCNs of measured GSM neighbors. DPCH RSCP for best timeslot.... –25 dBm –116 .... Argument: See GSM Neighbor ARFCN. DPCH ISCP for worst timeslot. 6 Arg – – – – – – Description DPCH ISCP for best timeslot.Chapter 3. Number of downlink timeslots occupied by one or more DPCH(s) at least once during the latest reporting period..... Version number of device firmware. Direction of travel measured in degrees clockwise from north. Information Elements IE Name DPCH ISCP Best (dBm) DPCH ISCP Worst (dBm) DPCH RSCP Average (dBm) DPCH RSCP Best (dBm) DPCH RSCP Worst (dBm) DPCH Timeslot Count DL Range/Unit –116 . –25 dBm –116 .. 6 – Text See section 3. 360 degrees – – Device model. Number of uplink timeslots occupied by one or more DPCH(s) at least once during the latest reporting period.. DPCH RSCP for worst timeslot.1 under “ARFCN BCCH” Text – 1 .. LZT 138 0375 R1A 131 .. Argument: See GSM Neighbor ARFCN. etc.. GSM Neighbor RxLev (dBm) –110 .. Average DPCH RSCP taken over all timeslots.. –47 dBm 1 . Argument: 1 gives the neighbor with the highest signal strength. –25 dBm –116 ... –25 dBm –116 . DPCH Timeslot Count UL Firmware Version GSM Neighbor ARFCN 1 .. 16 Base Station Identity Codes (in text format) of measured GSM neighbors. 16 GSM Neighbor BSIC 1 . Hardware Heading Text 0 .... –25 dBm 1 .. 16 RxLev of measured GSM neighbors. 65535 0 . C/I for non-HS DPCH associated with HS session. The maximum value of the CQI (Channel Quality Indicator) during the latest reporting period...... See 3GPP 25.306. – – – – – HS CQI (Mean) 0 . section 6A. ACK / (NACK + ACK) ratio on the HSDSCH. 30 – The minimum CQI value during the latest reporting period.. –25 dBm –116 . Block error rate on the HS-DSCH for first transmission.. 30 – The mean CQI value during the latest reporting period. 30 See Description Arg – – Description HSPA Radio Network Temporary Identity. SIR for non-HS DPCH associated with HS session.. 20 dB 0 ...0: Information Elements and Events IE Name H-RNTI HS 16-QAM Modulation Rate HS Assoc DPCH C/I (dB) HS Assoc DPCH ISCP (dBm) HS Assoc DPCH RSCP (dBm) HS Assoc DPCH SIR (dB) HS CQI (Max) Range/Unit 0 .2..TEMS Investigation 11. RSCP for non-HS DPCH associated with HS session. The definition of the CQI values is given in 3GPP 25.. 100 % – – 132 ..214... Compare HS CQI (Max). 100 % –30 ... Table 5. expressed as a percentage of time.1a. 60 dB –116 . HSDPA Category HS-DSCH ACK Rate HS-DSCH BLER Text – HSDPA Category which the UE reports support for... Use of 16-QAM as modulation method.. HS CQI (Min) 0 . –25 dBm –20 .. 0 .. Compare HS CQI (Max). 100 % 0 . ISCP for non-HS DPCH associated with HS session. MAC-hs PDU receive rate expressed in kbit/s...... Best ISCP among all HS-PDSCHs in use. 60 dB –30 . 16 – – – – Average C/I taken over all HSPDSCHs (= all timeslots) in use.. NACK / (NACK + ACK) ratio on the HS-DSCH. 1456 bytes 0 .. Percentage of MAC-hs PDUs discarded.... Best C/I among all HS-PDSCHs in use. –25 dBm –116 .. 100 % 0 ....Chapter 3. Retransmission rate on the HS-DSCH.. – – – – Average size of MAC-hs PDUs. Worst C/I among all HS-PDSCHs in use.... 60 dB –30 . –25 dBm – – LZT 138 0375 R1A 133 . –116 . Information Elements IE Name HS-DSCH DTX Rate HS-DSCH NACK Rate HS-DSCH Retransmission Rate HS MAC PDU Average Size HS MAC PDU Discard Rate (%) HS MAC PDU Receive Rate (kbit/s) HS-PDSCH IEs: General remark HS-PDSCH C/I Average (dB) HS-PDSCH C/I Best (dB) HS-PDSCH C/I Worst (dB) HS-PDSCH Codes Used HS-PDSCH ISCP Average (dBm) HS-PDSCH ISCP Best (dBm) Range/Unit 0 . 100 % 0 .. Average ISCP taken over all HSPDSCHs (= all timeslots) in use. 2500 kbit/s Arg – Description DTX rate on the HS-DSCH: Percentage of TTIs estimated by the phone as “not used” on downlink.. 100 % 0 . – All of these elements are calculated over the phone’s latest reporting period. Average number of channelization codes used on the HS-DPSCH over the latest reporting period. 60 dB 0 .. –30 .. 100 % 0 ... .... (Single value reported regardless of the number of HS-PDSCHs in use. –25 dBm –116 .. Average RSCP taken over all HSPDSCHs (= all timeslots) in use. 4 Arg – Description Worst ISCP among all HS-PDSCHs in use.) Number of timeslots occupied by an HS-PDSCH at least once during the latest reporting period.. C/I reported for HS-SCCH. 0: No 1: Yes – – – – – 0 . –20 dB 0 .0: Information Elements and Events IE Name HS-PDSCH ISCP Worst (dBm) HS-PDSCH RSCP Average (dBm) HS-PDSCH RSCP Best (dBm) HS-PDSCH RSCP Worst (dBm) HS-PDSCH SIR (dB) HS-PDSCH Timeslots Used HS QPSK Modulation Rate HS-SCCH C/I (dB) HS-SCCH ISCP (dBm) HS-SCCH RSCP (dBm) HS-SCCH SIR (dB) HS Session Range/Unit –116 .. Use of QPSK as modulation method.... ISCP reported for HS-SCCH... HS-PDSCH signal-to-interference ratio. RSCP reported for HS-SCCH.. –25 dBm –116 . –25 dBm –116 .. –25 dBm –20 . Worst RSCP among all HS-PDSCHs in use. –25 dBm –20 . 1 – – – – – – 134 . Best RSCP among all HS-PDSCHs in use. 60 dB –116 ... Indicates whether or not HSPA is currently being used.. SIR reported for HS-SCCH.. expressed as a percentage of time. –25 dBm –116 . –20 dB 0 ...TEMS Investigation 11..... 100 % –30 . . Latitude in decimal degrees. 254 – Number of HSPA transport block sizes currently in use. Latitude recorded by positioning equipment. accumulated over the current session. Block counts for HSPA transport block sizes currently in use. 254 Block counts for HSPA transport block sizes currently in use. Argument: 1 represents the first TBS used (not TBS 1). See 3GPP 23.4. 14043 bits 1 ..Chapter 3. HS Transport Block Sizes No Of IMEI 0 . etc. For the presentation format. International Mobile Subscriber Identity. 65535 Arg – 1 . HS Transport Block Count (Curr) 0 . 90 degrees Text Text – – – –180 ... 65535 1 . Argument: 1 represents the first TBS used (not TBS 1).003... etc. Text – IMSI Text – Latitude Latitude (Text) Latitude Decimal Degrees (Text) Longitude –90 . 180 degrees – LZT 138 0375 R1A 135 . See 3GPP 23. collected over the latest report period. Latitude as text. 254 Description Same as HS Session but in text format... the unique equipment identity of the phone. etc... presented as text.. International Mobile Equipment Identity. the unique identity of the SIM in the phone. Longitude recorded by positioning equipment....003... HS Transport Block Size 0 ... see TR section 2. 254 Transport block sizes on the HSDSCH. Information Elements IE Name HS Session (Text) HS Transport Block Count (Accu) Range/Unit Text 0 . Argument: 1 represents the first TBS used (not TBS 1). 0: Information Elements and Events IE Name Longitude (Text) Longitude Decimal Degrees (Text) Mode Mode (Num) Range/Unit Text Text Arg – – Description Longitude as text.. 32 1 .. 32 Cell Parameter Identity for each neighbor.. For the presentation format. Requires cell file. 0 . 7 – – Mode .. 0 dB –116 . Pathloss for each neighbor.System (Text) Neighbor IEs: General remark Neighbor Carrier RSSI Neighbor Cell Name Neighbor CPI Neighbor Pathloss Neighbor PCCPCH Ec/No Neighbor PCCPCH RSCP Text – Same as Mode ... –25 dBm 1 . –131 .System but in text format.. Same as Mode (Num) but in text format. These elements pertain to neighbors of the current serving cell.System 1 .. Name of each neighbor. 25 dBm Text 1 .. Argument 1 thus points to the strongest neighbor.. 127 46 .. see TR section 2.. Relevant values: 2: Idle mode 3: Dedicated mode Text 1 .. presented as text. Argument: The elements are sorted by descending RSCP. P-CCPCH Ec/No for each neighbor.. 32 1 ..... Longitude in decimal degrees. etc.. 8 – Relevant values: 2: GSM 8: TD-SCDMA Mode ..4..... 32 1 .. 158 dB –30 . 32 1 . 32 Carrier RSSI for each neighbor. P-CCPCH received signal code power for each neighbor. 136 .TEMS Investigation 11.. 0 .. 32 Description Primary UARFCN of each neighbor. Text – Same as RRC State (Num) but in text format.... 100 % 1 . Argument: RLC entity.. Packet TMSI in hexadecimal format. P-TMSI 0 . Argument: RLC entity. 232 – 1 – Packet TMSI (Temporary Mobile Subscriber Identity).... Argument: RLC entity...Chapter 3. 32 RLC uplink throughput for each data bearer.. Argument: PDP context index. 32 RLC uplink retransmission ratio for each data bearer. counted from the first Activate PDP Context Request message to Activate PDP Context Accept. 16383 (frequency band dependent) 0 .. P-TMSI (Hex) RLC DL Throughput (kbit/s) RLC UL Retransmission Ratio (%) RLC UL Throughput (kbit/s) RRC State Text 0 .. RLC downlink throughput for each data bearer. 32 0 ... see 3GPP 23.003. 60000 ms Arg 1 . PDP Context Completion Time (ms) 1 . 2500 kbit/s – 1 ... 1000 kbit/s 1 . Information Elements IE Name Neighbor UARFCN Range/Unit 0 ... LZT 138 0375 R1A 137 .... 11 Time to complete establishment of PDP context. “Sc <nth>” elements: General remark These elements contain pilot scan data from a particular UARFCN......3. chapter 7. The same family of elements are populated in the Midamble and Sync DL modes. It is taken either over the Midamble for TS0 or over SyncDL..0: Information Elements and Events IE Name RRC State (Num) Range/Unit 0 . see UM section 12. and the information element is then updated each time the state changes. though with certain differences of detail as noted below. Cell Name Sc . Sc ... Cell Distance (m) 0 .TEMS Investigation 11. Requires cell file and UE positioning data. 5 Arg – Description State of RRC protocol: 0: No service 1: Idle mode 2: Connected_Cell_FACH 3: Connected_Cell_DCH 4: Connected_Cell_PCH 5: Connected_URA_PCH The state is set to idle when the UE registers. Ec/Io (dB) Text 1 . See 3GPP 25... 128 Distance to the cell in meters. 128 Cell Parameter Id of the cell..3... Argument: The sorting order within each element depends on the General window setting: see UM section 12... This is the primary measurement for pilot scanning... 138 .. 0 . Requires cell file. CPI Sc .331. 0 dB 1 .. depending on the Measurement Mode setting. The received energy per chip divided by the relevant measured power density (noise and signal) in the wide band... Sc .. 1 · 105 m 1 .. 127 –32 .. 128 1 . 128 Name of the cell site. ... see UM section 12. The argument. 0 dB Arg 1 .3. SIR (dB) –115 . 25599 chip/4 1 . LZT 138 0375 R1A 139 . “Sc RSSI” elements: General remark Sc RSSI (dBm) These elements derive from RSSI scanning.. Position of a selected CPI in quarters of chips from the internal 1/200th second time mark that is aligned with GPS time. 1500 RSSI for each scanned frequency. Invalid if either pilot or interference is missing. again see UM section 12. 20 dB 0 . Wide-band channel power of the UARFCN... 128 “Sc Best” elements These elements combine cells from all scanned UARFCNs.. The sorting order of the “Best” elements is not affected by the settings in the General window (see UM section 12.... Time Offset 1 . 128 Sc . Information Elements IE Name Sc . Sc . –25 dBm 0 .. 128 –20 . Number of cells detected on the UARFCN... if a GPS signal is present. Argument (where present): 1 is the cell with the highest Ec/Io. Regarding pilot scanning in general...... where present.. sorted by descending Ec/Io. Peak pilot signal-to-interference ratio. –131 ..... 128 Description SyncDL Ec/Io measured over TS0: the received energy per chip divided by the relevant measured power density (noise and signal) in the wide band. is a sequence number pointing to scanned frequencies as specified by the “Sc RSSI Frequency (MHz)” element....... UARFCN 0 .. Eps/Io (dB) Range/Unit –32 . No Of CPI Sc ... 128 Sc .. unless otherwise indicated.. Scanned UARFCN. 25 dBm 1 .. 128 – 1 .Chapter 3.3). 16383 (frequency band dependent) 1 . etc. Antenna 1 radiation is used.... Io (dBm) Sc .3. Valid for Midamble measurement mode only. 1500 Description RSSI for each scanned frequency. 140 ... 127 – Cell Parameter Identity of serving cell.. “FFFFFFF” Text – – – – Carrier RSSI for serving cell... Serving Cell Name Serving CPI – Name of serving cell. –30 . These elements pertain to the current serving cell.0: Information Elements and Events IE Name Sc RSSI (dBm) [UARFCN] Sc RSSI Band Sc RSSI Count Sc RSSI Frequency (MHz) Sc RSSI UARFCN Serving IEs: General remark Serving C/I Range/Unit –131 . Requires cell file. Frequency scanned. 0 ..TEMS Investigation 11. 6000 MHz 0 . Serving Carrier RSSI Serving Cell Id Serving Cell Id (Dec) Serving Cell Id (Hex) –131 .. 228 – 1 Text Text: “0000000” .... Number of frequencies scanned. Cell identity of serving cell: text string in hexadecimal format. 25 dBm Text 0 .... Cell identity of serving cell. UARFCN where each scanned frequency is located.. 25 dBm 0 .. 1500 1 ... Argument: UARFCN. 16383 1 . 1500 0 .. Cell identity of serving cell: text string in decimal format. 60 dB – C/I of serving cell.... 1500 – 1 .. Valid only if Serving Current UARFCN = Serving Primary UARFCN.. 16383 Arg 0 . Band to which each scanned frequency belongs.... Calculated as Serving P-CCPCH RSCP – Timeslot ISCP (dBm) for timeslot 0 (the timeslot always used by the P-CCPCH). 65535 Text: “0000” . 999 46 . 9 0 . The maximum transmit power the terminal is allowed to use. LAC of serving cell in hexadecimal format... 0 dB –116 .. UARFCN used for control signaling by the serving cell.... DRX (Discontinuous Reception) coefficient for serving cell.Chapter 3. –25 dBm –11 . See 3GPP 25.6. 16383 (frequency band dependent) 3 . 33 dBm 000 .. 999 000 ..2.. Serving DRX Coefficient Serving LAC Serving LAC (Hex) Serving Max Allowed UL TxPower (dBm) Serving MCC Serving MNC Serving Pathloss Serving PCCPCH Ec/No Serving PCCPCH RSCP Serving PCCPCH SIR Serving Primary UARFCN – – – – – – – – – – – Serving Q-hysteresis (dB) – Cell reselection parameter Qhyst1s for serving cell: hysteresis value... P-CCPCH signal-to-interference ratio for the serving cell.5. 158 dB –30 . LAC of serving cell.. Mobile Country Code of serving cell.. 20 dB 0 . Pathloss for serving cell..... Information Elements IE Name Serving Current UARFCN Range/Unit 0 . section 5. P-CCPCH received signal code power for the serving cell.. 16383 (frequency band dependent) 0 . May consist of two or three digits. This UARFCN may also be used for traffic..1. Mobile Network Code of serving cell... 40 dB Arg – Description UARFCN currently used by the serving cell: either the Primary UARFCN or a different UARFCN (the latter in dedicated mode only)... P-CCPCH Ec/No for the serving cell. “FFFF” –50 ... LZT 138 0375 R1A 141 .304.. 1.. specifying the minimum required RxLev in the serving cell.5. 6000 MHz 1 .6.. 155 mph – – – These elements contain RSSI scan data. 32 Scanned UARFCN. section 5. Cell reselection parameter Sintrasearch for serving cell: threshold for intrafrequency measurements. 91 dB – 0 . –25 dBm Arg – Description Cell reselection parameter Qrxlevmin.5... 32 Received signal strength. 25 dBm Text 0 .. Argument: The frequencies are sorted by decreasing RSSI.304. 142 . See 3GPP 25..1. See 3GPP 25.. Cell reselection timer value Treselections.304. 0 .....2.5.. section 5. See 3GPP 25..2.304.6..304..0: Information Elements and Events IE Name Serving Q-rxlev-min (dBm) Serving S-intersearch Threshold Serving S-intrasearch Threshold Serving Treselection (s) Speed (km/h) Speed (mph) “Strongest Sc RSSI” IEs: General remark Strongest Sc RSSI (dBm) Strongest Sc RSSI Band Strongest Sc RSSI Frequency (MHz) Strongest Sc RSSI UARFCN Range/Unit –115 .. Scanned frequency. Speed in mph. section 5. Cell reselection parameter Sintersearch for serving cell: threshold for interfrequency measurements. See 3GPP 25.2.. 32 1 ...1. Speed in km/h..... 31 s 0 .1. section 5..6. –131 .2. 250 km/h 0 . Scanned frequency band.6.5.TEMS Investigation 11. 16383 1 . 0 . 32 1 . 91 dB – 0 ... . 16 0 ..... Direction of transmission for each used timeslot: “UL” or “DL”...mm... 8 0 .. Sum of DPCH received signal code powers for all reported timeslots. measured and reported per timeslot.. 6 0 .. 6 LZT 138 0375 R1A 143 .... 6 Text –116 . –25 dBm –116 . 2. Current time in text format: HH:MM:SS. 6 1 . HS-PDSCH C/I..008. 16} on the uplink and {1. where mm = decimal seconds. –25 dBm –30 . Given as raw value in deci-hours (0 means no periodic updates).. 6 – 0 .. 16 0 .. Current time in ms..Chapter 3. 0 . 0 ... Time Text – Time (ms) 0 . 6 Number of channelization codes in use for each timeslot during a non-HS session. 8.. Spreading factor used for the channelization codes in each timeslot. The summing is done in the mW domain. Number of channelization codes in use for each timeslot during an HS session.. 4. 16} on the downlink. See 3GPP 24. Information Elements IE Name T3212 Range/Unit 0 . measured and reported per timeslot. etc. 255 deci-hours Arg – Description Value of timer T3212 controlling periodic location area updating. Dedicated Physical Channel received signal code power. 86400000 ms – Timeslot IEs: General remark Timeslot Code Count Timeslot Code Count HSPDSCH Timeslot Code Spreading Factor Timeslot Direction Timeslot DPCH RSCP (dBm) Timeslot DPCH RSCP Sum (dBm) Timeslot HSPDSCH C/I (dB) The argument is equal to the timeslot index: 0 means TS 0.. Possible values are {1... 60 dB 0 .. . –25 dBm –116 . 0.. –25 dBm –116 . Temporary Mobile Subscriber Identity. Based on the recent history of power control decisions: • The value –1 means that the power has been adjusted predominantly downward. See 3GPP 23.. –25 dBm –16 .. 6 – – – – • • TPC UL –1. 3 dB – 144 . measured and reported per timeslot... 1 – Inner loop power control indication pertaining to the uplink. Timing Advance parameter stated in chip units.... measured and reported per timeslot. Works the same way as TPC DL. 6 0 . 0. The value +1 means that the power has been adjusted predominantly upward.. 6 Description HS-PDSCH interference signal code power. HS-PDSCH received signal code power. which see.. Transmit power control step size in dB........ Interference signal code power for each timeslot. 1 Arg 0 . 232 – 1 Text –1.TEMS Investigation 11.003. 240 chips 0 .0: Information Elements and Events IE Name Timeslot HSPDSCH ISCP (dBm) Timeslot HSPDSCH RSCP (dBm) Timeslot ISCP (dBm) Timing Advance (chips) TMSI TMSI (Hex) TPC DL Range/Unit –116 . TPC Step (dB) 1 . The value 0 means that the upward and downward power adjustments have canceled out exactly. TMSI in hexadecimal format. Inner loop power control indication pertaining to the downlink. 0 . .. Valid only in connected mode.Chapter 3.. LZT 138 0375 R1A 145 .... Frame error rate for voice service.... Identity of each downlink transport channel. 32 1 . UTRAN Radio Network Temporary Identity in decimal.. 232 – 1 Text 0 .. 100 % 0 . 100 % – – – – – UE transmit power in dBm. – 1 . 32 – Block error rate averaged over all downlink transport channels. 33 dBm –120 . Argument: Transport channel index. Argument: Transport channel index.. 30 dBm 0 . 32 Description Block error rate for each downlink transport channel. Uplink pilot channel transmit power. 0 .. UTRAN Radio Network Temporary Identity... Number of downlink transport channels. 100 % Arg 1 ... 32 UE TxPower (dBm) UpPCH TxPower (dBm) U-RNTI U-RNTI (Dec) Voice Frame Error Rate (%) –50 .. Information Elements IE Name Transport Channel BLER DL Transport Channel BLER Total DL Transport Channel Count DL Transport Channel ID DL Range/Unit 0 ... . IE Name Access Channel Max Capsule Size Access Channel Preamble Size Access Initial Power Offset Access Max Req Seq Access Max Rsp Seq Access Num Step Access Power Increment 0 ... 255 – – The argument points to the active set member index. CDMA Information Elements Range/Unit 0 . Open loop transmit power increment in units of 1 dB between successive access probes in an 1x access probe sequence. Maximum number of access probe sequences for each 1x access attempt (used in case of PACA origination). Sequence number of access probe sent during 1x access attempt. See 3GPP2 TS C..0: Information Elements and Events 3. less 3... less 1. Sequence number of access probe sequence sent during 1x access attempt. 255 dB 0 ... 7 Arg – Description Maximum number of Access Channel or Enhanced Access Channel frames in an Access Channel Message Capsule.. 15 0 .. Maximum number of access probe sequences for each 1x access attempt (used for regular MS origination). 255 0 ....... Number of access probes in each 1x access probe sequence. 15 – 0 . 15 – – 0 .. 255 – 0 .. Number of frames in the Access Channel or Enhanced Access Channel preamble.. 6 Frequency band class for each active set member. less 1.5..TEMS Investigation 11. 146 . 255 dB – – Access Probe Number Access Probe Sequence Number Active Set IEs: General remark Active Set Band Class 0 . Text 1 .S0057B. Initial power offset or adjustment used in the open loop power control procedure. Information Elements IE Name Active Set Cell Name Range/Unit Text Arg 1 .. 511 0 . Total signal-to-noise ratio (Ec/Io in dB) for all active set members. Received signal code power for each active set member..... The number of members in the active set........ 0 .. whether in idle or traffic mode.. 6 – 1 . 6 1 .. 6 1 . Requires cell file. 10 dBm –32 ... 2047 1 . 6 0 .Chapter 3.. The summing is done in the mW domain...... 0 dB 0 .. 3 1 . 1199 0 . SCH QOF mask id used by each active set member.. FCH code channel used by each active set member. 6 LZT 138 0375 R1A 147 .. 0 dB –32 . Pilot PN offset for each active set member... 6 – 1 ... 6 0 ... 6 Channel number of RF channel used by each active set member..... 2047 1 . Signal-to-noise ratio (Ec/Io in dB) for each active set member... 3 1 . 6 0 ... 6 Description Cell name for each active set member as defined in cell file (if available). 6 0 .. Active Set Channel Active Set Count Active Set DCCH Code Channel Active Set DCCH QOF Mask Id Active Set Ec Active Set Ec/Io Active Set Ec/Io Sum Active Set FCH Code Channel Active Set FCH QOF Mask Id Active Set PN Active Set SCH Code Channel Active Set SCH QOF Mask Id 0 . DCCH code channel used by each active set member. FCH QOF mask id used by each active set member.. DCCH QOF mask id used by each active set member... 2047 1 ... 3 1 . 6 –157 . SCH code channel used by each active set member. 2. see section 6. see section 6.. Number of Call End events.3..3. Height above sea level in feet. –25 dBm –1312 . 65535 0 .. 1000 0 .2. AMPS Supplemental Code Channel.. Base ID Call Blocked Count Call Dropped Count Call Success Count Calls Blocked (%) 0 . Calculated as: # blocks / (# blocks + # drops + # ends) where blocks = Blocked Call events drops = Dropped Call events ends = Call End events Regarding the events.. section 2. ERP levels in dBW are found in Table 2. Reported by positioning equipment. 255 0 . 1000 0 . Number of Blocked Call events... Base ID transmitted in Layer 3 message System Parameters.. see section 6. Regarding this event. Regarding this event. Number of Dropped Call events..1.3. See TIA/EIA-553-A..2-1.3. 8848 m –120 .. 1000 0 .. Analog RSSI Analog SCC Analog Tx Power Level – – – Received signal strength indicator for AMPS..TEMS Investigation 11. see section 6. –30 dBm 0 . Transmit power level in AMPS traffic state... 29028 ft –400 . Altitude (m) – Height above sea level in meters.. 7 Arg – – Description Total received signal power in the serving RF channel. 100 % – – – – – 148 ..0: Information Elements and Events IE Name Active Set Serving Io Altitude (ft) Range/Unit –125 ..1. Reported by positioning equipment. Regarding this event..... ... see section 6. Text 1 . 6 –157 . where present. 6 Channel number of RF channel used by each candidate set member. 6 The number of candidate set members.. Pilot PN offset for each candidate set member.... Candidate Set IEs: General remark Candidate Set Band Class Candidate Set Cell Name The argument. 6 1 . 0 dB 0 . See 3GPP2 TS C.. LZT 138 0375 R1A 149 . 6 1 . Requires cell file. 100 % Arg – Description Calculated as: # drops / (# blocks + # drops + # ends) where blocks = Blocked Call events drops = Dropped Call events ends = Call End events Regarding the events.. Candidate Set Count Candidate Set Ec Candidate Set Ec/Io Candidate Set PN – 1 .... points to the candidate set member index. Cell name for each candidate set member.... Received signal code power for each candidate set member.. 6 Candidate Set Channel 0 . 10 dBm –32 . 1023 (dependent on band class) 0 . 6 Frequency band class for each candidate set member. Information Elements IE Name Calls Dropped (%) Range/Unit 0 ...Chapter 3.. 511 1 .3.. Text 1 .S0057-B..... Signal-to-noise ratio (Ec/Io in dB) for each candidate set member. ..0: Information Elements and Events IE Name CDMA Rx State Range/Unit Text Arg – One of: • • • • • • Description “Entering CDMA” “Sync Channel” “Paging Channel” “Traffic Channel Initialization” “Traffic Channel” “Exit” Country ID Dialed Number 0 .S0024-A section 8.6. Maximum number of access probe sequences per EV-DO access attempt. 255 – 150 . Sequence number of access probe sequence sent during EV-DO access attempt.. 255 0 ... Argument: Pilot PN index in Traffic Channel Assignment message.. 999 Text – – MCC. Mobile Country Code.. Data Source Control channel associated with each pilot in the Traffic Channel Assignment message....7. 100 % 0 . The number dialed to initiate the current call. Sequence number of access probe sent during EV-DO access attempt... Number of access probes in each EVDO access probe sequence. 15 EV-DO Access Failure Rate (%) EV-DO Access Max Probe Seq EV-DO Access Probe Count EV-DO Access Probe Num Step EV-DO Access Probe Seq Count 0 ... 255 – Number of failed EV-DO access attempts divided by total number of EVDO access attempts.2. – 0 .. Valid only while a call is in progress. DSC Channels 0 .. 255 – – 0 .2. 8 0 . See 3GPP2 C.TEMS Investigation 11. points to the active set member index... 1 1 ... 7 – –30 . Information Elements IE Name EV-DO Access Result Range/Unit 0 .Chapter 3. 6 EV-DO Active Set Drop Timer Expired 0 .. 3 Arg – Description Result of EV-DO access attempt: 0: ACAck not received 1: ACAck received 2: TCA message received 3: Probe Interrupted EV-DO Active Set IEs: General remark EV-DO Active Set DRC Cover EV-DO Active Set DRC Lock EV-DO Active Set Drop Timer Active The argument...... 0: Inactive 1: Active Text 1 . 15 dB – LZT 138 0375 R1A 151 . 6 EV-DO: DRC cover for each active set member. EV-DO: DRC lock status for each active set member: “Locked”/ ”Unlocked”. EV-DO: Drop timer for each active set member.. 1 1 . 0 .... EV-DO: DRC cover for the active set pilot currently having the best predicted SINR. 7 1 . 127 1 .. 6 0 ... 6 EV-DO: The medium access control index associated with each active set member. 0 .. 6 EV-DO: Drop timer status for each active set member.. EV-DO: Predicted SINR for the active set pilot currently having the best predicted SINR. where present..... 0: Drop timer running 1: Drop timer expired EV-DO Active Set MAC Index EV-DO Active Set Predicted DRC EV-DO Active Set Predicted SINR 0 .. See 3GPP2 TS C. EV-DO: Signal to interference-plusnoise ratio for each active set member.. EV-DO Active Set RAB Usage (%) EV-DO Active Set RPC Index EV-DO Active Set RPC Indication 0 ...2. EV-DO: DRC cover for the current serving active set pilot.. 100 % 1 .2.3. a running average of the last 64 reverse power control bits. 7 – 0 .1..3. EV-DO: Reverse power control index for each active set member. EV-DO: PN offset for the current serving active set pilot. EV-DO: RPC index for the current serving active set pilot. 6 0 . EV-DO: For each active set member.. 6 152 .. showing the recent trend of the power control.. Given in chip units. specifies the slots in which a new reverse activity bit can be transmitted. 15 –1 . 6 1 .. 6 Description EV-DO: For each active set member.. EV-DO: Center of search window for each active set member.S0024.1. section 9.2.2.. 1 1 . 15 dB –30 .... EV-DO: For each active set member. See 3GPP2 TS C.4..3. 23768 chips – 1 ...2...S0024. 255 Arg 1 . 511 – 0 ...... 15 – –30 . section 9.. the rate of reverse activity bits during the last PN roll (16 slots).. 15 dB 0 . 6 1 . 6 EV-DO Active Set Serving DRC EV-DO Active Set Serving PN EV-DO Active Set Serving RPC EV-DO Active Set Serving SINR EV-DO Active Set SINR EV-DO Active Set Window Center 0 ...TEMS Investigation 11.0: Information Elements and Events IE Name EV-DO Active Set RAB Offset Range/Unit 0 . calculated as (number of ones) / 16... EV-DO: SINR for the current serving active set pilot... if Actual RRI < Condition RRI.. 255 – – Same as EV-DO AT State (Num) but in text format.. 5 – – Same as EV-DO ALMP State (Num) but in text format. 255 timeslots 0 .. 5 – EV-DO ALMP State (Text) EV-DO AT State (Num) Text 0 .. EV-DO: PN offset for the active set pilot currently having the best predicted SINR. 0: Inactive 1: Initialization 2: Idle 3: Connected EV-DO ALMP State (Num) 0 . Transaction ID of EV-DO access attempt... as there is not enough data to be sent.... 15 dB – LZT 138 0375 R1A 153 . 0: Inactive (AT is switched to 1x or is in Deep Sleep) 1: Acquisition 2: Sync 3: Idle 4: Access 5: Connected EV-DO AT State (Text) EV-DO Attempt Duration EV-DO Attempt Transaction Id EV-DO Best Pilot PN EV-DO Best SINR Text 0 . Time (in slots) taken to complete the EV-DO access attempt. EV-DO: Air Link Management Protocol State.. 511 – –30 . This should be ≤ EV-DO Condition RRI (kbit/s).Chapter 3.. EV-DO access terminal state. EV-DO: Predicted SINR for the active set pilot currently having the best predicted SINR. Information Elements IE Name EV-DO Actual RRI (kbit/s) Range/Unit 0 ... – 0 . then the reverse rate has been demoted.. 1800 kbit/s Arg – Description EV-DO: RRI at which the reverse link packet was transmitted. TEMS Investigation 11.0: Information Elements and Events IE Name EV-DO Candidate Set IEs: General remark EV-DO Candidate Set Drop Timer Active EV-DO Candidate Set Drop Timer Expired EV-DO Candidate Set Window Center EV-DO Color Code EV-DO Condition RRI (kbit/s) Range/Unit Arg Description The argument, where present, points to the candidate set member index. 0 ... 1 1 ... 6 EV-DO: Drop timer for each candidate set member. 0: Inactive 1: Active 0 ... 1 1 ... 6 EV-DO: Status of drop timer for each candidate set member. 0: Drop timer running 1: Drop timer expired 0 ... 23768 1 ... 6 EV-DO: Center of search window for each candidate set member. Given in chip units. EV-DO base station color code. EV-DO reverse rate indication calculated according to the algorithm in 3GPP2 TS C.S0024, section 8.5.6.1.5.2. Compare EV-DO Actual RRI (kbit/s). EV-DO Connected State. 0: Inactive 1: Open 0 ... 255 0 ... 1800 kbit/s – – EV-DO Connected State (Num) EV-DO Connected State (Text) EV-DO Connection Failure Rate (%) 0 ... 5 – Text – Same as EV-DO Connected State (Num) but in text format. Number of failed EV-DO connection attempts divided by total number of EVDO connection attempts. 0 ... 100 % – 154 Chapter 3. Information Elements IE Name EV-DO DRC Rate Received (kbit/s) EV-DO DRC Rate Received Average (kbit/s) EV-DO DRC Rate Requested (kbit/s) EV-DO DRC Rate Requested Average (kbit/s) EV-DO DRC State EV-DO Finger IEs: General remark EV-DO Finger Antenna Selection Range/Unit 0 ... 4000 kbit/s 0 ... 4000 kbit/s Arg – Description EV-DO received downlink data rate, instantaneous value. EV-DO received downlink data rate, running average. – 0 ... 4000 kbit/s – EV-DO downlink data rate requested by terminal, instantaneous value. 0 ... 4000 kbit/s – EV-DO downlink data rate requested by terminal, running average. Text – EV-DO DRC state: “Fixed” or “Dynamic”. The argument points to an EV-DO finger index. 0 ... 1 1 ... 12 Antenna(s) selected for each EV-DO finger. Of interest only if the access terminal is equipped with two antennas and is enabled to use both. 0: Antenna 0 1: Antenna 1 EV-DO Finger C/I Antenna 0 –30 ... 15 dB 1 ... 12 EV-DO: When antenna diversity is enabled, for each finger, the cumulative energy of all search results for antenna 0. EV-DO: When antenna diversity is enabled, for each finger, the cumulative energy of all search results for antenna 1. EV-DO Finger C/I Antenna 1 –30 ... 15 dB 1 ... 12 LZT 138 0375 R1A 155 TEMS Investigation 11.0: Information Elements and Events IE Name EV-DO Finger Diversity Enabled Range/Unit 0 ... 1 Arg 1 ... 12 Description State of EV-DO antenna diversity. Relevant only if the access terminal is equipped with two antennas. 0: Not enabled 1: Enabled EV-DO Finger Index EV-DO Finger MSTR 1 ... 12 0 ... 232 – 1 chip/8 1 ... 12 – The index of the EV-DO finger. EV-DO Mobile Station Time Reference: the access terminal’s current timing reference based on the sync channel time (in slots) and on the finger lock to the earliest arriving usable multipath of a pilot. Given in units of 1/8 chip. Finger delay for each EV-DO finger, expressed as an offset from the current MSTR. Given in units of 1/8 chip. EV-DO: PN offset of pilot currently used as timing reference. EV-DO RPC Cell Index. Pilots that have the same RPC bit for the AT share the same value. EV-DO Finger MSTR Error EV-DO Finger MSTR Pilot PN EV-DO Finger RPC Cell Index EV-DO FL IEs: General remark EV-DO FL Bad Packet Count –32767 ... 32767 chip/8 0 ... 511 1 ... 6 1 ... 12 – 1 ... 12 The argument, where present, points to a DRC index. Arg 0 = DRC index 0x1, etc. 0 ... 231 – 1 0 ... 25 For each DRC index, the number of packets on the forward link received with bad CRC, accumulated over latest reporting period. For each DRC index, the number of packets on the forward link received with bad CRC, accumulated from start. For each DRC index, the percentage of bad packets on the forward link. Given for the latest reporting period. EV-DO FL Bad Packet Count (Total) EV-DO FL Bad Packet Rate 0 ... 231 – 1 0 ... 25 0 ... 100 % 0 ... 25 156 Chapter 3. Information Elements IE Name EV-DO FL Bad Packet Rate Multi User (Total) EV-DO FL Good Packet Count EV-DO FL Good Packet Count (Total) EV-DO FL Good Packet Rate EV-DO FL Multi Throughput (kbit/s) EV-DO FL Packet Size EV-DO FL Throughput (kbit/s) EV-DO Hybrid Mode Range/Unit 0 ... 100 % Arg 0 ... 25 Description For each DRC index, the percentage of bad multi-user packets on the forward link, accumulated from start. For each DRC index, the number of packets on the forward link received with good CRC, accumulated over latest reporting period. For each DRC index, the number of packets on the forward link received with good CRC, accumulated from start. For each DRC index, the percentage of good packets on the forward link. Given for the latest reporting period. Instantaneous EV-DO forward link throughput in the multi-user case. 0 ... 231 – 1 0 ... 25 0 ... 231 – 1 0 ... 25 0 ... 100 % 0 ... 4000 kbit/s 0 ... 25 – Text 0 ... 4000 kbit/s Text 0 ... 25 – For each DRC index, the raw bit rate on the forward link (kbit/s). Instantaneous EV-DO forward link throughput. Tells whether the access terminal is in hybrid mode: “On” or “Off”. A terminal in hybrid mode is monitoring both 1x and EV-DO paging channels in idle mode. EV-DO Idle State: 0: Inactive 1: Monitor 2: Sleep 3: Connection Setup 4: Suspend – EV-DO Idle State (Num) 0 ... 5 – LZT 138 0375 R1A 157 TEMS Investigation 11.0: Information Elements and Events IE Name EV-DO Idle State (Text) EV-DO Init State (Num) Range/Unit Text 0 ... 5 Arg – – Description Same as EV-DO Idle State (Num) but in text format. EV-DO Init State: 0: Inactive 1: Network Determination 2: Pilot Acquisition 3: Sync EV-DO Init State (Text) EV-DO Neighbor Set Age EV-DO Neighbor Set Window Offset EV-DO Neighbor Set Window Size EV-DO OVHD Message State (Num) Text 0 ... 65535 – 1 ... 40 Same as EV-DO Init State (Num) but in text format. EV-DO: Age counter for each neighbor set member. See 3GPP2 TS C.S0024, section 6.6.6.1.2.7. EV-DO: Offset (from MSTR) of search window used for each neighbor set member. EV-DO: Size of search window used for each neighbor set member. EV-DO Overhead Message State: 0: Inactive 1: Process All Messages 2: Sleep 3: Frequency Change In Progress 4: Access Handoff In Progress 5: Wait For Link 0 ... 65535 chips 0 ... 65535 chips 0 ... 5 1 ... 40 1 ... 40 – EV-DO OVHD Message State (Text) EV-DO PA State EV-DO PER Instantaneous (%) Text – Same as EV-DO OVHD Message State (Num) but in text format. State of EV-DO power amplifier: “On” or “Off”. EV-DO Packet Error Rate, immediate value (no averaging). Text 0 ... 100 % – – 158 running average over (approximately) 600 reports.Chapter 3. 1800 kbit/s 0 .... running average over (approximately) 60 reports.. 100 % –20 . EV-DO: Offset between Aux Channel and Pilot Channel output powers. EV-DO: Offset between RRI Channel and Pilot Channel output powers...... EV-DO Packet Error Rate..... EV-DO reverse link data rate.... 100 % 0 .. running average. 20 dB 0 . 20 dB –20 . instantaneous value. 1800 kbit/s Text – EV-DO reverse link data rate.. EV-DO: Offset between the ACK Channel and Pilot Channel output powers. Information Elements IE Name EV-DO PER Long (%) EV-DO PER Short (%) EV-DO Power Ratio ACK Pilot EV-DO Power Ratio Aux Pilot EV-DO Power Ratio Data Pilot EV-DO Power Ratio DRC Pilot EV-DO Power Ratio RRI Pilot EV-DO Reverse Rate AN Limit EV-DO Reverse Rate Average (kbit/s) EV-DO Reverse Rate Current (kbit/s) EV-DO Reverse Rate PA Limit EV-DO Revision Range/Unit 0 . EV-DO: Offset between DRC Channel and Pilot Channel output powers. 1800 kbit/s Arg – Description EV-DO Packet Error Rate. EV-DO reverse link data rate limit imposed by power amplifier (PA). EV-DO: Offset between Data Channel and Pilot Channel output powers. EV-DO revision: “Rev 0” or “Rev A”.. 20 dB –20 . 20 dB –20 . EV-DO reverse link data rate limit imposed by access network (AN). – – LZT 138 0375 R1A 159 .. 1800 kbit/s 0 . – – – – – – – – 0 . 20 dB –20 ... the raw bit rate on the reverse link.... For each RL current rate..... EV-DO: Number of received duplicate frames. 5 0 ... where present. 232 – 1 1 . –20 . 231 – 1 – EV-DO: Maximum offset between the Traffic Channel and Pilot Channel output powers. the number of packets sent on the reverse link from start of logfile/since device connect. Instantaneous EV-DO reverse link throughput... points to a reverse link current rate index. 5 1 .. EV-DO Route Update Protocol State: 0: Inactive 1: Idle 2: Connection Setup 3: Connected 4: Synchronize Connection Setup Text – Same as EV-DO Route Update State (Num) but in text format. 5 – – 0 .. Percentage distribution showing the current usage of the reverse link current rates. Based on latest report.. 100 % Text 0 .TEMS Investigation 11. Number of failed EV-DO session attempts divided by total number of EVDO session attempts. 100 % – 160 .. For each RL current rate. 1 . 4 – EV-DO Route Update State (Text) EV-DO Session Failure Rate (%) 0 . 20 dB 0 ..0: Information Elements and Events IE Name EV-DO RL IEs: General remark EV-DO RL Max Traffic To Pilot EV-DO RL Packet Count (Total) EV-DO RL Packet Rate EV-DO RL Packet Size EV-DO RL Throughput (kbit/s) EV-DO RLP RX Duplicate Bytes EV-DO Route Update State (Num) Range/Unit Arg Description The argument... 1800 kbit/s 0 ... .2. 0: Failure 1: Success 0 .. 65535 1 .S0024. EV-DO: Transaction ID sent in UATIRequest message. EV-DO: Random Access Terminal Identifier allocated to the terminal. given as 32-bit values (lowest 4 bytes of full UATI)...2.7.S0024... Success or failure of EV-DO session attempt. 5 – EV-DO session state.1.2. 1 – – EV-DO Session State (Num) 0 .. EV-DO: UATI Color Code sent in UATIAssignment message.. 255 – 0 ... 255 – EV-DO UATI (Hex) Text: “0000” ... 0 ... section 5.. 8 Same as EV-DO UATI (Hex) but in decimal format. 255 0 . 8 EV-DO UATI (Num) 0 . One of: 0: Closed 1: AMP setup 2: AT-initiated negotiation 3: AN-initiated negotiation 4: Open 5: Closing EV-DO Session State (Text) EV-DO Session Transaction ID EV-DO Session UATI Color Code Text – Same as EV-DO Session State (Num) but in text format. as indicated by the AN giving the AT a UATI assignment or not..7. LZT 138 0375 R1A 161 . Information Elements IE Name EV-DO Session Full UATI EV-DO Session RATI EV-DO Session Result Range/Unit Text Arg – Description EV-DO: Full (128-bit) Unicast Access Terminal Identifier allocated to the access terminal..3.3. EV-DO: List of active UATIs (Unicast Access Terminal Identifiers).Chapter 3. section 5. The AN sets this field to the Color Code associated with the subnet to which the UATI belongs. “FFFF” 1 .. See 3GPP2 TS C. see 3GPP2 TS C. Argument: Sequence number. . 100 % 0 . Forward link DCCH frame size in milliseconds. 100 % 0 . 65535 bits – – – – – – – 162 ... Forward link DCCH Radio Configuration as specified in 3GPP2 TS C.1. Table 3. 9 – 0 .. 100 % 0 . Frame erasure rate on the SCH0 (Supplemental Channel 0).1-1.. State of forward link DCCH: “Used”/ ”Not Used”....2.. Forward link FCH bit rate configuration... Frame erasure rate on the FCH (Fundamental Channel)... Number of bits in a forward link FCH physical layer frame.S0002-A. 100 % 0 .S0003-A. 162600 kbit/s 0 . Frame erasure rate on the DCCH (Digital Control Channel)..3. 100 % 0 . 65535 bits Text Arg – – – – Description EV-DO: Number of active UATIs.1. Frame erasure rate on the SCH1 (Supplemental Channel 1). 8 0 . Forward link DCCH bit rate configuration..1. Number of bits in a forward link DCCH physical layer frame. Frame erasure rate calculated over all forward channels..0: Information Elements and Events IE Name EV-DO UATI Count F-DCCH Bitrate (kbit/s) F-DCCH Enabled F-DCCH Frame Length (bits) F-DCCH Frame Size (ms) F-DCCH MUX PDU F-DCCH Radio Configuration FER DCCH (%) FER FCH (%) FER SCH0 (%) FER SCH1 (%) FER Total (%) F-FCH Bitrate (kbit/s) F-FCH Frame Length (bits) Range/Unit 0 .. section 2.. Forward link DCCH MUX PDU type: see 3GPP2 TS C.TEMS Investigation 11... 162600 kbit/s Text 0 . – Text – 1 ... 1. Information Elements IE Name F-FCH Frame Size (ms) F-FCH MUX PDU F-FCH Radio Configuration F-FCH Rate Range/Unit Text Text 1 ... 0x02 (1/2 Rate allowed). one of: 0: No forward traffic 1: Primary traffic 2: Secondary traffic F-FCH Traffic Type (Text) Finger IEs: General remark Finger Count Finger Delay Delta (chips) Finger Delta (ms) Finger Energy (dB) Finger Energy Sum (dB) Text – Same as F-FCH Traffic Type (Num) but in text format. where present.. section 2. 15 – F-FCH Traffic Type (Num) 0 .... 0 ... 9 Arg – – – Description Forward link FCH frame size in milliseconds. Forward link FCH rate bitmask..Chapter 3... 12 2 . 12 Number of valid fingers. 15 dB –64 .. 65535 ms –32 . – LZT 138 0375 R1A 163 .1. Table 3. 12 1 .. instantaneous value: Ec/Io for 1x fingers. Forward link FCH Radio Configuration as specified in 3GPP2 TS C. Total signal-to-noise ratio for all fingers... A combination of: 0x01 (Full Rate allowed).S0002-A.2. SINR for EV-DO fingers.. The argument. Signal-to-noise ratio for each finger: Ec/Io for 1x fingers.3. Forward link FCH MUX PDU type: see 3GPP2 TS C. points to a finger index. Time delta between the earliest finger and each of the other fingers. 0x04 (1/4 Rate allowed). and 0x08 (1/8 Rate allowed) 0 . 12 1 . SINR for EV-DO fingers.. 2 – Forward link FCH traffic type.. 10 dB – 1 ... 512 chips 0 .1-1...S0003-A. The position of each finger (in chips) relative to the earliest finger arrived.1. .25 ms = 18. Real Time Clock offset for each finger...125 dB. page 23.. 1 . 511 1 ...125 dB. 12 – – Status of each finger: a combination of “Reference”. The current outer loop estimation Eb/Io setpoint of the forward link FCH in units of 0. 255 dB/8 0 . – – – Frequent AQM elements F-SCH Rate See the description (cellular technology independent) under GSM...125 dB.. 0 .. 12 0 .. and “Assigned”. 5 – Forward link SCH rate.. “Locked”.TEMS Investigation 11... Index of the earliest finger. Version number of device firmware.0: Information Elements and Events IE Name Finger Pilot PN Finger Reference Finger RTC Offset (1/8 chip) Finger Status Firmware Version FPC F-DCCH Setpoint Avg FPC F-FCH Setpoint Avg FPC F-SCH0 Setpoint Avg Frame Offset Range/Unit 0 . 255 dB/8 0 . 15 See Description Arg 1 .... 12 – 1 . The current outer loop estimation Eb/Io setpoint of the forward link DCCH in units of 0..75 ms.. A time skewing of Traffic Channel frames from System Time in integer multiples of 1. The maximum frame offset is 15 × 1.. 12 Description Pilot PN for each finger..25 ms. 232 – 1 chip/8 Text Text 0 . 255 dB/8 0 . 0: 1X 1: 2X 2: 4X 3: 8X 4: 16X 5: 32X 164 .. The current outer loop estimation Eb/Io setpoint of the forward link SCH0 in units of 0. see TR section 2. For the presentation format.. The argument points to a neighbor index. Direction of travel measured in degrees clockwise from north. Electronic Serial Number... Device model. 65535 bits Text 1 .. 360 degrees –90 . Text 1 . 9 Arg – – – Description F-SCH0 channel bit rate configuration. 180 degrees Text – – – Latitude Latitude (Text) Longitude Longitude (Text) Missing Neighbor IEs: General remark Missing Neighbor Cell Name – – – – These elements are obtained when using a scanner in follow phone mode (see UM section 13. Longitude as text. Table 3.4.. For the presentation format.... Reported by positioning equipment.. 90 degrees Text –180 .2.1. State of F-SCH0 channel: “Used”/”Not Used”. Number of bits in an F-SCH0 physical layer frame. LZT 138 0375 R1A 165 . 162600 kbit/s Text 0 . Longitude recorded by positioning equipment.Chapter 3. F-SCH0 Radio Configuration as specified in 3GPP2 TS C.S0003-A. Latitude as text.. see TR section 2. Latitude recorded by positioning equipment.1.3).1.3. F-SCH0 MUX PDU type: see 3GPP2 TS C. – – Text Text 0 .. ESN. Requires cell file... section 2.4. Information Elements IE Name F-SCH0 Bitrate (kbit/s) F-SCH0 Enabled F-SCH0 Frame Length (bits) F-SCH0 MUX PDU F-SCH0 Radio Configuration Hardware Hardware ID Heading (deg) Range/Unit 0 ..S0002-A.1-1. 40 Cell name of each missing neighbor. . 0 dB 0 .. 1199 1 .. 40 Frequency band class for each neighbor set member... where present.. 40 – – – Description Signal-to-noise ratio for each missing neighbor.S0057-B. 40 Channel number of RF channel used by each neighbor set member. PN offset of each missing neighbor. Qualcomm chipset family (e. Same as “Mode (Num)” (which see) but in text format: “No service” etc. 40 1 .System 1 . 1: No service 2: Idle mode 3: Dedicated mode (4: Limited service mode) (5: Scan mode) 6: Packet mode (7: Packet Idle mode) Relevant values: 3: CDMA (1x) 4: 1xEV-DO 5: Analog Mode . 40 Neighbor Set Channel 0 ..System (Text) MSM Revision Neighbor Set IEs: General remark Neighbor Set Band Class Neighbor Set Cell Name Text Text – – Same as “Mode .. Mobile Identity Number of the device. 8 – Mode ..TEMS Investigation 11... 7 Arg 1 . Requires cell file. Cell name for each neighbor set member.g. points to the neighbor set member index... See 3GPP2 TS C. Text 1 .. 166 ... “MSM 6800“)..System” but in text format.. 511 Text Text 1 .. Text 1 .0: Information Elements and Events IE Name Missing Neighbor Ec/Io Missing Neighbor PN Mobile Identity Number Mode Mode (Num) Range/Unit –32 . The argument.. . page 39.. and neighbor sets. 52 Frequency band class for each pilot set member... “Candidate”.. Cell name for each pilot set member.. 1 .. 40 – – Description The number of neighbor set members... 52 1 . 52 1 . 0 dB 0 .. Network Identification (NID). 52 – Type of pilot: “Active”. points to the pilot set member index. Signal-to-noise ratio (Ec/Io in dB) for each neighbor set member. 40 –157 . Pilot PN offset for each neighbor set member. The argument.. 52 1 .S0057-B. Same as Network ID but in hexadecimal format.. Information Elements IE Name Neighbor Set Count Neighbor Set Ec Neighbor Set Ec/Io Neighbor Set PN Network ID Network ID (Hex) Number Of DSC Channels PESQ elements Pilot PN Increment Pilot Set IEs: General remark Pilot Set Band Class Pilot Set Cell Name Pilot Set Cell Type Pilot Set Channel Pilot Set Count Range/Unit 0 . 40 1 . Total number of pilots in active....... where present.. or “Neighbor”... Text Text 1 . Received signal code power for each neighbor set member. “FFFF” 0 . LZT 138 0375 R1A 167 .... 65535 Text: “0000” . 40 1 . 10 dBm –32 ... candidate. Requires cell file. Number of DSC (Data Source Control) Channels currently in use. – See the description (cellular technology independent) under GSM.. See 3GPP2 TS C. 15 Arg – 1 ... Text 0 . Channel number of RF channel used by each pilot.Chapter 3.. 15 – Inter-sector pilot PN increment used by the AN in assigning PN offsets to sectors... 1199 0 . 511 0 ... Argument: Rank on polluter top list...0: Information Elements and Events IE Name Pilot Set Ec Pilot Set Ec/Io Pilot Set PN “Polluters” IEs: General remark Range/Unit –157 . Polluters Top List Channel 0 .. 5 Cell name of each polluter on the top list.... “Top List” refers to cumulative polluter statistics amassed since start of logfile/since device connect. Argument: Rank of this polluter among current polluters.. • • “Current” refers to the polluter data derived from the latest scan report... Argument: Rank of this polluter among current polluters. Text 1 . 5 RF channel number of each polluter on the top list.. 1199 1 . Requires cell file. Requires cell file. –32 . Argument: Rank on polluter top list. 52 1 . Argument: Active set member index. 0 .... 52 Description Received signal code power for each pilot set member.. PN offset for each pilot set member.TEMS Investigation 11.. 511 1 . Argument: Rank of this polluter among current polluters. 10 dBm –32 .3.. 0 dB 1 . Polluters Current Active Set Polluters Current Cell Name Polluters Current Ec/Io Polluters Current Pilot PN Polluters Top List Cell Name 0 ... 511 Arg 1 .. 0 dB 0 ...... Signal-to-noise ratio for each pilot set member.... section 13. 52 1 . 5 Cell name of each current polluter. These elements are obtained when using a scanner in follow phone mode: see UM. Text 1 . 5 Signal-to-noise ratio for each current polluter.. 6 PN offset of each current active set member. 511 1 .... 5 PN offset of each current polluter. 168 .. 1. 5 Description PN offset of each polluter on the top list. Table 3.Mobile (Num)” but in text format.. Reverse link DCCH MUX PDU type: see 3GPP2 TS C. Argument: Rank on polluter top list.. 7 – Text – Same as “Protocol Revision .1-1...3. Text – Same as “Protocol Revision ... Protocol revision (P-Rev) negotiated between phone and base station. State of reverse link DCCH: “Used”/ ”Not Used”. Reverse link DCCH bit rate configuration..Chapter 3.1.2. 7 – Text – 0 .. 65535 bits Text – – – – 1 . Protocol Revision Base (Num) Protocol Revision Base (Text) Protocol Revision Mobile (Num) Protocol Revision Mobile (Text) Protocol Revision In Use (Num) Protocol Revision In Use (Text) R-DCCH Bitrate (kbit/s) R-DCCH Enabled R-DCCH Frame Length (bits) R-DCCH MUX PDU R-DCCH Radio Configuration 0 . 0 ... Reverse link DCCH Radio Configuration as specified in 3GPP2 TS C. Information Elements IE Name Polluters Top List Pilot PN Range/Unit 0 .. section 2.Base (Num)” but in text format.1..S0002-A. Same as “Protocol Revision In Use (Num)” but in text format. 511 Arg 1 . 9 – LZT 138 0375 R1A 169 .. Number of bits in a reverse link DCCH physical layer frame.... Phone protocol revision (P-Rev). 0 . 162600 kbit/s Text 0 . 7 – Base station protocol revision (P-Rev).S0003-A. 0: Information Elements and Events IE Name RF Mode Range/Unit Text Arg – Description For Analog and CDMA: “<technology> <phone state>”. “Idle”. Access 7: CDMA. Inactive 9: EV-DO. Init 1: Analog. Table 3.S0003-A.1. RF Mode (Num) 0 . Init 5: CDMA. Traffic 4: CDMA. Traffic 8: EV-DO.1-1. Acquisition 10: EV-DO..2.TEMS Investigation 11. “Acquisition”. 13 – RF Mode mapped to an integer. 9 – – – – Reverse link FCH bit rate configuration. Idle 2: Analog.. Access 3: Analog. Number of bits in a reverse link FCH physical layer frame.. 170 . 162600 kbit/s 0 . Idle 6: CDMA.. where • • <technology> = “1xEV-DO”. “Traffic”. Reverse link FCH MUX PDU type: see 3GPP2 TS C. “Access”...1. Idle 12: EV-DO. Sync 11: EV-DO. “Access”. where • • <technology> is one of “Analog” and “CDMA”. “Idle”. 65535 bits Text 1 .S0002-A. and <AT state> is one of “Inactive”.3. “Connected”. For EV-DO: “<technology> <AT state>”. Connected R-FCH Bitrate (kbit/s) R-FCH Frame Length (bits) R-FCH MUX PDU R-FCH Radio Configuration 0 . section 2... and <phone state> is one of “Init”. Reverse link FCH Radio Configuration as specified in 3GPP2 TS C. 0: Analog. “Sync”. Access 13: EV-DO.1. Chapter 3. Information Elements IE Name R-FCH Rate Range/Unit 0 ... 15 Arg – Description Reverse link FCH rate bitmask. A combination of: 0x01 (Full Rate allowed), 0x02 (1/2 Rate allowed), 0x04 (1/4 Rate allowed), and 0x08 (1/8 Rate allowed) R-FCH Traffic Type (Num) 0 ... 2 – Reverse link FCH traffic type; one of: 0: No reverse traffic 1: Primary traffic 2: Secondary traffic R-FCH Traffic Type (Text) RLP DL Avg. Throughput (kbit/s) RLP DL Throughput (kbit/s) RLP Erasure Rate (%) RLP Retransmitted Frames Rx (%) RLP Retransmitted Frames Tx (%) Text 0 ... 4000 kbit/s 0 ... 4000 kbit/s 0 ... 100 % 0 ... 100 % 0 ... 100 % – – Same as R-FCH Traffic Type (Num) but in text format. Averaged throughput on downlink at RLP level (16 s sliding window). Valid for both 1x and EV-DO. Instantaneous throughput on downlink at RLP level. Valid for both 1x and EVDO. Erasure rate at RLP level. Retransmitted frames on downlink at RLP level. Retransmitted frames on uplink at RLP level. – – – – LZT 138 0375 R1A 171 TEMS Investigation 11.0: Information Elements and Events IE Name RLP Rx Channel Rate (kbit/s) Range/Unit 0 ... 162600 kbit/s Arg 0 ... 12 Description RLP downlink physical channel bit rate configuration. Argument: 0: FCH 1: DCCH 2: SCH0 3: SCH1 4: SCCH0 5: SCCH1 6: SCCH2 7: SCCH3 8: SCCH4 9: SCCH5 10: SCCH6 11: SCCH7 12: PDCH RLP Total Bytes Rx RLP Total Bytes Tx RLP Tx Channel Rate (kbit/s) 0 ... 231 bytes 0 ... 231 bytes 0 ... 162600 kbit/s – – 0 ... 12 Total bytes transferred on downlink at RLP level. Total bytes transferred on uplink at RLP level. RLP uplink physical channel bit rate configuration. Argument: See RLP Rx Channel Rate (kbit/s). RLP UL Avg. Throughput (kbit/s) RLP UL Throughput (kbit/s) R-SCH Rate 0 ... 2000 kbit/s 0 ... 2000 kbit/s 0 ... 5 – Averaged throughput on uplink at RLP level (16 s sliding window). Valid for both 1x and EV-DO. Instantaneous throughput on uplink at RLP level. Valid for both 1x and EVDO. Reverse link SCH rate. 0: 1X 1: 2X 2: 4X 3: 8X 4: 16X 5: 32X – – 172 Chapter 3. Information Elements IE Name R-SCH0 Bitrate (kbit/s) R-SCH0 Enabled R-SCH0 Frame Length (bits) R-SCH0 MUX PDU R-SCH0 Radio Configuration Rx Power “Scanned 1st Freq.” elements Scanned 1st Freq. Band Scanned 1st Freq. Cell Name Scanned 1st Freq. Channel Scanned 1st Freq. Delay Scanned 1st Freq. Delay Spread Scanned 1st Freq. Ec Range/Unit 0 ... 162600 kbit/s Text 0 ... 65535 bits Text Arg – – – Description Reverse link SCH0 bit rate configuration. State of reverse link SCH0: “Used”/”Not Used”. Number of bits in a reverse link SCH0 physical layer frame. Reverse link SCH0 MUX PDU type: see 3GPP2 TS C.S0003-A, section 2.2.1.1. Reverse link SCH0 Radio Configuration as specified in 3GPP2 TS C.S0002-A, Table 3.1.3.1-1. Received signal power. Valid for both 1x and EV-DO. – 1 ... 9 – –120 ... 10 dBm – Pilot scanning: First scanned RF channel. Argument: The sorting order within each element depends on the setting in the General window: see UM section 13.3.4.1. Text Text – 1 ... 512 Band class for scanned RF channel. See 3GPP2 TS C.S0057-B. Cell names corresponding to each scanned pilot. Requires cell file. 0 ... 1199 –3 ... 60 chips 0 ... 63 chips –157 ... –10 dBm – 1 ... 512 1 ... 512 Channel number of scanned RF channel. Pilot delay in chips for each scanned pilot. See UM section 13.3.1. Delay spread in chips for each scanned pilot. See UM section 13.3.1. Received signal code power of each scanned pilot. 1 ... 512 LZT 138 0375 R1A 173 TEMS Investigation 11.0: Information Elements and Events IE Name Scanned 1st Freq. Ec/Io Scanned 1st Freq. Io Scanned 1st Freq. Pilot PN Scanned 1st Freq. Pilots Count “Scanned 1st Freq. Strongest” elements “Scanned 2nd (etc.) Freq.” elements “Scanned 2nd (etc.) Freq. Strongest” elements Scanned Channel Range/Unit –32 ... 0 dB –125 ... –25 dBm 0 ... 511 0 ... 512 Arg 1 ... 512 – 1 ... 512 – Description Peak Ec/Io for each scanned pilot. Total signal power in RF channel. PN offset for each scanned pilot. Number of pilots scanned. Pilot scanning: First scanned RF channel. The strongest pilots are sorted by descending peak Ec/Io. Argument (1 ... 32): 1 means the pilot with highest peak Ec/Io, etc. Pilot scanning: Second (etc.) scanned RF channel. Argument: The sorting order within each element depends on the setting in the General window: see UM section 13.3.4.1. Pilot scanning: Second (etc.) scanned RF channel. The strongest pilots are sorted by descending peak Ec/Io. Argument (1 ... 32): 1 means the pilot with highest peak Ec/Io, etc. 0 ... 1199 1 ... 512 RSSI scanning: RF channel number of each RF channel scanned. Argument: 1 means the RF channel with the lowest number, etc. Scanned Channels Count Scanned RSSI 0 ... 512 – RSSI scanning: The number of RF channels scanned. RSSI scanning: RSSI for each RF channel. Argument: 1 means the RF channel with the lowest number, etc. –120 ... –30 dBm 1 ... 512 Scanned RSSI Average (dBm) –120 ... –30 dBm – RSSI scanning: Average RSSI over all scanned RF channels. 174 Chapter 3. Information Elements IE Name “Scanned Strongest” elements Range/Unit Arg Description These elements contain the strongest pilots irrespective of scanned RF channel. The pilots are sorted by descending peak Ec/Io. Argument (1 ... 32): 1 means the pilot with the highest peak Ec/Io, etc. Searcher State Text – Searcher state, e.g. “Acquisition”, “TCH operation”. Valid for both 1x and EVDO. Size of search window used for pilots in the active set. For the mapping to PN chip length see IS-95, Table 6.6.6.2.11. Size of search window used for pilots in the neighbor set. Size of search window used for pilots in the remaining set (see 3GPP2 TS C.S0005-A, page 1-18). Hex string containing the 128-bit sector address of the serving sector. Format: “0011:2233:4455:6677:8899:AABB:CC DD:EEFF” Radio Link Protocol service ID. Service Option for the current session. See 3GPP2 TS C.R1001. Same as Service Option (Num) but in text format. Slot cycle index described in 3GPP2 TS C.S0005-A, section 2.6.2.1.1.3. Soft handoff state. One of “No Soft Handoff”, “2-Way”, “3-Way”, “4-Way”, “5-Way”, “6-Way”. Derived from the information element Active Set Count. Searcher Window A 0 ... 15 See Description 0 ... 15 0 ... 15 – Searcher Window N Searcher Window R Sector ID – – Text – Service ID Service Option (Num) Service Option (Text) Slot Cycle Index Soft Handoff State 0 ... 254 0 ... 65535 Text 0 ... 7 Text – – – – – LZT 138 0375 R1A 175 . where present.0: Information Elements and Events IE Name “Spectr Ana” IEs: General remark Range/Unit Arg Description These elements are populated by spectrum analysis scanning..3.. 160 mph 1 .. 5 MOS Text 0 ... System Identification (SID) in decimal format...TEMS Investigation 11. 800 ms 1 ... 870 .S0005-A.. Speed in mph. 250 km/h 0 .3. 65535 Text (“0000” . –20 dBm 0 .... See UM chapter 29.. 2560 – Speed (km/h) Speed (mph) SQI MOS Station Class Mark (hex) Subnet Mask System ID System ID (Hex) 0 . Spectrum analysis: The number of downlink frequencies swept by the scan. The argument. section 2. 2560 1 . This element only appears in merged logfiles (see UM section 36. “FFFF”) – – – – – – – Speed in km/h... Sector subnet identifier.. SQI expressed on the MOS scale. 176 . is simply a sequence number pointing to scanned frequencies as indicated by the “Spectr Ana Sc DL Freq” element... 900 MHz 0 . System Identification (SID) in hexadecimal format.. Spectr Ana Sc DL Freq Spectr Ana Sc DL No Of Freq Spectr Ana Sc DL RSSI Speech Path Delay –130 .2). 2560 – Spectrum analysis: Scanned downlink frequencies in ascending order.. Spectrum analysis: RSSI of downlink frequencies scanned... 255 0 . AQM: The length of time it takes for the speech to travel from the Call Generator to the MTU and back to the Call Generator again. Defined in 3GPP2 TS C. .. 36 dBm –127 . See 3GPP2 TS C. section 2.2. See 3GPP2 TS C.6..0. section 2.2. Equal to Closed Loop Adjust parameter when in EV-DO mode... See 3GPP2 TS C. 0 See Description – T-Drop (Num) – T-TDrop (Num) 0 .5 dB). See 3GPP2 TS C.S0005-A.6...2. LZT 138 0375 R1A 177 .2. Active set versus candidate set comparison threshold (expressed in units of 0..3-1. Table 2.S0005-A v6. 0 See Description Arg – Description Pilot detection threshold (sign reversed).3-1. Active set versus candidate set comparison threshold. Valid for both 1x and EV-DO.2.6.6.2.0. section 2. “319 s”) –128 .6. – Tx Pilot Power parameter.. Pilot drop threshold (sign reversed).3. See 3GPP2 TS C..6.5 dB and sign reversed).6.. 36 dBm – Tx Open Loop Power parameter.2. section 1.S0005-A... 0 dB –63 ... Tx Open Loop Power Tx Pilot Power –127 . 8 dB 0 . T-TDrop (sec) Text (“0. Drop timer value in seconds.6. mapped to an integer value according to 3GPP2 TS C. Pilot drop threshold (expressed in units of 0.S0005-A. T-Add (Num) – T-Comp (dB) 0 .6.1.. Valid for both 1x and EV-DO..S0005-A v6.5..6.Chapter 3. Information Elements IE Name T-Add (dB) Range/Unit –32 .1 s”. 0 dB –63 .. Pilot detection threshold (expressed in units of 0. 15 See Description – T-Comp (Num) – T-Drop (dB) –32 .2.5 dB and sign reversed).2. Table 2. 15 See Description – Drop timer value.. 127 dB – Tx Adjust – Tx Adjust power control parameter..6..S0005-A. Valid for both 1x and EV-DO. –10 dBm 0 . 36 dBm Arg – Description Tx Power parameter. IE Name RSSI SQE 178 . 100 dB Arg – – Description Received Signal Strength Indicator..TEMS Investigation 11.6... Valid for both 1x and EV-DO.. Speech Quality Estimate.0: Information Elements and Events IE Name Tx Power Range/Unit –127 .. 3.. iDEN Information Elements Range/Unit –128 . 4.. “Number of Samples for Stats”).. Note that as power level fluctuations become minute. Reported by positioning equipment.. Reported by positioning equipment. 8848 m Text Text Text 0 . Scanner model... 360 degrees –90 .Chapter 3. Direction of travel measured in degrees clockwise from north.. Hardware identification string.1. Information Element Table IE Name Altitude (ft) Range/Unit –1312 . Information Elements 3. – Height above sea level in meters.3. WiMAX Information Elements Notes on CINR The number of samples on which to base the CINR mean values and standard deviations is set in the WiMAX scan setup dialog (UM section 14. Reported by positioning equipment. 29028 ft –400 . This number is reported in the “Samples Taken” elements (see below). For the presentation format. Latitude as text. this figure only serves as a guideline to the scanner. – – – – Version number of device firmware. Altitude (m) Firmware Version Hardware Hardware ID Heading (deg) Latitude Latitude (Text) – – LZT 138 0375 R1A 179 .7.. Latitude recorded by positioning equipment. the standard deviation likewise approaches zero and hence tends towards negative infinity when expressed in dB. 90 degrees Text Arg – Description Height above sea level in feet.. see TR section 2. in practice the scanner may on some occasions use a lower number of samples as input to the statistics calculation. A large negative number has been used as the lower endpoint for the standard deviation range. However. .TEMS Investigation 11.. gated during the preamble symbol time. These elements are obtained from preamble scanning.System (Text) “Sc Channel” IEs: General remark Sc Channel [indx] Sc Channel Count Sc Channel Profile (Text) [indx] Sc Channel RSSI (dBm) [indx] Range/Unit –180 .. 32 0 . 0 . 180 . points to the position of the channel in the list of scanned channels. 8 Text Arg – – – – – – Description Longitude recorded by positioning equipment.. 1499 Number of samples used to calculate RSSI statistics (mean. 180 degrees Text Text 1 .System Mode . 1499 RF channel number of each channel scanned...0: Information Elements and Events IE Name Longitude Longitude (Text) Mode Mode (Num) Mode .. Longitude as text. where present.. The number of channels scanned.. The total power in all the allowed preamble subcarriers of the WiMAX signal. 1500 Text –140 . 1580 0 . 1499 0 .4. Table 130... 20 dBm Sc Channel RSSI Mean (dBm) [indx] Sc Channel RSSI Samples Taken [indx] –140 .. 0 . see TR section 2.. Not used... 1499 0 .. 7 1 . For the presentation format... See WiMAX Forum Mobile System Profile version 1. 20 dBm 0 . Not used.... Running mean value of channel RSSI.4. The argument. Not used. 1499 – 0 ..... Not used. standard deviation).. The WiMAX RF profile to which each scanned channel belongs. This is the sum of all three segment powers. . 0 . 20 dBm Arg 0 .. 20 dBm 0 . where present... 1499 –140 . gated during the preamble symbol time...... gated during the preamble symbol time.. 99 For each preamble detected. –140 . (dB) [indx] Sc Channel Segment 0 Power (dBm) [indx] Sc Channel Segment 1 Power (dBm) [indx] Sc Channel Segment 2 Power (dBm) [indx] “Sc Preamble” IEs: General remark Sc Preamble Center Frequency Offset (Hz) [indx] Sc Preamble Cha-PI (Text) [indx] Sc Preamble Channel [indx] Sc Preamble CINR (dB) [indx] Sc Preamble CINR Mean (dB) [indx] Range/Unit –200 ..... –10000 . 1580 –37 ... Channel number for each preamble detected.. Running mean value of carrier to interference-plus-noise ratio (CINR) for each preamble detected. 20 dB –140 . 1499 These elements are obtained from preamble scanning. 99 0 . Information Elements IE Name Sc Channel RSSI Std. 99 LZT 138 0375 R1A 181 . a text string containing RF channel number and preamble index.. 1499 Description Running standard deviation for channel RSSI... The total power in the preamble subcarriers allocated to segment 0.. 10000 Hz 0 . indicates the position of the preamble in the list of detected preambles.. Dev.Chapter 3.. gated during the preamble symbol time.. 60 dB 0 .. 99 0 .. Carrier to interference-plus-noise ratio (CINR) for each preamble detected. The argument.. Text 0 .. 99 The center frequency offset of the channel on which each preamble was detected. 1499 0 ...... The total power in the preamble subcarriers allocated to segment 1. The total power in the preamble subcarriers allocated to segment 2.. 60 dB –37 . 20 dBm 0 . . where present. 113 0 ... points to the position of the channel in the list of scanned channels.1.. section 8. standard deviation).4.... 60 dB 0 .. Text 0 . –100 . 182 . Dev. 99 Description Number of samples used to calculate CINR statistics (mean. 32 Arg 0 ..TEMS Investigation 11.... Index of each detected preamble as defined in the tables in IEEE 802. 20 dBm Text 0 . Sector ID for each detected preamble..... 20 dBm Text 0 . –140 . Running standard deviation of carrier to interference-plus-noise ratio (CINR) for each preamble detected. The number of preambles detected.. 100 0 ... RSSI of each detected preamble...16e.. 99 0 .. 99 0 .. 99 These elements are obtained from RSSI scanning.. The argument...6...0: Information Elements and Events IE Name Sc Preamble CINR Samples Taken [indx] Sc Preamble CINR Std. 1499 – RSSI for each scanned channel. Segment index for each detected preamble. 2 0 . 99 –140 . (dB) [indx] Sc Preamble Count Sc Preamble Index [indx] Sc Preamble Operator ID [indx] Sc Preamble Power (dBm) [indx] Sc Preamble Profile (Text) [indx] Sc Preamble Sector ID [indx] Sc Preamble Segment Index [indx] “Sc RSSI” IEs: General remark Sc RSSI (dBm) Sc RSSI Bandwidth (kHz) Range/Unit 0 .. 99 – 0 ..1. 99 The WiMAX RF profile to which each detected preamble belongs. 99 Text 0 . Operator ID for each detected preamble.. The bandwidth scanned around the center frequency of each channel. 1 .. 1 .... Argument: 1 = channel with highest RSSI. gated during the preamble symbol time. 20 dBm 1 ... 32 1 .. Dev. 1499 – 0 . 20 dBm –140 . 0 . 1580 Arg 0 . 1 ... Preamble scanning... 20 dB –140 .. Table 130... Running standard deviation of channel RSSI. WiMAX RF Profile. 1499 Description Channel number of each channel scanned. 32 Channel RSSI. 20 dBm –200 . etc... 1499 0 . 20 dBm –140 .. standard deviation)....... 32 RF channel number..... Frequency of each scanned channel.. Information element components sorted by decreasing channel RSSI.. 32 1 .. 32 LZT 138 0375 R1A 183 . (dB) Sc Strongest Channel Segment 0 Power (dBm) Range/Unit 0 . See WiMAX Forum Mobile System Profile version 1..Chapter 3.. –140 .4.... 32 Number of samples used to calculate channel RSSI statistics (mean.. Information Elements IE Name Sc RSSI Channel Sc RSSI Channel Count Sc RSSI Frequency (MHz) Sc RSSI Profile (Text) “Sc Strongest Channel” IEs: General remark Sc Strongest Channel Sc Strongest Channel Profile (Text) Sc Strongest Channel RSSI (dBm) Sc Strongest Channel RSSI Mean (dBm) Sc Strongest Channel RSSI Samples Taken Sc Strongest Channel RSSI Std. 0 . The number of channels scanned.. 1580 Text 1 . 6000 MHz Text The WiMAX RF Profile to which each scanned channel belongs. 1500 0 . The total power in the preamble subcarriers allocated to segment 0. 32 Running mean value of channel RSSI.. RSSI scanning. 20 dBm 1 . 6000 MHz 1 . 32 Text string containing RF channel number and preamble index.... 1580 0 .. etc... The total power in the preamble subcarriers allocated to segment 2. Argument: 1 = channel with highest RSSI. 32 –37 . 32 1 . Argument: 1 = preamble with highest CINR. 32 1 . 20 dBm Arg 1 . Frequency of each RSSI scanned channel... 113 1 . –140 . 60 dB 0 .. Text 1 ..0: Information Elements and Events IE Name Sc Strongest Channel Segment 1 Power (dBm) Sc Strongest Channel Segment 2 Power (dBm) “Sc Strongest (CINR)” IEs: General remark Sc Strongest (CINR) Cha-PI (Text) Sc Strongest (CINR) Channel Sc Strongest (CINR) CINR Sc Strongest (CINR) Preamble Index “Sc Strongest RSSI” IEs: General remark Sc Strongest RSSI (dBm) Sc Strongest RSSI Channel Sc Strongest RSSI Frequency (MHz) Range/Unit –140 .TEMS Investigation 11... gated during the preamble symbol time. 32 CINR. etc. 32 RSSI of each channel included in RSSI scan. RF channel number of each RSSI scanned channel. 32 Preamble scanning.. –140 .. 32 1 . Information element components sorted by decreasing RSSI.... gated during the preamble symbol time..... 184 .... Preamble index.. 32 Description The total power in the preamble subcarriers allocated to segment 1... 1580 1 ...... RF channel number.. Information element components sorted by decreasing preamble CINR. 0 . 20 dBm 0 .. ... 60 dB 0 ... The argument. 3001 –140 ... 32 CINR... 0 .. 1580 1 . Information Elements IE Name Sc Strongest RSSI Profile (Text) “Sc Strongest (Preamble Power)” IEs: General remark Sc Strongest (Preamble Power) Cha-PI (Text) Sc Strongest (Preamble Power) Channel Sc Strongest (Preamble Power) CINR Sc Strongest (Preamble Power) Preamble Index “Spectr Ana” IEs: General remark Range/Unit Text Arg 1 . 6 · 106 MHz 0 . Text 1 . 113 1 .. RSSI of downlink frequencies scanned. 20 dBm 1 . These elements are populated by spectrum analysis scanning. 32 Text string containing RF channel number and preamble index. Preamble scanning.Chapter 3. Argument: 1 = preamble with highest RSSI.. 3001 Scanned frequencies on downlink in ascending order. The number of downlink frequencies swept by the scan. where present. –37 .. 32 Preamble index. etc. 32 RF channel number.... Information element components sorted by decreasing preamble RSSI. 32 Description RF Profile to which each RSSI scanned channel belongs... 0 .. Spectr Ana Sc DL Freq (MHz) Spectr Ana Sc DL No Of Freq Spectr Ana Sc DL RSSI (dBm) LZT 138 0375 R1A 185 . 1 ....... 3001 – 1 . is simply a sequence number pointing to scanned frequencies as indicated by the “Spectr Ana Sc DL Freq (MHz)” element.. .. Current time in ms. 250 km/h 0 . 86400000 ms – 186 .TEMS Investigation 11.mm..0: Information Elements and Events IE Name Speed (km/h) Speed (mph) Time Range/Unit 0 . where mm = decimal seconds. Current time in text format: HH:MM:SS. Speed in mph... Time (ms) 0 .. 160 mph Text Arg – – – Description Speed in km/h. RLP.. Data Service Testing Information Elements This section lists the information elements in the “Data” category. 80000 kbit/s – – – LZT 138 0375 R1A 187 .. Information Elements 3.). including login information. • The “Data” information elements are mostly independent of the bearer service used (packet-switched or circuit-switched). In the PC. Bytes Sent App. The “Data” category contains two kinds of elements: • Application-level data service measurements. Information Element Table IE Name App.Chapter 3.12. Current throughput for data sent at the application level (current uplink throughput).8..1. They are defined in UM section 15. Bytes Received Range/Unit 0 . those obtained when performing data service testing. Statistics on the dial-up connection obtained from Microsoft’s Remote Access Service (RAS).. these are taken in the Winsock interface. 2 · 109 bytes 0 . Throughput UL (kbit/s) 0 . Number of bytes sent at the application level since dial-up. Note the meaning of the terms connection and session which are used in the explanations below. LLC. 80000 kbit/s 0 .. Current throughput for data received at the application level (current downlink throughput). i. etc.. 2 · 109 bytes Arg – Description Number of bytes received at the application level since dial-up. Application-level measurements reflect the performance experienced directly by the user.e.11).. Throughput DL (kbit/s) App. A number of elements are however bearer-specific. as opposed to the performance at lower levels in the protocol hierarchy (RLC.e. Login information is included in this byte count. i. Remember that not all data services are run over a dial-up connection (see UM section 15. Dial-up Networking. App.1.. . i.. – – 0 . However. 2 · 109 bytes 0 . 2 · 109 bytes 0 ... Valid only during Ping sessions. Given in hours. Downlink throughput on the current data connection.. Data Connection Type IP Address “NDIS/RAS” IEs: General remark NDIS/RAS Bytes Received NDIS/RAS Bytes Sent NDIS/RAS Current Throughput DL (kbit/s) NDIS/RAS Current Throughput UL (kbit/s) Packets Received Per Second Packets Sent Per Second Ping Delay (ms) Text – Text – IP address assigned to the RAS client. and seconds.0: Information Elements and Events IE Name Connection Duration Range/Unit Text hh:mm:ss Arg – Description Time since dial-up.. 0 .. 2 · 109 – Number of packets received per second. Number of bytes sent over the current data connection. these elements are currently not updated for NDIS. Number of packets sent per second.. 30000 ms – – 188 .. in Windows 7 and Windows Vista.TEMS Investigation 11. how long the currently established data service connection has been up.. 2 · 109 0 . 80000 kbit/s – Number of bytes received over the current data connection... Type of data connection: NDIS or RAS. 0 .. Round-trip time for an individual Ping Response during the current Ping session.e. 0 . minutes. 80000 kbit/s – Uplink throughput on the current data connection. These elements are valid for a RAS connection as well as an NDIS connection.. .. 2000 – 0 . 2000 – – – Number of alignment errors on the current dial-up connection... 2 · 109 0 . 0 . 2 · 109 0 .. Compression ratio for the data being sent on the current dial-up connection. Bytes Received These elements are valid only if the device uses a RAS dial-up connection. 2000 bytes Arg – Description Size in bytes of the packet sent with the Ping command. Number of timeout errors on the current dial-up connection.. Number of hardware overrun errors on the current dial-up connection..Chapter 3.. 2 · 109 0 ... “RAS” IEs: General remark RAS Alignment Errors RAS Buffer Overrun Errors RAS Compression Ratio In RAS Compression Ratio Out RAS CRC Errors RAS Frames Received RAS Frames Sent RAS Framing Errors RAS Hardware Overrun Errors RAS Timeout Errors Session App. 2 · 109 bytes – – – – – – LZT 138 0375 R1A 189 .. 2 · 109 – 0 ... Number of frames received over the current dial-up connection. Number of bytes received at the application level during the current session. Number of frames sent over the current dial-up connection. Number of framing errors on the current dial-up connection. 2 · 109 0 ... 0 .. Number of buffer overrun errors on the current dial-up connection... Number of cyclic redundancy check (CRC) errors on the current dial-up connection. 2 · 109 0 .. Valid only during Ping sessions. 2 · 109 0 .. Information Elements IE Name Ping Size (bytes) Range/Unit 0 ... 2 · 109 0 ... Compression ratio for the data being received on the current dial-up connection. TEMS Investigation 11. Time for which the current session has been ongoing..) Same as App.. 5 MOS – 190 . 100 % 0 . 80000 kbit/s – – Session Current Throughput UL (kbit/s) 0 . 80000 kbit/s – Session Duration Session Information VSQI Intermediate Score Text hh:mm:ss Text – – 1 . minutes.. Mean Throughput UL (kbit/s) Session Current Packet Loss (%) Session Current Throughput DL (kbit/s) Range/Unit 0 . This element is more suitable to use for statistics. for data sent at the application level (mean uplink throughput).. calculated over the whole of the current session. calculated over the whole of the current session... 80000 kbit/s – 0 . 0 . Mean Throughput DL (kbit/s) Session App. Throughput UL (kbit/s) except that this element is valid only while a data transfer session is in progress. since it will not contain any zeroes from periods of inactivity. Average of the latest 30 VSQI Realtime Scores (which see). Same as App. Throughput DL (kbit/s) except that this element is valid only while a data transfer session is in progress. Bytes Sent Session App.. e. This element is more suitable to use for statistics.txt”.. and seconds. for data received at the application level (mean downlink throughput). Given in hours.com/temp/my_file. since it will not contain any zeroes from periods of inactivity. (Useful when testing video streaming. Mean throughput. Mean throughput. Current packet loss level in percent.. Description of the current session in plain text...g.my_server.. 2 · 109 bytes 0 ... 80000 kbit/s Arg – – Description Number of bytes sent at the application level during the current session.0: Information Elements and Events IE Name Session App. “FTP DL: www. No uplink information elements are valid when running GPRS/EGPRS. which appears in the Session End report). unlike the overall VSQI score for an entire session. Cell Identity of neighbor cell.. 6 LZT 138 0375 R1A 191 . Argument: Indicates neighbor ranking: 1 gives the neighbor with the highest rank.Chapter 3. 65535 – – 1 . and so they have been omitted here. Information Element Table IE Name BCCH Allocation Used DTX DL Used DTX UL Used Neighbor CI Range/Unit Text Arg – Description BCCH Allocation (BS) list currently used by the phone. All such elements have precisely the same ranges and meanings as the corresponding elements in section 3.. The GSM Uplink category includes further elements besides those listed. Uplink (MTR) Information Elements This section lists the information elements in the “GSM Uplink” category. Use of DTX on downlink.. 3. Information Elements IE Name VSQI Realtime Score Range/Unit 1 . Text: “YES” or “NO” Text: “YES” or “NO” 0 .1... i. No uplink data can be recorded in MTR files when running a data service. those originating from MTR files. Use of DTX on uplink.e..9. 5 MOS Arg – Description Video Streaming Quality Index (realtime score which is regularly updated during the streaming session. including RxLev and RxQual (Full and Sub) for both uplink and downlink. See UM chapter 32. etc. see 3GPP 45. Power Level MS Power Level MS (dBm) 0 . If a ranking value of a neighbor becomes positive. Valid only in dedicated mode.. see 3GPP 45.1)..005. Base station transmit power. Argument: Indicates neighbor ranking: 1 gives the neighbor with the highest rank. section 4.. Argument: Indicates neighbor ranking: 1 gives the neighbor with the highest rank. 31 See Description – – – – Pathloss. Regarding the value range..1.TEMS Investigation 11.1. 190 dB 0 . Phone transmit power in dBm (compare MS Tx Power (dBm) in section 3. One of • • • • • Undefined K-value L-value High signal cell Low signal cell.0: Information Elements and Events IE Name Neighbor Ranking Type Range/Unit Text Arg 1 . etc.. 15 See Description 0 . Sub value... Valid only in dedicated mode. Neighbor Ranking Value –127 . Valid only in dedicated mode.005. this neighbor probably soon will become the serving cell.1.. Phone transmit power (compare MS Power Control Level in section 3. 31 dBm 192 . 128 1 ...2. Path Loss Full Path Loss Sub Power Level BS 47 . 190 dB 47 ..1).. 6 This value is usually negative. Regarding the value range. Pathloss... A higher value means a higher ranking. section 4. etc.. 6 Description Indicates the algorithm used to compute the ranking value. Full value.. Chapter 3. Extended Timing Advance. 50 dBQ 0 . For the significance of the parameter value.. see 3GPP 45. Valid only in dedicated mode.. Information Elements IE Name SQI TA Actual Range/Unit –40 .010. LZT 138 0375 R1A 193 .. 219 See Description Arg – – Description Uplink Speech Quality Index.. TEMS Investigation 11.0: Information Elements and Events 4. Information Element Support in Phones and Scanners This chapter details which devices support which information elements, for all cellular technologies where this is non-trivial. Elements derived from positioning equipment are not included in the tables. In the Information Elements column, <string>* means all IEs beginning with <string>. A gray checkmark means that the IE support is restricted to a subset of the devices in the column; see the accompanying footnote for details. The tables include certain devices that are no longer connectable in this version of TEMS Investigation; these devices are printed in non-boldface. They are retained here since old logfiles recorded with the devices can still be replayed in the application. There also exist information elements which are unique to one or more of these devices. 4.1. CDMA Information Elements Qualcomm Sc. EV-DO Color Code EV-DO* (others) Missing Neighbor* Polluters* Sector ID Subnet Mask 194 EV-DO Rev A EV-DO Rev 0 CDMA (1x) Information Elements PCTel Scanners Chapter 4. Information Element Support in Phones and Scanners Qualcomm Sc. Scanned* Spectr Ana* Tx Open Loop Power Tx Pilot Power All other IEs 4.2. • • • GSM Information Elements The Sony Ericsson column containing W995* is also valid for TM506 and W760i. Scanning elements supported by the SRU are the same as those supported by the Sony Ericsson W995* phones. The Nokia column containing 6720 is also valid for 6120/6121. Sony Ericsson Motorola Nokia Qualc. Dt Sc Information Elements Adjacent RxLev* Adjacent Scan AMR Active Set* AMR C/I* AMR Codec* AMR Hysteresis LZT 138 0375 R1A W995*, C905*, C702, Z750i K600i, K800i W600i, K790* V800, Z800 S710a T610, T616, T618 Razr V3xx, Razr2 V9 E1000, E1070, Razr V3x A835, A845 6720, 7376, N75/80/95/96 6086, 6125, 6230(i), 6280 6630, 6680 6650, 6651 HSPA, HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners 195 EV-DO Rev A EV-DO Rev 0 CDMA (1x) Information Elements PCTel Scanners TEMS Investigation 11.0: Information Elements and Events Sony Ericsson Motorola Nokia Qualc. Dt Sc Information Elements AMR Threshold ARFCN* Attach Time Band Control BER* BLER/Timeslot BSIC* a C Value C/A* b C/I Absolute, Best, Best: ARFCN, Worst, Worst: ARFCN c C/I* (others) C1 C2 C31 C32 Call Setup Time Caller Ident. Success Calling Phone Number Cell EGPRS Support Cell GPRS Support Cell Id* Cell Name* CGI* Channel* Ciphering Algorithm Coding Scheme DL Coding Scheme UL CS-* DL Usage... 196 W995*, C905*, C702, Z750i K600i, K800i W600i, K790* V800, Z800 S710a T610, T616, T618 Razr V3xx, Razr2 V9 E1000, E1070, Razr V3x A835, A845 6720, 7376, N75/80/95/96 6086, 6125, 6230(i), 6280 6630, 6680 6650, 6651 HSPA, HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners TEMS Automatic logfiles only TEMS Automatic logfiles only TEMS Automatic logfiles only Chapter 4. Information Element Support in Phones and Scanners Sony Ericsson Motorola Nokia Qualc. Dt Sc Information Elements Current CS* Current MCS* Data Mode* Disable Handover d Downlink Sign. Ctr Curr. Downlink Sign. Ctr Max DTX Rate DL EGPRS BEP (*) EGPRS BEP Total (*) EGPRS Link Q. Ctrl UL EGPRS Window Size* FER* Firmware Version Forced* Frequency Band* Frequent AQM* e GA-RC*, GAN*, GANC* f GMM State GRR State Hardware Hardware ID Hopping* HSN Idle Channel Quality Ignore Cell Barred Interference* LAC* LLC BLER DL LLC BLER UL LLC Bytes* LZT 138 0375 R1A W995*, C905*, C702, Z750i K600i, K800i W600i, K790* V800, Z800 S710a T610, T616, T618 Razr V3xx, Razr2 V9 E1000, E1070, Razr V3x A835, A845 6720, 7376, N75/80/95/96 6086, 6125, 6230(i), 6280 6630, 6680 6650, 6651 HSPA, HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners 197 TEMS Investigation 11.0: Information Elements and Events Sony Ericsson Motorola Nokia Qualc. Dt Sc Information Elements LLC Throughput* LLC Window Size* MAC Mode* MAIO MCC MCS-* DL Usage... Message Hex Dump... MNC Mode* Modulation* g MS Behavior Modified MS Power Control Level MS Tx Power Neighbor ARFCN* Neighbor BSIC* Neighbor C1* Neighbor C2* Neighbor C31* Neighbor C32* Neighbor Cell* Neighbor LAC* Neighbor RxLev* Neighbor (SI) ARFCN Network Control Order Network Mode Of Oper. Number Of Hopp. Freq. Number Of Used T’slots* PBCCH Timeslot PDCH Utilization* PDP* 198 W995*, C905*, C702, Z750i K600i, K800i W600i, K790* V800, Z800 S710a T610, T616, T618 Razr V3xx, Razr2 V9 E1000, E1070, Razr V3x A835, A845 6720, 7376, N75/80/95/96 6086, 6125, 6230(i), 6280 6630, 6680 6650, 6651 HSPA, HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners C905*. A845 6720. HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners 199 . Dt Sc Information Elements PESQ* e Preferred GAN Mode f Prevent* Q Search Power h RAC* Radio Link Timeout Curr. Information Element Support in Phones and Scanners Sony Ericsson Motorola Nokia Qualc. E1070. 6280 6630. Z800 S710a T610. K800i W600i. Radio Link Timeout Max RLA_P* RLC BLER* RLC Block* RLC Bytes* RLC Thr’put DL (%) RLC Thr’put DL (kbit/s) RLC Thr’put UL (%) i RLC Thr’put UL (kbit/s) RLP* RxLev* RxQual* Scanned Adjacent* Scanned ARFCN Scanned Band Scanned BSIC Scanned C/A* Scanned C/I Scanned Cell Name Scanned Channels No of Scanned RxLev* Serving Cell List Active Signal Strength* SNDCP BLER* LZT 138 0375 R1A W995*. Razr V3x A835. Razr2 V9 E1000. T616. K790* V800.Chapter 4. 7376. T618 Razr V3xx. 6125. C702. N75/80/95/96 6086. 6651 HSPA. Z750i K600i. 6680 6650. 6230(i). Option must be turned on in phone’s Properties dialog: see UM section 16. C/I Weakest Sc. Regarding BSIC decoding with PCTel scanners. E1070. C905*. Dt Sc Information Elements SNDCP Bytes* SNDCP Throughput DL SNDCP Throughput UL Speech Codec Speech Path Delay e SQI* Strongest Sc.2. For PCTel scanners this requires the C/I measurement option: see UM section 9. C/I Strongest Sc. b.* (others) Sub Channel Number TA Target Handover TD-SCDMA Neighbor* TFI* Time Timeslot Timeslot Channel Type* Timeslot Used* TLLI* Tone Event Training Sequence Code Uplink State Flag WCDMA Neighbor* Weakest Sc. T616. C702. A845 6720. HSPA+ HSDPA WCDMA Datang LC8130E PCTel Scanners TEMS Automatic logfiles only .* (others) a. Razr2 V9 E1000.2. 200 W995*. K790* V800. 6230(i). Z800 S710a T610.4.3. N75/80/95/96 6086. 6280 6630.0: Information Elements and Events Sony Ericsson Motorola Nokia Qualc. 6125.3. Z750i K600i.TEMS Investigation 11. Razr V3x A835. 7376. K800i W600i. c. see UM section 9.4. T618 Razr V3xx.2. 6651 HSPA. 6680 6650. h. Supported by K800i but not by K600i. W995*. K800i.Chapter 4. Supported by C702. i. Also note that what AQM elements are obtained depends on what hardware is used at the other end: Call Generator with analog calling card. e. Information Element Support in Phones and Scanners d. Call Generator with digital calling card. Supported by K790* but not by W600i. f. For full details. Supported by K790*. LZT 138 0375 R1A 201 . C905*. Supported by K790* and K800i but not by W600i and K600i. or an MRU. and W995*. consult the document “AQM in TEMS Products (Including PESQ)”. and Z750i. Supported by Nokia 6086 only. g. W760i. 0: Information Elements and Events 4.. N80 . 6650. presented in DC only 202 6680. 7376. A845 Nokia Qualcomm Scan. N95. Razr V3x A835. Razr2 V9 E1000.TEMS Investigation 11. W760i K800i K600i V800...* AS* Averaged BER BLER Target Control* Call Event Success Rate Call Setup Time Caller Ident. Det Neigh Pathloss Det Neigh* (others) DPCCH ISCP DL DPCCH Power UL DPCCH RSCP DL DTX Rate DL DVB-H* Finger 1st* Finger 2nd*. RSCP Sum/Ant. 6121.* Det Neigh CPICH Tx P. E1070.. 6630. 12th* TEMS Automatic logfiles only TEMS Automatic logfiles only TEMS Automatic logfiles only TCC protocol terminals only b TCC protocol terminals only b LG U960 only. EX Rohde & Schwarz 6720 6120. Z800 Razr V3xx. Information Elements AMR* a AS . 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. • • WCDMA Information Elements The Sony Ericsson column containing Z750i is also valid for TM506. Success Calling Phone Number Cell Barred Control* Compressed Mode CW* Det Neigh * Sum/Ant. N96 6280.3. C905*/C702. 3rd*. Scanning elements supported by the SRU are the same as those supported by the Sony Ericsson W995* phones. 4th* Finger 5th* . Sony Ericsson Motorola W995* Z750i. N95. N96 6280. EX Rohde & Schwarz 203 6720 6120. LZT 138 0375 R1A 6680. Razr2 V9 E1000. HS UL E-TFC* HS UL Happy Rate HS UL HICH* HS UL New Trans. Z800 Razr V3xx. 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. 6121. N80 . 6630. Limited Tx HS UL Succ. HS UL Succ. First Tx R. Rate HS Dual Carrier Sess. A845 Nokia Qualcomm Scan. 7376. C905*/C702. E-AGCH R. W760i K800i K600i V800. Rate HS UL S. Razr V3x A835. Information Elements Firmware Version Frequent AQM* c GSM Neigh* Hardware HO Event Type* HS 64-QAM Mod. Information Element Support in Phones and Scanners Sony Ericsson Motorola W995* Z750i. G. Rate HS UL Non-Serving* HS UL Number of TTIs HS UL Power Limited Tx HS UL Retransm. E1070.* HS MIMO* HS Phy* HS UL Average* HS UL BLER 1st HS UL BLER Residual HS UL Buffer Limited Tx HS UL DTX Rate HS UL E-DCH Th’put HS UL E-DPCCH Power HS UL E-DPDCH Power HS UL Error Blocks* HS UL Error Residual Bl.Chapter 4. 6650. . N80 . Razr2 V9 E1000. AS M. 12th* PDP* PESQ* c Poss No .. HS* (others) HS-DSCH HARQ Proc. Information Elements HS UL Transm.. 6650. 3–4 Poss No . HS-DSCH Post Rate HS-DSCH Pre Rate HS-DSCH Throughput HS-DSCH * Per Process HS-DSCH* (others) HS-SCCH* IMEI Inter-freq* Inter-RAT* Intra-freq* MCC Message Hex Dump.. W760i K800i K600i V800. Distr.. A845 Nokia Qualcomm Scan. 5–12 204 6680.* d HS UL UE Tr. AS M. 1–2 Poss No . Z800 Razr V3xx. Razr V3x A835. 6630. MNC Mode* Mon Neigh * Sum/Ant. 2nd* Other/Own 3rd*...0: Information Elements and Events Sony Ericsson Motorola W995* Z750i. Pwr Headr..* Mon Neigh* (others) MS Behavior Modified Network Search* Other/Own 1st*. 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. 7376. N95. N96 6280. 4th* Other/Own 5th* .. EX Rohde & Schwarz EX EX 6720 6120. C905*/C702.TEMS Investigation 11.. E1070. AS M. 6121... 6121. Razr V3x A835. 6650. 7376. Z800 Razr V3xx. Razr2 V9 E1000. 6630. Sc [1st–4th] Io Sc [1st–4th] No Of SCs Sc [1st–4th] Peak* Sc [1st–4th] P-SCH* Sc [1st–4th] Rake F. Information Elements Power Control Indic. E1070. LZT 138 0375 R1A 6680. A845 Nokia Qualcomm Scan. C905*/C702. Data Mode RLC DL Throughpute RLC No Of Entities RLC UL Ent. N80 205 . Information Element Support in Phones and Scanners Sony Ericsson Motorola W995* Z750i.* RACH Initial TX RACH Max Preambles RACH Message TX RACH Transm. EX Rohde & Schwarz EX 6720 6120. 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. Data Mode RLC UL Throughpute RLC/Trsp DL Thr’put RLC/Trsp UL Thr’put RRC State* SAN URA Id SAN* (others) Sc [1st–4th] Aggr Eb/Io Sc [1st–4th] Aggr Ec Sc [1st–4th] Aggr Ec/Io Sc [1st–4th] Ag–Pk Ec Sc [1st–4th] Cell* Sc [1st–4th] Delay Spr. Sc [1st–4th] Intra-fr. W760i K800i K600i V800.Chapter 4. C. RAT Control* RB Setup UL DPCH SC RLC AM* RLC DL Ent. N95. Preamb. C. N96 6280. TEMS Investigation 11. 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. Razr V3x A835. EX Rohde & Schwarz EX 6720 6120. A845 Nokia Qualcomm Scan. 6121. 6630. C905*/C702. 6650. see above SCH TS Sc* Sector Control Serving * Sum/per Ant. 7376. N80 . Z800 Razr V3xx. N95. W760i K800i K600i V800.0: Information Elements and Events Sony Ericsson Motorola W995* Z750i. Serving Cell LAC* Serving Cell RAC* Serving CPICH Tx Pwr Serving URA Id Serving* (others) SF* SHO* SIR SIR Target Spectr Ana DL* Spectr Ana UL* SQI* Str Neigh * Sum/Ant.* Str Neigh* (others) Time Tone Event TEMS Automatic logfiles only Trsp Ch BLER* Trsp Ch Id DL 206 6680. N96 6280. Sc [5th–12th]* Sc Best*: same as Sc [1st–4th]*. E1070. Razr2 V9 E1000. Information Elements Sc [1st–4th] SC Sc [1st–4th] SC Group Sc [1st–4th] SIR Sc [1st–4th] S-SCH* Sc [1st–4th] Time Offset* Sc [1st–4th] UARFCN Sc [1st–4th] UL Interf. DL (Log). Z800 Razr V3xx. 7376. RSSI Sum VTQI f g a. C905*/C702. 6121. W760i K800i K600i V800. consult the document “AQM in TEMS Products (Including PESQ)”. Razr2 V9 E1000. UTRA Ca. 6650. or an MRU. d. 6651 HSPA+ HSPA HSDPA WCDMA Anritsu PCTel SeeGull LX. c. Trsp Ch No Of UL Trsp Ch Throughput* Trsp Ch Type* UE Initial Transmit Pwr UE Tx Power UL Interference Serving UTRA Carrier RSSI UTRA Ca. For full details. b. E1070. N80 . Supported by Nokia 6650 and 6651 but not by Nokia 6630 and 6680. since old logfiles recorded with these terminals can still be replayed. Supported by N96 only. Nevertheless. Note on Nokia phones: VTQI is based on transport channel BLER. Not supported by Sony Ericsson W760i. Also note generally that what AQM elements are obtained depends on what hardware is used at the other end: Call Generator with analog calling card. Gray checkmark: Supported only by Z750i among these phones. RSSI per Ant. N95. EX Rohde & Schwarz 207 6720 6120. g. Call Generator with digital calling card. LZT 138 0375 R1A 6680. The residual percentage is not obtained from Nokia 6720.Chapter 4. A845 Nokia Qualcomm Scan. This means that VTQI scores based on Nokia reports will not be accurate if further transport channels are used in parallel with the one used for the video call. Information Element Support in Phones and Scanners Sony Ericsson Motorola W995* Z750i. information elements supported only by TCC protocol terminals remain in the application and are kept in this table. Razr V3x A835. TCC protocol terminals are no longer connectable in TEMS Investigation. Information Elements Trsp Ch No Of DL Trsp Ch No Of Error Bl. 6630. Nokia phones do not report BLER for individual transport channels but only an average over all channels (see Trsp Ch BLER. N96 6280. e. f. except: IEs Supported by DRT Only • • Sc <nth> BCH RSSI (dBm) Sc <nth> CFO (Hz) IEs Supported by PCTel Only • Sc <nth> Channel RSSI (dBm) 208 .4.0: Information Elements and Events 4.TEMS Investigation 11. LTE Information Elements All LTE elements are populated by both DRT and PCTel. Certain Sony Ericsson phones deliver two mode reports that are relevant in this context. power unchanged. Notes on Plain-text Decoding of Mode Reports 5. TPC Info per Cell (Sony Ericsson) While in soft handover. LZT 138 0375 R1A 209 .Chapter 5. U = Up: The cell ordered the phone to raise the power. C = Skip: The phone was in compressed mode at this time. Power control commands are received on the DPCCH. whereas the DPCCH DL report gives the final power control decision obtained by combining and weighting the input from all active set members. each letter in the string represents 1/1500 of a second. TPC Info shows the power control commands from each cell in the active set separately. Notes on Plain-text Decoding of Mode Reports 5. N = No change: No power control command. the phone is power controlled jointly by all members of the active set.1. Since the power control frequency is 1500 Hz. The plain-text decoding of the TPC Info mode report represents the power control commands from each cell by a string of letters as follows: • • • • • Q = Not valid: The cell was not part of the active set at this time. D = Down: The cell ordered the phone to lower the power. measuring on a different UARFCN or on GSM. TPC Info and DPCCH DL. an event may be triggered by a message not mentioned here. Generated in drive testing mode only. Can only be associated with an audio indication. Not all of the extra information listed in the table is necessarily included every time the event occurs. Event Name Filemark GPS Connected – Symbol Description/Extra Information A filemark was encountered in the logfile. A GPS unit has been connected in TEMS Investigation. cannot appear in presentation windows. Predefined Events Here all predefined events are listed and explained.3.TEMS Investigation 11.0: Information Elements and Events 6.4. they can be changed in line charts (UM section 24. The descriptions of how events are triggered are not always exhaustive. In exceptional cases. General Events Under this heading have been collected events that do not result from interaction with a cellular network. cannot appear in presentation windows. GPS Disconnected – 210 . along with any extra information provided in the application (see section 7.5. Event symbols shown are default symbols. Can only be associated with an audio indication. 6.3) and maps (UM section 26. All cause values are decoded into plain-text format in the presentation.4). A GPS unit has been disconnected in TEMS Investigation.4).1. Generated in drive testing mode only. Chapter 6. Predefined Events Event Name GPS Position Invalid Symbol Description/Extra Information Positions reported by the GPS unit have become invalid (GPS coverage lost). (red triangle) GPS Position Valid (dark green circle) MS Connected (green) MS Disconnected (red) Recording Paused Recording Resumed Scanner Connected (green) Scanner Disconnected GPS positions are valid again (GPS coverage regained). Reported after a GPS Position Invalid event has occurred. A phone has been connected in TEMS Investigation. A phone has been disconnected in TEMS Investigation. The recording of a logfile has been paused. The recording of a logfile has been resumed. A scanner has been connected in TEMS Investigation. A scanner has been disconnected in TEMS Investigation. (red) LZT 138 0375 R1A 211 TEMS Investigation 11.0: Information Elements and Events 6.2. GSM/WCDMA/LTE/TD-SCDMA Events Events in this category are generated by phones supporting at least one of the technologies GSM, WCDMA, LTE, and TD-SCDMA. The following is to be noted: • For GAN-capable phones, call events in GAN mode are triggered in precisely the same manner as in GSM mode. This is achieved by unpacking Direct Transfer messages and extracting embedded GSM Layer 3 messages. For TD-SCDMA phones a subset of the listed events can be generated (in both TD-SCDMA and GSM mode). The extra information given in the table is rarely provided with events originating from TD-SCDMA phones. There are also a number of TD-SCDMA specific events. • The asterisk column uses the following codes: Code c e g g w ga sg sw td w Meaning Requires that a cell file has been loaded. Generated in EDGE mode. Generated in GSM mode. Generated in GSM and WCDMA mode. Generated by GAN-capable phone interacting with a GANC. Generated during GSM scanning. Generated during WCDMA scanning. Generated in TD-SCDMA mode (and unique to that mode). Generated in WCDMA mode. 212 Chapter 6. Predefined Events Event List Event Name AQM Out of Synch Symbol * g w Description/Extra Information The synchronization between the AQM module and the Call Generator has been lost. See the document “AQM in TEMS Products (Including PESQ)”. The synchronization between the AQM module and the Call Generator has been re-established. See the document “AQM in TEMS Products (Including PESQ)”. The authentication or ciphering failed. Can be generated for both packetswitched and circuit-switched. Extra information: GMM/MM cause (if available). Baton Handover Baton Handover Failure Blocked Call (red) td td g w ga Successful baton handover in TDSCDMA. An attempted baton handover in TDSCDMA failed. GSM/WCDMA/TD-SCDMA: Call abnormally ended prior to Call Established event (for example because all traffic channels were busy). GAN: Layer 3 message Activate Channel Failure received prior to Call Established. Extra information: • • • • Block type CC cause RR cause Call time (time since Call Initiation event) AQM Synched g w Authentication Failure g w LZT 138 0375 R1A 213 TEMS Investigation 11.0: Information Elements and Events Event Name Call Attempt Symbol * g w ga Description/Extra Information GSM: A traffic channel has been requested (through the Layer 3 message Channel Request). (Note that the request could also be for a signaling channel, in which case no call is actually attempted; the two types of request cannot be distinguished.) WCDMA/TD-SCDMA: An RRC Connection Request has been sent following initiation of an MO or MT call. GAN: • (MO call) GAN Layer 3 message Request sent with establishment cause 64 (TCH/H sufficient) or 224 (TCH/F needed). (MT call) GAN Layer 3 message Paging Request received. (gray) • Call Attempt Retry (gray) Call End g w g w A call attempt (see the event Call Attempt) was repeated. Triggered by Channel Request/RRC Connection Request. A call has been terminated. This event is normally triggered by the CC message Release. Extra information: • Call end cause (usually one of “MS initiated release”, “NW initiated release”, “User busy”) Call duration • Call Established (green) g w ga A call has been established. The event is triggered by • (GSM/WCDMA/TD-SCDMA:) the Layer 3 message Connect (MO call) or Connect Acknowledge (MT call) (GAN:) the Layer 3 message Activate Channel Complete. • 214 Chapter 6. Predefined Events Event Name Call Initiation Symbol * g w Description/Extra Information An MO call has been initiated by a command sequence (the equivalent of the “yes” button being pressed on the handset). This event is normally triggered by a report from the PC communication protocol, never by a Layer 3 message. This event precedes Call Attempt. Call Setup g w ga A call has been set up by the phone. The event is triggered by • (GSM/WCDMA/TD-SCDMA:) one of the Layer 3 messages Alerting or Connect (GAN:) the GAN Layer 3 message Activate Channel. Call direction (MO/MT) Call setup time (measured from Call Attempt, i.e. the first call attempt) User setup time (measured from Call Initiation, thus more accurately reflecting the user-perceived setup time; obtained only for MO calls in command sequence) • Extra information: • • • Cell Change Order From UTRAN g Successful cell change order: handover from UTRAN to GSM packet data channel. Generated after entering GSM mode. Only occurs when the change takes place from Cell_DCH mode. If it takes place from a Common channel, the event Cell Reselection From UTRAN is generated instead. Cell Change Order From UTRAN Failure w Cell change order from UTRAN failed. LZT 138 0375 R1A 215 Generated after entering GSM mode. Switch from HS-PDSCH to DPCH failed.TEMS Investigation 11. The phone has entered compressed mode. If it is to a Common channel. Cell reselection within GSM or within UTRAN (intra-frequency). Extra information (GSM): BCCH ARFCN and BSIC of new cell.0: Information Elements and Events Event Name Cell Change Order To UTRAN Symbol * w Description/Extra Information Successful cell change order: handover from GSM to UTRAN packet data channel. Cell Change Order To UTRAN Failure Cell Reselection g g w Cell change order to UTRAN failed. Successful switch from HS-PDSCH to DPCH. The phone has left compressed mode. Datalink failure caused by unsolicited Disconnected Mode response or sequence error. Successful switch from DPCH (3GPP Release 99. Generated after entering WCDMA mode. td td td w w g 216 . Generated after entering WCDMA mode. Only occurs when the change is to Cell_DCH mode. Switch from DPCH to HS-PDSCH failed. Cell Reselection From UTRAN Cell Reselection To UTRAN Channel Switch R4 To R5 Channel Switch R4 To R5 Failure Channel Switch R5 To R4 Channel Switch R5 To R4 Failure Compressed Mode Entered Compressed Mode Exited Datalink Failure g w td Cell reselection from UTRAN to GSM. Cell reselection from GSM to UTRAN. “R4”) to HS-PDSCH (3GPP Release 5. the event Cell Reselection To UTRAN is generated instead. “R5”). Extra information: • • • • Drop type Cause CC cause Call duration (time since Call Established event) EGPRS MS Out Of Memory e The phone’s status buffer has filled up so that the phone is no longer able to use Incremental Redundancy on the downlink for link quality control. Handover From UTRAN g Handover from UTRAN to GSM accomplished. Triggered by GAN Layer 3 message Handover Failure. Successful intercell handover in GSM. Predefined Events Event Name Dedicated Mode Symbol * g Description/Extra Information The phone has entered dedicated mode. Triggered by GAN Layer 3 message Handover Command if followed by Deregister or if a period of 2 s passes without Handover Failure being received.Chapter 6. Successful handover from GAN to GERAN (GSM). Dropped Call g w Call abnormally ended after Call Established event. Extra information: BCCH ARFCN and BSIC. Generated after entering GSM mode. Handover Handover Failure Handover From GAN g g ga Handover From GAN Failure ga Handover from GAN to GERAN (GSM) failed. An attempted intercell handover in GSM failed. LZT 138 0375 R1A 217 . Consequently it is forced to switch to using Link Adaptation. The same symbol is used as for Interfrequency Handover Failure (compare HS Serving Cell HO).0: Information Elements and Events Event Name Handover From UTRAN Failure Handover Intracell Handover Intracell Failure Handover To GAN Symbol * w g g ga Description/Extra Information Handover from UTRAN to GSM failed. The same symbol is used as for Interfrequency Handover.TEMS Investigation 11. Successful intracell handover in GSM. TU3920 is a timer included in the Register Accept message sent from the GANC. Handover from GSM to UTRAN failed. Hard handover in TD-SCDMA failed. Successful hard handover in TD-SCDMA. Generated after entering WCDMA mode. Handover To GAN Failure ga Handover from GERAN (GSM) to GAN failed. Successful HSPA serving cell handover. 218 . Handover To UTRAN w Handover from GSM to UTRAN accomplished. Successful handover from GERAN (GSM) to GAN. Handover To UTRAN Failure Hard Handover Hard Handover Failure HS Serving Cell HO g td td w HS Serving Cell HO Failure w Unsuccessful HSPA serving cell handover. since HSPA serving cell handover is handled in a similar way (and differently from UMTS soft handover). Triggered by GAN Layer 3 message Handover Complete. An attempted intracell handover in GSM failed. Triggered if TU3920 timer expires after Handover Access without Handover Complete being received. Extra information: BCCH ARFCN and BSIC. new SC. Inter-frequency Cell Reselection w Successful WCDMA inter-frequency cell reselection. etc. Extra information: New UARFCN. Extra information: Location update type (LUT). location update type (LUT). Predefined Events Event Name Idle Mode Symbol * g Description/Extra Information The phone has entered idle mode. Successful WCDMA intra-frequency hard handover. The phone failed in changing its location area. Location Area Update Failure g w Measurement Report 1 w Intra-frequency measurement report sent from phone (UMTS reporting event “e1a”. Extra information: Type of UMTS event. etc.Chapter 6. LZT 138 0375 R1A 219 . Extra information: Type of UMTS event.). The phone has changed location areas.). WCDMA intra-frequency hard handover failed. The GSM phone has entered limited service mode (emergency calls only). Inter-frequency Handover Failure Intra-frequency Hard Handover Intra-frequency Hard Handover Failure Limited Service Mode Location Area Update w w w g g w WCDMA inter-frequency handover failed. Measurement Report 2 w Inter-frequency measurement report sent from phone (UMTS reporting event “e2a”. Inter-frequency Handover w Successful WCDMA inter-frequency handover. Extra information: Cause. Extra information: New UARFCN. The event does not require a cell file. It is assumed that the strongest cell with decoded BSIC is the serving cell. an instance of this event is generated. etc. Extra information: Type of UMTS event. etc.TEMS Investigation 11. Measurement Report 6 w Measurement report containing phoneinternal measurements sent from phone (UMTS reporting event “e6a”.). Extra information: Type of UMTS event. BSIC.). For each cell that is not in the neighbor list. and signal strength (in dBm) of missing neighbor. Compare the LTE information element MIMO Mode. The event is only generated once for each combination of assumed serving cell (ARFCN + BSIC) and missing neighbor (ARFCN). See 3GPP 25.0: Information Elements and Events Event Name Measurement Report 3 Symbol * w Description/Extra Information Intra-frequency measurement report sent from phone (UMTS reporting event “e3a”. ARFCN. MIMO Mode Changed Missing GSM Neighbor sg (yellow bar on the right) Change of MIMO mode. section 14. Among other cells with decoded BSIC. Extra information: BCCH ARFCN and BSIC of serving cell. 220 . This is a GSM event based on scan data that includes decoded BSIC and System Information. the six strongest ones are looked up in the strongest cell’s neighbor list (which is extracted from System Information messages).331.6. Extra information: Serving cell ARFCN and BSIC (i.e. (yellow bar on the right) LZT 138 0375 R1A 221 . GSM Symmetry Symbol * g Description/Extra Information This is a GSM event based on phone data. old serving cell prior to handover). The event triggering is delayed two seconds after the handover to ensure that the entire neighbor list of the target cell has been received. Cells are compared with respect to ARFCN and BSIC.e. missing neighbor ARFCN and BSIC (i. new serving cell after handover). the event will not be triggered. Triggered in when the source cell of a handover is not in the target cell’s neighbor list. If BSIC is not available. It does not require a cell file. Predefined Events Event Name Missing GSM Neighbor.Chapter 6. 2. No cell from the strongest cell's neighbor list is detected. but at least one cell is detected besides the strongest cell. 3. (yellow bar on the right) 222 . (The event is then triggered regardless of the strength of that cell. The margin n dB is set in the General window under “LTE”. Defined neighbor Cell Identity and RSRQ. Triggered in the following cases: 1. Strongest cell Cell Identity. Strongest cell Cell Identity. It requires that a cell file is loaded and that the currently strongest cell has a neighbor list defined in that file. A cell not defined as a neighbor of the strongest cell is within n dB of the strongest cell. 2. (The event is then triggered regardless of the strength of defined neighbors. missing neighbor Cell Identity and RSRQ.) 3.) The signal power measure used in the comparisons is RSRQ. Extra information: EARFCN plus the following (different for each of the three cases listed above): 1.0: Information Elements and Events Event Name Missing LTE Neighbor Symbol * Description/Extra Information This event is based on LTE scan data. missing neighbor Cell Identity and RSRQ. missing neighbor Cell Identity.TEMS Investigation 11. A cell not defined as a neighbor of the strongest cell is more than n dB stronger than at least one neighbor of the strongest cell. 3. missing neighbor CPI.Chapter 6. Extra information: UARFCN plus the following (different for each of the three cases listed above): 1. A cell not defined as a neighbor of the strongest cell is within n dB of the strongest cell. The margin n dB is set in the General window under “TDSCDMA”. 2. missing neighbor CPI and Ec/Io. It requires that a cell file is loaded and that the currently strongest cell has a neighbor list defined in that file. (The event is then triggered regardless of the strength of that cell. Strongest cell CPI. (The event is then triggered regardless of the strength of defined neighbors. A cell not defined as a neighbor of the strongest cell is more than n dB stronger than at least one neighbor of the strongest cell. but at least one cell is detected besides the strongest cell. (yellow bar on the right) LZT 138 0375 R1A 223 . missing neighbor CPI and Ec/Io. Predefined Events Event Name Missing TD-SCDMA Neighbor Symbol * Description/Extra Information This event is based on TD-SCDMA scan data.) 3. 2. Strongest cell CPI. Defined neighbor CPI and Ec/Io.) The signal power measure used in the comparisons is Ec/Io. No cell from the strongest cell’s neighbor list is detected. Triggered in the following cases: 1. The signal strength measure used in the comparisons is CPICH Ec/No. and the strongest detected neighbor is stronger than –12 dB. The strongest active set member is stronger than –12 dB. Extra information: • Cases 1 and 2 above: Priority (“1” and “2” respectively). 3. although no active set member or monitored neighbor exists. A detected neighbor exists. Triggered in the following cases: 1. The strongest active set member lies between –18 dB and –12 dB. strongest active set member SC and Ec/No. 2. Case 3: Missing neighbor SC and Ec/ No. missing neighbor SC and Ec/No.0: Information Elements and Events Event Name Missing WCDMA Intra-frequency Neighbor Symbol * w Description/Extra Information This is a WCDMA event based on phone data. The event does not require a cell file. (yellow bar on the right) • 224 .TEMS Investigation 11. and the strongest detected neighbor is stronger than –12 dB. Defined neighbor SC and Ec/Io. but at least one cell is detected besides the strongest cell. LZT 138 0375 R1A 225 . Triggered in the following cases: 1.Chapter 6. A cell not defined as a neighbor of the strongest cell is more than n dB stronger than at least one neighbor of the strongest cell. 2. (yellow bar on the right) If both SIB and cell file data are available. No cell from the strongest cell's neighbor list is detected. missing neighbor SC and Ec/Io. (The event is then triggered regardless of the strength of defined neighbors. It requires either • • that the scan data includes decoded SIBs. the SIBs are used and the cell file is ignored. Strongest cell SC. or that a cell file is loaded and that the currently strongest cell has a neighbor list defined in that file. (The event is then triggered regardless of the strength of that cell. Strongest cell SC. Extra information: UARFCN plus the following (different for each of the three cases listed above): 1. missing neighbor SC. 2.) The signal power measure used in the comparisons is Aggr Ec. The margin n dB is set in the General window under “WCDMA”. 3. A cell not defined as a neighbor of the strongest cell is within n dB of the strongest cell. Predefined Events Event Name Missing WCDMA Neighbor Symbol * (c) sw Description/Extra Information This event is based on WCDMA scan data. missing neighbor SC and Ec/Io.) 3. (red bar on the right) No Service Mode Packet Mode g g The phone has entered no service mode. The information element Poss No of AS Members (with argument = power threshold n dB governed by the Missing Neighbor Margin setting in the General window under “WCDMA”) is larger than 3. Extra information: UARFCN. Protocol Data Unit error caused by syntax error in Layer 3 message. The phone has entered packet mode (it has switched to a PDCH). Extra information: • Setup time. counted from the first Activate PDP Context Request message to Activate PDP Context Accept. counted from the first RRC Connection Request message to Activate PDP Context Accept. • PDP Context Activation Failure PDP Context Deactivation PDU Error g w g w g Activation of a PDP context failed. Extra information: BCCH ARFCN and BSIC. An active PDP context has been deactivated. PDP Context Activation g w A PDP context has been successfully activated.0: Information Elements and Events Event Name More Than 3 Strong SCs Symbol * sw Description/Extra Information This event is based on WCDMA scan data. and all the detected scrambling codes are stronger than –100 dBm. since it cannot find a control channel. PDP context completion time. 226 .TEMS Investigation 11. Extra information: Failure cause. failure cause. PS RAB Channel Rate Switch Failure w A change of spreading factor failed for the radio access bearer. Extra information: Direction of switch: “Dedicated to Common” or “Common to Dedicated”. was changed successfully for the radio access bearer. PS Attach Failure g w The phone failed to attach to the packet service. Extra information: Attach type. The spreading factor.Chapter 6. LZT 138 0375 R1A 227 . PS Detach PS RAB Channel Rate Switch Complete g w w The phone successfully detached from the packet service. attach completion time. RACH Error w A RACH error was triggered because no RRC Connection Request was sent after initiation of a voice call by a command sequence. Extra information: Uplink and downlink spreading factors. Extra information: Attach type. PS Channel Type Switch Failure w A switch between a dedicated data channel and a common data channel failed. and hence the data rate. Extra information: Uplink and downlink spreading factors. Extra information: Direction of switch: “Dedicated to Common” or “Common to Dedicated”. PS Channel Type Switch Complete w A switch between a dedicated data channel and a common data channel succeeded. Predefined Events Event Name PS Attach Symbol * g w Description/Extra Information The phone successfully attached to the packet service. TEMS Investigation 11. event type. removed scrambling codes. Radio Link Addition Failure w Addition of one or several radio links failed. Extra information: Failure cause. w The phone could not set up the radio bearer.0: Information Elements and Events Event Name Radio Bearer Reconfiguration Failure Radio Bearer Setup Failure Symbol * w Description/Extra Information The phone could not reconfigure the radio bearer. 228 . Radio Link Replacement w Combined addition and removal of radio links. soft handover type. Extra information: Added scrambling codes. Extra information: Cause value. Extra information: Cause value. Extra information: Removed scrambling codes. Radio Link Addition w One or several radio links have been added. Extra information: Added scrambling codes. Extra information: Failure cause. Ringing Routing Area Update g g w The GSM phone is emitting a ringing signal. Radio Link Removal w One or several radio links have been removed. The phone has changed routing areas. Radio Link Replacement Failure w Addition or removal of one or several radio links failed. soft handover type. event type. Radio Link Removal Failure w Removal of one or several radio links failed. Extra information: Failure cause. event type. Rove Out From GAN ga Successful reselection from GAN to GSM. Rove Out From GAN Failure ga Reselection from GAN to GSM failed. Extra information: Failure cause. Extra information: Failure cause. Triggered by GAN Layer 3 message Deregister. Rove In To GAN Failure ga Reselection from GSM to GAN failed. Predefined Events Event Name Routing Area Update Failure Symbol * g w Description/Extra Information The phone failed in changing its routing area. RRC Connection Abnormal Release w An RRC connection was abnormally released. Triggered by GAN Layer 3 message Register Accept. Rove In To GAN Redirect ga When reselecting from GSM to GAN. w An RRC connection has been established. Triggered by GAN Layer 3 message Register Redirect. Extra information: Establishment cause. RRC Connection Reject RRC Established (green) w An RRC connection was rejected. Rove In To GAN ga Successful reselection from GSM to GAN. Triggered by GAN Layer 3 message Register Reject or by the TU3904 timer expiring after Register Request is sent. Extra information: Failure cause. Triggered when GA-RC/GA-CSR State switches to Deregistered without Deregister message being received. the phone was redirected from the default GANC to a different GANC. Extra information: Failure cause. LZT 138 0375 R1A 229 .Chapter 6. See the document “AQM in TEMS Products (Including PESQ)”. A Channel Request Timeout occurred. The event is triggered 27.0: Information Elements and Events Event Name RRC Protocol Error Symbol * w Description/Extra Information An RRC protocol error occurred. Security Mode Failure SHO Procedure Complete SHO Procedure Complete Without Measurement Control w w Soft handover: Active set update procedure completed with Measurement Control message. Extra information: “Addition”/”Removal”/ ”Replacement”. Extra information: Failure cause. Soft handover: Active set update procedure completed without a Measurement Control message (because another soft handover procedure started).e. (red) Scanning Mode sg The GSM phone has entered scanning mode. 230 . SMS Error SMS Received SMS Sent T200 Expired T3126 Expired g w g w g w g g Transfer of an SMS message failed (during either sending or receiving). An SMS message was successfully received. i. Sending of an SMS message was successfully competed. w Silent Call g w A silent call was detected by the AQM algorithm: all system signaling was OK. but the audio was not transferred in both directions. A Layer 2 Timeout occurred.TEMS Investigation 11.5 s after the last Stop DTMF Acknowledge message. A security mode command failed. Extra information: Cause value. it has started some type of scanning. Triggered by Service Connect Completion (RTCH) Message. MO call: Origination (ACH) message sent with a voice Service Option. The phone is in traffic state. or Order (PCH) Message received with one of the order codes “Reorder”. Triggered by Order (RTCH) Message or Order (FTCH) Message with order code = Release. MT call: Order (RTCH) Message with order code = Connect. Predefined Events Event Name T3162 Expired T3168 Expired T3170 Expired Symbol * g g g Description/Extra Information A Packet Queuing Timeout occurred.3. “Intercept”. A Packet Assignment Timeout occurred. “Registration Reject”. A Packet Channel Request Timeout occurred. A call has been set up by the phone. A call attempt (see Call Attempt above) was repeated. 6. Blocked Call (red) Call Attempt (gray) Call Attempt Retry (gray) Call End Call Established (green) Call Initiation Call Setup Dedicated Mode LZT 138 0375 R1A 231 . CDMA Events Event Name Symbol Description/Triggered By Unexpected change to idle or init state before Call Established. MT call: Page Response (ACH) message received with a voice Service Option. or “Release”. Triggered by Protocol Report containing dialed number.Chapter 6. MO call: Triggered by Service Connect Completion (RTCH) Message. EV-DO Connection Success EV-DO Dynamic Rate The phone switched back from fixed rate to dynamic rate during an EV-DO session. EV-DO Handoff 1 Active EV-DO Handoff 2 Actives EV-DO Handoff 3 Actives EV-DO active set reduced to a single pilot. EV-DO Fixed Rate The phone has entered fixed rate mode for a period of time during an EV-DO session. EV-DO Connection Failure An EV-DO connection attempt failed. Triggered by EV-DO Tuneaway Information Report. An EV-DO access attempt completed successfully. An EV-DO connection attempt completed successfully. Triggered by EV-DO Connection Attempt Report. Triggered by EV-DO Access Attempt Report. The phone suspended the EV-DO service to look for 1x paging. Triggered by EV-DO Connection Attempt Report.0: Information Elements and Events Event Name Dropped Call EV-DO 1x Tuneaway Symbol Description/Triggered By Unexpected change to idle or init state after Call Established. Handoff in EV-DO traffic mode. EV-DO Access Failure EV-DO Access Success An EV-DO access attempt failed. Handoff in EV-DO traffic mode. Triggered by receipt of Fixed Mode Enable Message (containing a given end time). two pilots in active set. three pilots in active set. 232 . Triggered by occurrence of fixed rate end time (see EV-DO Fixed Rate).TEMS Investigation 11. Triggered by EV-DO Access Attempt Report. LZT 138 0375 R1A 233 . An EV-DO session attempt completed successfully. Idle Handoff To Analog System change from 1x or EV-DO to Analog in idle mode. a different pilot set. Handoff in EV-DO traffic mode. Idle Handoff To CDMA System change from Analog or EV-DO to 1x in idle mode. EV-DO Session Failure An EV-DO session attempt failed. five pilots in active set. Triggered by EV-DO Pilot Sets Ver2 Report. Idle Handoff Idle handoff 1x to 1x or EV-DO to EV-DO. Triggered by System Determination Last Main Action Report. six pilots in active set. Triggered by Active Set Change. Triggered by Active Set Change. a different band. Triggered by System Determination Last Main Action Report. four pilots in active set. or a combination of these. EV-DO Session Success Hard Handoff Handoff in traffic state to another frequency. Triggered by EV-DO Session Attempt Ver2 Report.Chapter 6. or another frame offset. There is only a single active pilot and no candidates. Predefined Events Event Name EV-DO Handoff 4 Actives EV-DO Handoff 5 Actives EV-DO Handoff 6 Actives EV-DO Island Symbol Description/Triggered By Handoff in EV-DO traffic mode. Handoff in EV-DO traffic mode. Triggered by EV-DO Session Attempt Ver2 Report. The latter margin is set in the General window: see UM section 13. 234 .5. or is in sleep mode. The event is generated only once for a given interferer in the course of a scan. only one event is reported for all of these channels. No Service Mode Packet Mode Polluter (red bar on the right) Soft Handoff 2-Way The mobile is searching for serving network. two pilots in active set. The phone is in init state or has entered idle mode.0: Information Elements and Events Event Name Idle Handoff To EVDO Symbol Description/Triggered By System change from 1x to EV-DO in idle mode. See algorithm description in section 6. Idle Mode Missing CDMA Neighbor (olive green bar on the right) Narrowband Interference Generated in the course of narrowband interference scanning: see UM section 13.3. See algorithm description in section 6.1.1.1.3. The phone has entered data traffic mode. if interference is detected on several contiguous RF channels. Soft handoff in 1x traffic mode. Triggered by System Determination Last Main Action Report.TEMS Investigation 11. Triggered when an in-band RF channel has a strength exceeding the average in-band RSSI by an amount at least equal to Interference Offset.5. Furthermore. LZT 138 0375 R1A 235 . six pilots in active set. Triggered by System Determination Last Main Action Report. Active set in 1x reduced to a single pilot. System change from 1x to Analog during traffic. four pilots in active set. Triggered by System Determination Last Main Action Report.Chapter 6. five pilots in active set. Soft handoff in 1x traffic mode. Traffic Handoff To CDMA Traffic Handoff To EV-DO System change from 1x to EV-DO during traffic. three pilots in active set. Triggered by System Determination Last Main Action Report. Soft handoff in 1x traffic mode. System change from Analog or EV-DO to 1x during traffic. Soft handoff in 1x traffic mode. Predefined Events Event Name Soft Handoff 3-Way Soft Handoff 4-Way Soft Handoff 5-Way Soft Handoff 6-Way Soft Handoff Complete Traffic Handoff To Analog Symbol Description/Triggered By Soft handoff in 1x traffic mode. Order all pilot responses by descending .0: Information Elements and Events 6. Identify all pilots whose strength exceeds . Calculate where is the largest integer such that . is a 236 . where 6. Algorithm for Pilot Pollution and Missing Neighbor Detection in CDMA 1. Discard pilots that lie below the noise floor (which is technology and frequency band dependent). If polluter.TEMS Investigation 11. check whether the strongest pilot is in the neighbor list.3. Calculate . 4. 2. there is no pilot pollution.1. 7. then each pilot such that . Any pilot not in the neighbor list is flagged as a missing neighbor. where is the maximum number of fingers that a receiver can demodulate. . Calculate the percentage of useful energy 8. 3. 5. . If 9. Let . For . Chapter 6. The packet-switched access procedure succeeded from RAS Dial to IP Address Assigned. Predefined Events 6. Data Events These events are generated in the course of data service testing. Extra information: Failure cause. It is therefore always accompanied by either of the other two Ping events.4.3. A RAS dial-up has been performed. Extra information: • • Ping timeout notification Ping size PS Access Failure The packet-switched access procedure failed somewhere between RAS Dial and IP Address Assigned. it is equivalent to “Ping Success OR Ping Timeout”.21. NDIS Error Setup of an NDIS connection failed. PS Access Success RAS Dial LZT 138 0375 R1A 237 . Ping Response This event tells that the outcome of a Ping Request has become known. see UM section 15. Event Name IP Address Assigned Symbol Description/Extra Information An IP address has been assigned to the RAS client. Extra information: • • Ping delay Ping size Ping Timeout A Ping Request timed out. Extra information: IP address. Extra information: • • Ping Success Ping delay or timeout notification Ping size A response to a Ping Request was received. “Reproducing”. “Prebuffering”. 238 . Extra information: Session information.0: Information Elements and Events Event Name RAS Error Symbol Description/Extra Information An error occurred when performing a RAS dialup.21.21.TEMS Investigation 11. Session Start A data session has started. “Finished”.2. “Rebuffering”. “Negotiating”. RAS Hangup Session End A RAS hangup has been performed. Session Error A data session was interrupted because of an error. number of successful pings. see UM section 15. see UM section 15. Streaming State Changed The state of the streaming video client in TEMS Investigation has changed. Extra information: • • Session duration (If Ping was run during the session:) Total number of pings. A data session has ended. Extra information: State of streaming video client. Extra information: Failure cause. mean ping delay. Extra information: Failure cause. One of “Connecting”. 7. Note that only windows covered by your license will show up in the applications. (This window is common to multiple technologies. For example. Overview of Preconfigured Presentation Windows This chapter explains the purpose of each window found on the Menu tab of the Navigator.1.1.1. including PER and RLP layer performance. Shows information on an ongoing data session governed by a command sequence. Shows statistics on good and bad packets for each forward link data rate.1. if your license does not cover CDMA or EV-DO. Window Name Data Bytes Sent/Received Data Session EV-DO Overview EV-DO Forward Link Packets LZT 138 0375 R1A 239 .1.Chapter 7.1. all windows containing CDMA or EV-DO data will be hidden.) Shows data that is relevant to EV-DO. Preconfigured Status Windows CDMA Status Windows Data Service Status Windows Description Shows the total number of data bytes sent and received at various protocol levels. 7. Overview of Preconfigured Presentation Windows 7. 7. 6. Other Status Windows Description Shows properties of all cells in the CDMA active. and parameter settings of the current serving cell.0: Information Elements and Events Window Name EV-DO Reverse Link Packets EV-DO Status Description Shows statistics on good and bad packets for each reverse link data rate. FER/PER. The same window covers both 1x and EV-DO. Window Name A/C/N Sets Active Set Candidate Set Finger Info Neighbor Set Radio Parameters Serving Speech Quality 240 .1. Shows FER. Shows properties of the cells in the CDMA neighbor set. and Frequent AQM. PESQ. states. see section 3. Includes special features for graphical presentation of the T-Add and T-Drop thresholds. see UM section 19. candidate.1.TEMS Investigation 11. See UM chapter 30.2. and Tx/Rx Power. Shows properties of the cells in the CDMA candidate set. Shows data on Rake fingers. Among the data shown is signal strength. Shows a variety of EV-DO state values. Shows various IDs. For particulars of the information elements listed.2. Shows properties of the cells in the CDMA active set. and neighbor sets. Shows a collection of vital data about the status of the radio link.1. 7. 1. EDGE. Shows throughput and error/retransmission rates for HSCSD. Overview of Preconfigured Presentation Windows 7. and some parameters in other windows) is only shown when a data testing command sequence is being executed or replayed. EGPRS Status GPRS Status HSCSD Throughput PDP Context LZT 138 0375 R1A 241 . and channel coding/ modulation coding scheme usage for each timeslot.2. Some of the information (everything in the Data Session window. Shows throughput and decode error/ retransmission rates for GPRS/EGPRS. 7.1. Shows PDP context data for GPRS/ EGPRS.1.Chapter 7. GSM Status Windows Data Service Status Windows The information in these windows is obtained when running GPRS. or HSCSD.1. Shows the state and performance of the GPRS connection. Shows the timeslots currently used on the uplink and downlink for GPRS/EGPRS or HSCSD.2. performance. See section 7. as well as the utilization.1. Window Name Data Bytes Sent/Received Data Session Data Throughput Data Timeslots Description Shows the total number of data bytes sent and received at various protocol levels.1. Shows the state and performance of the EGPRS connection. including quality-of-service requirements specified in the subscription. 1. Interference Status Windows Description Shows the interference from adjacent channels.4.2. Window Name Uplink Neighbors Uplink Radio Parameters Uplink Serving Cell 7. the window shows the entire hopping list sorted by ascending C/I: the currently worst channel is at the top.1.1.2. Uplink Status Windows Description These windows present various categories of information from MTR files.0: Information Elements and Events 7. Shows the distribution of AMR speech codec usage for the time spent in the current serving cell.e. i.2. Window Name AMR Call Average AMR Cell Average 242 . Other GSM Status Windows Description Shows the distribution of AMR speech codec usage for the whole of the call currently in progress. Shows the carrier-over-interference ratio.TEMS Investigation 11. The C/I measure is discussed in UM chapter 33. If frequency hopping is used. the ratio between the signal strength of the current serving cell and the signal strength of interfering signal components.3.2. Window Name C/A C/I 7. Shows the current state of the userconfigurable GSM properties for the phone: see UM chapter 16. It also shows current time. Shows measurements and network parameters relating to the GAN as well as to the GERAN. For particulars of the information elements listed. RxLev and C/I for all channels currently in the hopping list. speech quality. Shows information elements relating to the channel currently used. see section 3.1. Shows ARFCN. Shows a collection of vital data about the status of the radio link (current BCCH. Overview of Preconfigured Presentation Windows Window Name AMR Codec Usage Description Shows the most recent distribution of AMR speech codec usage (exact updating frequency for these statistics may vary between phones). ARFCN.Chapter 7. and some further parameters for the serving cell and its neighboring cells. signal strength. and so on). Shows BSIC. AMR Settings Current Channel GAN Status Hopping Channels Modified MS Behavior Radio Parameters Serving + Neighbors LZT 138 0375 R1A 243 . sorted by signal strength in descending order. For particulars of the information elements listed. RxLev.1. see section 3. Shows the current active set of AMR speech coders on the uplink and downlink respectively. along with hysteresis and threshold values governing AMR mode switches (changes from one coder to another). with the serving cell on top and the neighbors below it. CI.1. See UM chapters 29 and 30.4. and Frequent AQM.1. ESM State.2.4. Other LTE Status Windows Description Shows information on each EPS bearer in use.1.1. PESQ. 7. RSRP. iDEN Status Windows Window Name Description Shows iDEN information elements. (This window is common to GSM and WCDMA.1.3. and RSRQ. Window Name EPS Bearer NAS Status 244 . Shows SQI. Shows Non-Access Stratum status: EMM State. iDEN Status 7.4.0: Information Elements and Events Window Name Serving + Neighbors By Band Description Similar to Serving + Neighbors except that the cells are sorted first by frequency band and then by signal strength in descending order. LTE Status Windows Scanning Status Windows Description Shows various data for each LTE cell scanned: EARFCN.) Speech Quality 7. Window Name Scanned Cells 7.TEMS Investigation 11. 1. TD-SCDMA Status Windows Data Service Status Windows Description See section 7. Shows information elements related to HSDPA.5. and RSRQ for the serving cell and its neighboring cells.4 for definitions of the information elements.5. Scanning Status Windows Description Shows various data for each TD-SCDMA cell scanned. sorted by signal strength in descending order. CPI. Shows a variety of RRC and RLC states. Shows EARFCN.Chapter 7. Shows configuration of and throughput on current RLC radio bearers.1. RSRP.1.5. CI. with the serving cell on top and the neighbors below it. Eps/Io. Shows PDP context data for TD-SCDMA.1. Ec/Io.1. See section 3. Window Name Data Session HSDPA Analysis PDP Context 7. 7.1. Window Name Scanned Cells LZT 138 0375 R1A 245 . Overview of Preconfigured Presentation Windows Window Name PDN Connection RLC Radio Bearer RRC/RLC Status Serving/Neighbor Cells Description Shows information on current packet data network connections. and SIR. including UARFCN.1. 7.2. 7.0: Information Elements and Events 7. Window Name Cell Reselection Current Channel Radio Parameters Serving + Neighbor Timeslots Transport Channels 246 .TEMS Investigation 11.5.1. It also shows current time. For particulars of the information elements listed. with the serving cell on top and the neighbors below it. including serving cell P-CCPCH RSCP. Shows timeslot usage as well as pertimeslot RSCP. For particulars of the information elements listed. Shows a collection of vital data about the status of the radio link. ISCP. CPI. and C/I readings.1. Other TD-SCDMA Status Windows Description Shows the values of cell search and reselection related parameters. Shows UARFCN.6. see section 3.5. and TxPower levels.4. TD-SCDMA Physical Channel Monitor Regarding this specially designed window. and signal strength readings for the serving cell and its neighboring cells. serving cell carrier RSSI. Shows data on each transport channel in use. see section 3.4. sorted by signal strength in descending order. Shows information elements relating to the channel currently used. see UM section 19.1.4.3. 2 for definitions of the information elements. See section 3. See section 3.1. Shows information elements related to HSDPA (single-antenna case). Shows HS information elements that are differentiated with respect to HARQ processes.1.Chapter 7. It is only shown when a data testing command sequence is being executed or replayed. WCDMA Status Windows Data Service Status Windows The information in these windows is obtained when testing data services.2 for definitions of the information elements. Overview of Preconfigured Presentation Windows 7. Shows information elements related to HSUPA.1. 7. Similar to the HSDPA Analysis window but for MIMO.1.1. Shows PDP context data for WCDMA. including quality-of-service requirements specified in the subscription. See section 3.6.6. Window Name Data Session DVB-H Analysis Description See section 7. HSDPA Analysis HSDPA Analysis MIMO HSDPA Analysis Per Process HSUPA Analysis PDP Context LZT 138 0375 R1A 247 .1. Shows information elements related to DVB-H.2 for definitions of the information elements. The data is given for each antenna separately. 7.2.6. Other WCDMA Status Windows Description Shows the distribution of AMR speech codec usage on uplink and downlink. See UM section 10. See UM section 10. All UARFCNs are covered in the same window. Window Name CPICH Best UARFCN Data CPICH Data Network Search Synch Channel Data 7.TEMS Investigation 11. Shows the outcome of network search scanning (UARFCNs and scrambling codes found).9.1.2.6.1. Shows scan data on the synchronization channels P-SCH and S-SCH. regardless of UARFCN. Shows pilot scan data for the strongest scrambling codes on each UARFCN.2. These windows show Rake finger information (obtained from either phones or scanners) for one UARFCN.2.2.6.2. Scanning Status Windows Description Shows pilot scan data for the strongest scrambling codes. See UM section 10. See UM section 10. 248 . obtained with the Pilot scanning method.) UARFCN GSM Neighbors Shows measurements of GSM neighbors performed in WCDMA mode. See UM section 10.7.3. Window Name AMR Codecs Finger Info 1st (etc.0: Information Elements and Events 7.8. Intra-Freq Meas Ctrl Events Modified MS Behavior RACH Analysis Radio Parameters Serving/Active Set + Neighbors Speech Quality LZT 138 0375 R1A 249 . and Frequent AQM. Shows SQI. success rate. Details about the elements are found in section 3. and inter-RAT criteria.Chapter 7. softer) and real-time statistics on handover frequency. inter-frequency.2. See section 3. See UM chapters 29 and 30. soft. These windows give the essentials of Measurement Control reports. Shows a collection of information elements describing the status of the radio link and some more general radio conditions. “RAT State” shows which radio access technology is currently used: GSM or WCDMA. (This window is common to GSM and WCDMA. Separate windows are provided for intrafrequency. Shows the current state of the userconfigurable WCDMA properties for the phone: see UM chapter 16. Inter-RAT Meas Ctrl Events.2 for precise definitions of the information elements shown. Shows information on the number of RACH preambles and their transmit power. and distribution across soft handover types. Overview of Preconfigured Presentation Windows Window Name Handover Description Shows information on handovers: indication of handover type (hard. PESQ. Shows data on the serving cell/active set and on the monitored neighboring cells.) Inter-Freq Meas Ctrl Events. which tell the UE what should trigger the sending of a measurement report to the network. 0: Information Elements and Events Window Name Transport Channels Description Shows data on each transport channel in use. WiMAX Status Windows Window Name Description Shows data on all preambles detected.1. including power and CINR. Scanned Preamble Index 7. 7.3. see UM chapter 20. Call Analysis Missing Neighbor Session Status WCDMA Handover Analysis 250 .TEMS Investigation 11. 7.2. Regarding Event Counter windows in general. Lists missing neighbor events (for multiple cellular technologies). Lists RRC messages that concern the DCCH as well as the “SHO” (soft handover) events.1. Preconfigured Event Counter Windows A preconfigured Event Counter window is found in the Analysis folder.3.7. Lists events pertaining to data sessions. 7. Preconfigured Message Windows Analysis Message Windows Window Name Description Lists events pertaining to calls and handovers (for multiple cellular technologies). Chapter 7.4.245 and IP protocol reports.3. Also lists H.2. Overview of Preconfigured Presentation Windows 7. Data Reports Error Reports Lists reports from the external device concerning malfunctions and received corrupt messages.4). GSM Uplink Data Message Windows Window Name Description Lists messages from uplink files (Ericsson Mobile Traffic Recordings). Note that these messages contain some information not appearing in the information elements in section 3.3–21.3. The Events and Columns tabs are absent from the properties dialog of this window (UM sections 21.1. data on throughput and overall VSQI scores for streaming sessions in Session End Reports).3. iDEN Messages 7. LZT 138 0375 R1A 251 .1. iDEN Message Windows Window Name Description Lists messages from iDEN phones. Signaling Message Windows Window Name Description Lists messages pertaining to data service testing. Ericsson MTR Records 7.8 (in particular. See UM chapter 34.3. handover. the emphasis being on call. handover. you can double-click an event in the Events windows to view details on the event in a separate plain-text window. extra information is provided. IP Analysis Lists all air interface message traffic occurring over the protocols in the Internet protocol suite: • Application layer: BOOTP. RTP. Layer 3 Messages Mode Reports 252 . PPP CHAP. For certain events. UDP Network layer: ICMP. RTSP. the emphasis being on call. and failure events. By default this window also shows certain events. All predefined events are listed in chapter 6 of this volume. IPv4.TEMS Investigation 11.0: Information Elements and Events Window Name Events Description Lists all events that occur. both predefined and user-defined. Lists Layer 3 messages. By default this window also shows certain events. IPv6 Data link layer: PPP CC. handover. NBNS. and failure events. NBDS. As in other message windows. PPP IPCP. PPP LCP. By default this window also shows certain events. DNS. FTP.3. RTCP. the emphasis being on call. The contents of this extra information are detailed in chapter 6. FTP-DATA. SNMP Transport layer: TCP. how to create user-defined events is covered in UM section 17. and failure events. Lists (vendor-specific) reports from external devices concerning their status. PPP PAP • • • Layer 2 Messages Lists Layer 2 messages. HTTP. 5.1. Tracks GPRS performance.4.5. 7. These charts track the strongest scanned pilots on a particular RF channel. Shows call events. Tracks the signal strength of the serving cell and neighbors. Shows data service testing events. including throughput.Chapter 7. Shows call and handover events. Video Monitor See UM chapter 22. 7.2. CDMA Line Chart CDMA Data Line Chart PN Scan 1st (etc. Shows data service testing events. GSM Line Charts Window Name Description Tracks EGPRS performance. EGPRS Line Chart GAN WLAN Quality Line Chart GPRS Line Chart GSM Line Chart LZT 138 0375 R1A 253 . Preconfigured Line Charts CDMA Line Charts Window Name Description Tracks the signal strength of active set and candidate set members. Overview of Preconfigured Presentation Windows 7. including throughput and BEP. Tracks signal strength and quality level in a WLAN. Tracks data service performance (1x and EV-DO). Shows data service testing events.5.) RF Line Chart 7. iDEN Line Chart 7.) EARFCN Line Chart RSSI Scan Line Chart Serving Cell Line Chart 254 . including VSQI.5. Tracks LTE RSRP and RSRQ on a particular scanned EARFCN. intended for presentation of interference scan data (from old logfiles). Tracks the performance of a video streaming session.0: Information Elements and Events Window Name Interference Line Chart Description This is a “shotgun chart”.) Uplink Line Chart Video Streaming Line Chart 7.5. iDEN Line Charts Window Name Description Tracks iDEN information elements.4. LTE Line Charts Window Name Description Tracks LTE MAC layer throughput. (This line chart is common to GSM and WCDMA. See UM chapter 34.3. Tracks the strongest LTE frequencies found during RSSI scanning.TEMS Investigation 11. Presents data from MTR files (signal strength and power level). MAC Throughput Line Chart RS 1st (etc. Tracks LTE serving cell RSRP and RSRQ. E-DPCCH. Tracks data service performance for TDSCDMA and (E)GPRS.Chapter 7.6. including application and RLC layer throughput as well as data service testing events. Tracks the strongest TD-SCDMA frequencies found during RSSI scanning. Tracks transport channel throughput as reported by Sony Ericsson UEs. including application and RLC layer throughput as well as data service testing events. WCDMA Line Charts Window Name Description Tracks scanned scrambling code signal strength on the CPICH for one UARFCN. Tracks data service performance for TDSCDMA. Tracks DVB-H performance.5. Tracks serving and neighbor signal strength for both TD-SCDMA and GSM.) RF Line Chart RSSI Scan Line Chart TD-SCDMA HS/GSM Data Line Chart TD-SCDMA Line Chart TD-SCDMA RLC Data Line Chart TD-SCDMA/GSM Line Chart 7. CPICH Scan 1st (etc.) UARFCN Line Chart DVB-H Stats Line Chart HS UL Output Power Trsp Ch Throughput Line Chart: Sony Ericsson LZT 138 0375 R1A 255 . and EDPDCH transmit power. Tracks DPCCH. See UM section 10. TD-SCDMA Line Charts Window Name Description Tracks scanned CPI signal strength on one UARFCN. Overview of Preconfigured Presentation Windows 7.7.2.5. Tracks serving and neighbor signal strength as well as UE transmit power. CPI Scan 1st (etc.5. including application and RLC layer throughput as well as data service testing events. and SQI. WiMAX Line Charts Window Name Description Tracks the strongest WiMAX channels found during preamble scanning.TEMS Investigation 11. Similar to WCDMA Line Chart. Tracks data service performance for WCDMA R99 and (E)GPRS. (This line chart is common to GSM and WCDMA. including application and RLC layer throughput as well as data service testing events.7. but also tracks GSM serving cell readings. including application and RLC layer throughput as well as data service testing events. Channel RSSI Line Chart RSSI Scan Line Chart 256 . Tracks data service performance for WCDMA R99.5. UE transmit power. 99/GSM Data Line Chart WCDMA RLC Data Line Chart WCDMA Line Chart WCDMA Two Antenna Line Chart WCDMA/GSM Line Chart 7. Tracks CPICH and GSM neighbor signal strength. including VSQI. Tracks the strongest channels found during RSSI scanning. WCDMA HSPA/GSM Data Line Chart WCDMA Rel. Tracks CPICH signal strength readings for each antenna used in MIMO.0: Information Elements and Events Window Name Video Streaming Line Chart Description Tracks the performance of a video streaming session.) Tracks data service performance for HSPA and (E)GPRS. These charts show the strongest scanned pilots on a particular RF channel. Overview of Preconfigured Presentation Windows 7. Shows the strongest pilots among all scanned RF channels.3. See UM section 13. CDMA Bar Chart Narrowband Interference Scan Bar Chart PN Scan 1st (etc.2. See UM section 13. each consisting of one C0 frequency surrounded by four adjacent channels (–2. 7.3. Preconfigured Bar Charts CDMA Bar Charts Window Name Description Shows signal power. Shows the result of an RSSI scan.1. obtained when scanning in “follow phone” mode. Shows the result of a narrowband interference scan. See UM section 13.6. Channels are drawn in groups of five.Chapter 7. GSM Bar Charts Window Name Description Shows C/A measurements.1. See UM section 13.2. –1. Shows the polluter top list.3. +1. and PER. Adjacent Bar Chart LZT 138 0375 R1A 257 .6.) RF Bar Chart Polluters Bar Chart RSSI Scan Bar Chart Spectrum Analysis Bar Chart Strongest Scanned PN Bar Chart 7.6. See UM section 13. Shows the result of a spectrum scan.6. FER. +2). See UM section 13.5.4. Shows the result of a spectrum scan. but here a parallel coordinates presentation is used where all C0 channels are connected by one line. LTE Bar Charts Window Name Description Shows RSSI for frequencies measured during an enhanced power scan.4. Shows GSM interference scan data (from old logfiles). Shows output from an RSSI scan. Shows RSRP and RSRQ for serving and neighbor cells.2. Enhanced Power Scan Bar Chart RS 1st (etc. Shows GSM radio parameters. Same data as in the Adjacent Bar Chart.TEMS Investigation 11. etc. See UM section 9.) EARFCN Bar Chart RSSI Scan Bar Chart Serving/Neighbor Cells Bar Chart Spectrum Analysis Bar Chart 258 . Shows the result of an RSSI scan.3.6.0: Information Elements and Events Window Name Compact Adjacent Bar Chart Description Shows C/A measurements. Shows RSRQ for cells on a particular scanned EARFCN. all “+1” adjacent channels by another. Shows the result of a spectrum scan. Interference Bar Chart Radio Quality Bar Chart RSSI Scan Bar Chart Spectrum Analysis Bar Chart 7. 6.).5. CPI Scan 1st (etc. Applies to the phone’s latest reporting period. Shows the distribution of transmission attempts with respect to the sequence number of the attempt (1st.4. Applies to the whole of the current session.) RF Bar Chart RSSI Scan Bar Chart 7. WCDMA Bar Charts Window Name Description Shows retransmission rate and usage for each E-TFC (Transport Format Combination).6. Overview of Preconfigured Presentation Windows 7. Shows current retransmission rate and usage for each E-TFC (Transport Format Combination). 2nd.Chapter 7. HS UL E-TFC Accumulated: Sony Ericsson HS UL E-TFC Current: Sony Ericsson HS UL Transmission Distribution Accumulated: Sony Ericsson HS UL Transmission Distribution Current: Sony Ericsson HSDPA MIMO Primary Transport Block Size Bar Chart LZT 138 0375 R1A 259 .). Specific to Sony Ericsson phones. Shows the distribution of transmission attempts with respect to the sequence number of the attempt (1st. Specific to Sony Ericsson phones. TD-SCDMA Bar Charts Window Name Description Shows Ec/Io on a particular scanned UARFCN. Shows HSDPA transport block size usage (MIMO. primary stream). Shows the result of an RSSI scan. etc. 2nd. etc. averaged over the current session. These charts show various kinds of WCDMA scan data. See the example in UM section 25.5. Shows power for all segments of all scanned channels. Shows power of detected preambles sorted by channel.) UARFCN Bar Chart. Spectrum Analysis Uplink Bar Chart Description Shows HSDPA transport block size usage (MIMO. Shows codes used on the HS-PDSCH. SCH Timeslot Scan Bar Chart. Channel RSSI Bar Chart Preamble Power Group Bar Chart RSSI Scan Bar Chart Segment Power Group Bar Chart Spectrum Analysis Bar Chart 260 . Shows WCDMA radio parameters. Spectrum Analysis Bar Chart. RSSI Scan Bar Chart. 7. Shows power readings for the entire spectrum scanned. Shows WCDMA radio parameters.0: Information Elements and Events Window Name HSDPA MIMO Secondary Transport Block Size Bar Chart HSDPA PDSCH Codes Bar Chart HSDPA Transport Block Size Bar Chart Radio Parameters Bar Chart Radio Parameters Parallel Bar Chart CPICH Scan 1st (etc. Shows HSDPA transport block size usage (single-antenna case).TEMS Investigation 11. See UM sections 10.5. WiMAX Bar Charts Window Name Description Shows channel power for all scanned channels.6. secondary stream). Shows the result of a spectrum scan.2–10.6. 7. Shows segments ranked by decreasing power. Shows segments grouped by channel. Preconfigured Maps In both applications. GPS Window See UM chapter 23. • • Presentation Window Templates The Template folder in the Navigator contains blank templates for: status windows Event Counter windows LZT 138 0375 R1A 261 . 7. Shows detected preambles grouped by channel.8. and CDMA information. Channels are ranked by total preamble power. 7. Overview of Preconfigured Presentation Windows Window Name Strongest CINR Bar Chart Strongest Preamble Power Bar Chart Strongest Preamble Power Group Bar Chart Strongest Segment Power (Cha Sort) Bar Chart Strongest Segment Power (Segment Pwr Sort) Bar Chart Weakest CINR Bar Chart Weakest Preamble Power Bar Chart Description Shows detected preambles ranked by decreasing CINR. a map window is supplied that is configured with some basic GSM. WCDMA. Shows detected preambles ranked by increasing CINR. Channels are ranked according to the power of their strongest segment.9. 7. regardless of channel. Shows detected preambles ranked by increasing power. Shows detected preambles ranked by decreasing power.Chapter 7. These templates contain no data. 262 .TEMS Investigation 11. you customize their contents from scratch.0: Information Elements and Events • • • message windows line charts bar charts. Abbreviations ACR AG AGC ALMP AM AMBR AMR AMR-NB AMR-WB APM AQM ARFCN AS ASP AT BCC BCCH BCH BEP BER BLEP BLER BOOTP BSIC BSN C/A C/I C/N CBCH CDMA CFO CGI CHAP CI CINR Absolute Category Rating Absolute Grant Automatic Gain Control Air Link Management Protocol Acknowledged Mode Aggregate Maximum Bit Rate Adaptive Multi Rate Adaptive Multi Rate Narrowband Adaptive Multi Rate Wideband Advanced Power Management Audio Quality Measurement Absolute Radio Frequency Channel Number Active Set Active Set Pilot Access Terminal Base Station Colour Code Broadcast Control Channel Broadcast Channel Bit Error Probability Bit Error Rate Block Error Probability Block Error Rate Bootstrap Protocol Base Station Identity Code Block Sequence Number Carrier-to-Adjacent (Ratio) Carrier-to-Interference (Ratio) Carrier-to-Noise (Ratio) Cell Broadcast Channel Code Division Multiple Access Carrier Frequency Offset Cell Global Identity Challenge Handshake Authentication Protocol Cell Identity Carrier to Interference-plus-Noise Ratio LZT 138 0375 R1A 263 .Appendix A. Abbreviations Appendix A. (Enhanced) Enhanced Dedicated Channel Enhanced Data Rates for GSM Evolution (= EGPRS) E.(Enhanced) HARQ Acknowledgement Indicator Channel Effective Isotropic Radiated Power EPS Mobility Management Evolved Packet System E.(Enhanced) Relative Grant Channel EPS Session Management Electronic Serial Number Extended Service Set 264 .TEMS Investigation 11.(Enhanced) Absolute Grant Channel E-UTRA ARFCN Extended Cyclic Prefix E.(Enhanced) Dedicated Physical Data Channel Enhanced Full Rate Enhanced GPRS (= EDGE) E.(Enhanced) Dedicated Physical Control Channel E. Server) Dedicated Physical Control Channel Dedicated Physical Channel Dead Reckoning Data Rate Control Discontinuous Reception Data Source Control (CDMA) Downlink Signalling Counter (GSM) Downlink Shared Channel Discontinuous Transmission Digital Video Broadcasting – Handheld E.0: Information Elements and Events CPI CPICH CQI CRC C-RNTI CS CSD CW DCCH DCD DCH DGPS DL DN DNS DPCCH DPCH DR DRC DRX DSC DSC DSCH DTX DVB-H E-AGCH EARFCN ECP E-DCH EDGE E-DPCCH E-DPDCH EFR EGPRS E-HICH EIRP EMM EPS E-RGCH ESM ESN ESS Cell Parameter Identity Common Pilot Channel Channel Quality Indicator Cyclic Redundancy Check Cell Radio Network Temporary Identity Coding Scheme Circuit-Switched Data Continuous Wave Digital Control Channel Downlink Channel Descriptor Dedicated Channel Differential GPS Downlink Detected Neighbor Domain Name System (Service. Appendix A.(Enhanced) Transport Format Combination Indicator 1x Evolution-Data Optimized Enhanced Variable Rate Codec Fast Associated Control Channel Forward Access Channel Fundamental Channel Frame Erasure Rate Forward Link Forward Power Control Full Rate Fixed Wireless Terminal Generic Access Circuit Switched Resources Generic Access Network Generic Access Network Controller Generic Access Resource Control Guaranteed Bit Rate GSM EDGE Radio Access Network Gateway GPRS Support Node GPRS Mobility Management General Packet Radio Service Global Positioning System GPRS Radio Resource Global System for Mobile Communication Hybrid Automatic Repeat Request Handover Half Rate HS-DSCH Radio Network Temporary Identity High Speed Circuit-Switched Data High Speed Downlink Packet Access High Speed Downlink Shared Channel Hopping Sequence Number High Speed Packet Access High Speed Physical Downlink Shared Channel High Speed Shared Control Channel High Speed Uplink Packet Access Information Element International Mobile Equipment Identity International Mobile Subscriber Identity Internet Protocol Internet Protocol Control Protocol Interference Signal Code Power LZT 138 0375 R1A 265 .(Enhanced) Transport Format Combination E. Abbreviations E-TFC E-TFCI EV-DO (1xEV-DO) EVRC FACCH FACH FCH FER FL FPC FR FWT GA-CSR GAN GANC GA-RC GBR GERAN GGSN GMM GPRS GPS GRR GSM HARQ HO HR H-RNTI HSCSD HSDPA HS-DSCH HSN HSPA HS-PDSCH HS-SCCH HSUPA IE IMEI IMSI IP IPCP ISCP E. 0: Information Elements and Events JPEG KML KPI LA LAC LAT LCP LLC LON LTE LUT M2M MAC MBR MCC MCS MD5 MDM MFER MIMO MIN MM MMS MMSC MN MNC MO MOS MRU MS MSM MSTR MT MTR MTU MuxPDU NAS NBDS NBNS NCC NDIS NID Joint Photographic Expert Group Keyhole Markup Language Key Performance Indicator Location Area Location Area Code Latitude Link Control Protocol Logical Link Control Longitude Long Term Evolution Location Update Type Mobile To Mobile Medium Access Control Maximum Bit Rate Mobile Country Code Modulation Coding Scheme Message-Digest algorithm 5 Mobile Diagnostic Monitor Frame Error Rate after MPE-FEC decoding Multiple Input Multiple Output Mobile Identity Number Mobility Management Multimedia Messaging Service MMS Center Monitored Neighbor Mobile Network Code Mobile-originated Mean Opinion Score Mobile Receiving Unit Mobile Station (may represent phone or scanner) Mobile Station Modem Mobile Station Time Reference Mobile-terminated Mobile Traffic Recording Mobile Test Unit Multiplex Sublayer Protocol Data Unit Non-Access Stratum NetBIOS Datagram Service NetBIOS Name Service Network Colour Code Network Driver Interface Specification Network Identification 266 .TEMS Investigation 11. Appendix A. Abbreviations NMEA NMO NSAPI NV OFDM OVHD PA PACA PAP PBCCH PCCCH P-CCPCH PCH PCI PCIG PCS PDCH PDN PDP PDSCH PDU PER PESQ PI PID PLMN PMI PN POP3 PPCH PPP PPS P-SCH PSTN P-TMSI PUSCH QAM QCELP QCI QOF QoS QPSK National Marine Electronics Association Network Mode of Operation Network Service Access Point Identifier Non Volatile Orthogonal Frequency-Division Multiplexing Overhead Power Amplifier Priority Access and Channel Assignment Password Authentication Protocol Packet Broadcast Control Channel Packet Common Control Channel Primary Common Control Physical Channel Paging Channel Physical layer Cell Identity Physical layer Cell Identity Group Personal Communications Service Packet Data Channel Packet Data Network Packet Data Protocol Physical Downlink Shared Channel Protocol Data Unit Packet Error Rate Perceptual Evaluation of Speech Quality Preamble Index Product ID Public Land Mobile Network Precoding Matrix Indicator Pseudo Noise Post Office Protocol version 3 Packet Paging Channel Point-to-Point Protocol Precise Positioning Service Primary Synchronisation Channel Public Switched Telephone Network Packet Temporary Mobile Subscriber Identity Physical Uplink Shared Channel Quadrature Amplitude Modulation Qualcomm Code Excited Linear Prediction Quality-of-service (QoS) Class Identifier Quasi-Orthogonal Function Quality of Service Quadrature Phase Shift Keying LZT 138 0375 R1A 267 . 0: Information Elements and Events RA RAB RAC RACH RAN RAS RAT RATI RB RI RL RLA RLC RLP RNC RP RPC RQ RR RRC RRI RS RSCP RSRP RSRQ RSSI RTC RTCP RTP RTSP SACCH SAN SAPI SC SCC SCH SCH SDCCH SDP SDU SEGW SF Routing Area Reverse Activity Bit Routing Area Code Random Access Channel Radio Access Network Remote Access Service Radio Access Technology Random Access Terminal Identifier Radio Bearer Rank Indication Reverse Link Received Level Average Radio Link Control Radio Link Protocol Radio Network Controller Received Power Reverse Power Control Received Quality Radio Resource (Management) Radio Resource Control Reverse Rate Indication Reference Signal Received Signal Code Power Reference Signal Received Power Reference Signal Received Quality Received Signal Strength Indicator Real Time Clock Real Time Control Protocol Real Time Transport Protocol Real Time Streaming Protocol Slow Associated Control Channel Serving/Active Set + Neighbors Service Access Point Identifier Scrambling Code Supplemental Code Channel Supplemental Channel (CDMA) Synchronisation Channel (UMTS) Standalone Dedicated Control Channel Session Description Protocol Signaling Data Unit Security Gateway Spreading Factor 268 .TEMS Investigation 11. Abbreviations SG SGSN SGW SHO SIB SID SID SIM SINR SIR SMS SMTP SMV SNDCP SNR SPS SQI SRU SS S-SCH SSID TA TAB TAC TB TBS TCA TCH TCP TDD TDMA TD-SCDMA TFI TIF TLLI TM TMSI TPC TS TSC TTI UARFCN Serving Grant Serving GPRS Support Node Security Gateway Soft Handover System Information Block Silence Descriptor (UMTS) System Identification (CDMA) Subscriber Identity Module Signal to Interference plus Noise Ratio Signal to Interference Ratio Short Message Service Simple Mail Transfer Protocol Selectable Mode Vocoder Subnetwork Dependent Convergence Protocol Signal to Noise Ratio Standard Positioning Service Speech Quality Index Scanning Receiver Unit Signal Strength Secondary Synchronisation Channel Service Set Identifier Timing Advance (umbrella term for various MapInfo file types) Tracking Area Code Transport Block Transport Block Size Traffic Channel Assignment Traffic Channel Transmission Control Protocol Time Division Duplex Time Division Multiple Access Time Division Synchronous Code Division Multiple Access Temporary Flow Id Tag Image File Temporary Logical Link Identifier Transparent Mode Temporary Mobile Subscriber Identity Transmit Power Control Timeslot Training Sequence Code Transmission Time Interval UMTS Absolute Radio Frequency Channel Number LZT 138 0375 R1A 269 .Appendix A. 0: Information Elements and Events UATI UCD UCS UDP UE UL UM UMA UMTS UpPCH URA URI U-RNTI USB UTF UTM UTRAN VID VMR-WB VSQI VTQI WAP WCDMA WiMAX WLAN WSP XML Unicast Access Terminal Identifier Uplink Channel Descriptor Universal Character Set User Datagram Protocol User Equipment Uplink Unacknowledged Mode Unlicensed Mobile Access Universal Mobile Telecommunications System Uplink Pilot Channel UTRAN Registration Area Uniform Resource Identifier UTRAN Radio Network Temporary Identity Universal Serial Bus UCS Transformation Format Universal Transverse Mercator UMTS Terrestrial Radio Access Network Vendor ID Variable Multi Rate Wideband Video Streaming Quality Index Video Telephony Quality Index Wireless Application Protocol Wideband Code Division Multiple Access Worldwide Interoperability for Microwave Access Wireless Local Area Network Wireless Session Protocol Extensible Markup Language 270 .TEMS Investigation 11. preconfigured 257 CDMA 257 GSM 257 LTE 258 TD-SCDMA 259 WCDMA 259 WiMAX 260 C C/A window (GSM) 242 C/I window (GSM) 242 Call Analysis window 250 Candidate Set window (CDMA) 240 CDMA Bar Chart 257 CDMA Data Line Chart 253 CDMA Line Chart 253 Cell Reselection window (TD-SCDMA) 246 Channel RSSI Bar Chart (WiMAX) 260 Channel RSSI Line Chart (WiMAX) 256 Compact Adjacent Bar Chart (GSM) 258 contents of Information Elements and Events 1 CPI Scan bar charts (TD-SCDMA) 259 CPI Scan line charts (TD-SCDMA) 255 LZT 138 0375 R1A 271 .Index Index A A/C/N Sets window (CDMA) 240 abbreviations 263 Active Set window (CDMA) 240 Adjacent Bar Chart (GSM) 257 AMR Call Average window (GSM) 242 AMR Cell Average window (GSM) 242 AMR Codecs window (WCDMA) 248 AMR Settings window (GSM) 243 AMR window (GSM) 243 B bar charts. listing of predefined 210 CDMA 231 data service testing 237 general events 210 GSM/WCDMA/LTE/TD-SCDMA 212 F Finger Info window (CDMA) 240 Finger Info windows (WCDMA) 248 G GAN Status window (GSM) 243 GAN WLAN Quality Line Chart 253 272 .TEMS Investigation 11. 241. 245.0: Information Elements and Events CPICH Best UARFCN Data window (WCDMA) 248 CPICH Data window (WCDMA) 248 CPICH Scan bar charts (WCDMA) 260 CPICH Scan line charts (WCDMA) 255 Current Channel window (GSM) 243 Current Channel window (TD-SCDMA) 246 D Data Bytes Sent/Received window (CDMA) 239 Data Bytes Sent/Received window (GSM) 241 Data Reports window 251 data service testing information elements 187 Data Session window (common to all technologies) 239. 247 Data Throughput window (GSM) 241 Data Timeslots window (GSM) 241 DVB-H Analysis window (WCDMA) 247 DVB-H Stats Line Chart (WCDMA) 255 E EGPRS Line Chart 253 EGPRS Status window 241 Enhanced Power Scan Bar Chart (LTE) 258 Ericsson MTR Records window (GSM) 251 Error Reports window 251 EV-DO Forward Link Packets window 239 EV-DO Overview window 239 EV-DO Reverse Link Packets window 240 EV-DO Status window 240 Event Counter windows preconfigured 250 Events window 252 events. Index GPRS Line Chart 253 GPRS Status window 241 GSM information elements 5 GSM Line Chart 253 GSM Neighbors window (WCDMA) 248 GSM uplink information elements 191 H Handover window (WCDMA) 249 Hopping Channels window (GSM) 243 HS UL E-TFC Accumulated Sony Ericsson (WCDMA bar chart) 259 HS UL E-TFC Current Sony Ericsson (WCDMA bar chart) 259 HS UL Output Power Line Chart 255 HS UL Transmission Distribution Accumulated Sony Ericsson (WCDMA bar chart) 259 HS UL Transmission Distribution Current Sony Ericsson (WCDMA bar chart) 259 HSCSD Throughput window 241 HSDPA Analysis MIMO window 247 HSDPA Analysis Per Process window 247 HSDPA Analysis window (TD-SCDMA) 245 HSDPA Analysis window (WCDMA) 247 HSDPA MIMO Primary Transport Block Size Bar Chart 259 HSDPA MIMO Secondary Transport Block Size Bar Chart 260 HSDPA PDSCH Codes Bar Chart 260 HSDPA Transport Block Size Bar Chart 260 HSUPA Analysis window 247 I iDEN Line Chart 254 iDEN Messages window 251 iDEN Status window 244 information elements 4 CDMA 146 CDMA category 3 Data category 3 data service testing 187 Full and Sub values 7 GSM 5 GSM category 2 GSM uplink (MTR) 191 LZT 138 0375 R1A 273 . TEMS Investigation 11. preconfigured 253 CDMA 253 GSM 253 iDEN 254 LTE 254 TD-SCDMA 255 WCDMA 255 WiMAX 256 LTE information elements 116 M MAC Throughput Line Chart (LTE) 254 Map windows. preconfigured 250 analysis 250 GSM uplink data 251 iDEN 251 signaling 251 Missing Neighbor window 250 274 . preconfigured 261 message windows.0: Information Elements and Events GSM Uplink category 3 LTE 116 LTE category 2 support for in phones and scanners 194 CDMA 194 GSM 195 LTE 208 WCDMA 202 TD-SCDMA 130 TD-SCDMA category 2 WCDMA 59 WCDMA category 2 WiMAX 179 WiMAX category 3 Interference Bar Chart (GSM) 258 Interference Line Chart (GSM) 254 Inter-Freq Meas Ctrl Events window (WCDMA) 249 Inter-RAT Meas Ctrl Events window (WCDMA) 249 Intra-Freq Meas Ctrl Events window (WCDMA) 249 IP Analysis window 252 L Layer 2 Messages window 252 Layer 3 Messages window 252 line charts. plain-text decoding of 209 Modified MS Behavior window (GSM) 243 Modified MS Behavior window (WCDMA) 249 MTR information elements 191 N Narrowband Interference Scan Bar Chart (CDMA) 257 Neighbor Set window (CDMA) 240 Network Search window (WCDMA) 248 P PDP Context window (GSM) 241 PDP Context window (TD-SCDMA) 245 PDP Context window (WCDMA) 247 PN Scan bar charts (CDMA) 257 PN Scan line charts (CDMA) 253 Polluters Bar Chart (CDMA) 257 Preamble Power Group Bar Chart (WiMAX) 260 presentation windows overview of preconfigured 239 templates for 261 R RACH Analysis window (WCDMA) 249 Radio Parameters Bar Chart (WCDMA) 260 Radio Parameters Parallel Bar Chart (WCDMA) 260 Radio Parameters window (CDMA) 240 Radio Parameters window (GSM) 243 Radio Parameters window (TD-SCDMA) 246 Radio Parameters window (WCDMA) 249 Radio Quality Bar Chart (GSM) 258 RAS 187 Remote Access Service (RAS) 187 RLC/MAC header data 42 RS bar charts (LTE) 258 RS line charts (LTE) 254 RSSI Scan Bar Chart (CDMA) 257 RSSI Scan Bar Chart (GSM) 258 RSSI Scan Bar Chart (LTE) 258 RSSI Scan Bar Chart (TD-SCDMA) 259 RSSI Scan Bar Chart (WCDMA) 260 RSSI Scan Bar Chart (WiMAX) 260 RSSI Scan Line Chart (LTE) 254 LZT 138 0375 R1A 275 .Index Mode Reports window 252 mode reports. preconfigured 239 CDMA 239 data service testing 239 GSM 241 data service testing 241 interference 242 uplink data 242 iDEN 244 LTE 244 TD-SCDMA 245 data service testing 245 scanning 245 WCDMA 247 data service testing 247 276 . 249 status windows.0: Information Elements and Events RSSI Scan Line Chart (TD-SCDMA) 255 RSSI Scan Line Chart (WiMAX) 256 S Scanned Cells window (LTE) 244 Scanned Cells window (TD-SCDMA) 245 Scanned Preamble Index window (WiMAX) 250 SCH Timeslot Scan Bar Chart (WCDMA) 260 Segment Power Group Bar Chart (WiMAX) 260 Serving + Neighbor window (TD-SCDMA) 246 Serving + Neighbors By Band window (GSM) 244 Serving + Neighbors window (GSM) 243 Serving Cell Line Chart (LTE) 254 Serving window (CDMA) 240 Serving/Active Set + Neighbors window (WCDMA) 249 Serving/Neighbor Cell Bar Chart (LTE) 258 Session Status window 250 signal power notes on quantities denoting 59 Sony Ericsson UEs line chart for transport channel throughput 255 Spectrum Analysis Bar Chart (CDMA) 257 Spectrum Analysis Bar Chart (GSM) 258 Spectrum Analysis Bar Chart (LTE) 258 Spectrum Analysis Bar Chart (WCDMA) 260 Spectrum Analysis Bar Chart (WiMAX) 260 Spectrum Analysis Uplink Bar Chart (WCDMA) 260 Speech Quality window (CDMA) 240 Speech Quality window (GSM/WCDMA) 244.TEMS Investigation 11. 248 WiMAX 250 Strongest CINR Bar Chart (WiMAX) 261 Strongest Preamble Power Bar Chart (WiMAX) 261 Strongest Preamble Power Group Bar Chart (WiMAX) 261 Strongest Scanned PN Bar Chart (CDMA) 257 Strongest Segment Power (Cha Sort) Bar Chart (WiMAX) 261 Strongest Segment Power (Segment Pwr Sort) Bar Chart (WiMAX) 261 Synch Channel Data window (WCDMA) 248 T TD-SCDMA HS/GSM Data Line Chart 255 TD-SCDMA information elements 130 TD-SCDMA Line Chart 255 TD-SCDMA Physical Channel Monitor 246 TD-SCDMA RLC Data Line Chart 255 TD-SCDMA/GSM Line Chart 255 Timeslots window (TD-SCDMA) 246 TPC per Cell mode report (Sony Ericsson) 209 Transport Channels window (TD-SCDMA) 246 Transport Channels window (WCDMA) 250 Trsp Ch Throughput Line Chart -. 99/GSM Data Line Chart 256 WCDMA RLC Data Line Chart 256 WCDMA Two Antennas Line Chart 256 WCDMA/GSM Line Chart 256 Weakest CINR Bar Chart (WiMAX) 261 Weakest Preamble Power Bar Chart (WiMAX) 261 LZT 138 0375 R1A 277 .Index scanning 244. 256 W WCDMA Handover Analysis window 250 WCDMA HSPA/GSM Data Line Chart 256 WCDMA information elements 59 WCDMA Line Chart 256 WCDMA Rel.Sony Ericsson (WCDMA) 255 U Uplink Line Chart (GSM) 254 Uplink Neighbors window (GSM) 242 Uplink Radio Parameters window (GSM) 242 Uplink Serving Cell window (GSM) 242 V Video Streaming Line Chart (GSM/WCDMA) 254. TEMS Investigation 11.0: Information Elements and Events WiMAX information elements 179 Winsock 187 278 . . TEMS Optimization Solutions – Making Wireless Better. the TEMS portfolio helps operators maximize their Quality of Service and get the most out of their network investment. For every stage of a wireless network’s life cycle and supporting all major technologies. and success. .TEMS™ Optimization Solutions – the number one choice for operators worldwide. The experience and technological leadership of TEMS gives network operators the strong partnership they need and a commitment to quality. accuracy. 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