Content for TR 45.050 Word version: 18.0.0
ZF Machine-type-communication (MTC) deployment, including EC-GSM-IoT, in a reduced BCCH spectrum allocation
ZF.1 Common simulation assumption framework
ZF.2 Simulator for Network synchronization evaluation
ZF.3 Simulator for Common control channel evaluation
ZF.4 Simulator for Data traffic and control channel performance
ZF.5 Results for Network synchronization evaluation
ZF.6 Results for Common control channel evaluation
ZF.7 Results for Data traffic and control channel evaluation
ZF.8 Traffic model for legacy GPRS MTC
ZF.9 Simulator model for wanted signal level and SINR estimation error
$ Change history
ZF Machine-type-communication (MTC) deployment, including EC-GSM-IoT, in a reduced BCCH spectrum allocation p. 358
ZF.1 Common simulation assumption framework p. 358
ZF.2 Simulator for Network synchronization evaluation p. 360
ZF.2.1 Tdoc reference p. 360
ZF.2.2 Introduction p. 360
ZF.2.3 Simulator description p. 361
ZF.2.3.1 General p. 361
ZF.2.3.2 Network configuration and plan p. 361
ZF.2.3.3 Mapping and timing of logical channels p. 362
ZF.2.3.4 Relevant range of coupling loss p. 362
ZF.2.3.5 Realistic interference model p. 362
ZF.2.3.6 Receiver model p. 365
ZF.2.4 Discussion and conclusions p. 366
ZF.3 Simulator for Common control channel evaluation p. 366
ZF.3.1 Tdoc reference p. 366
ZF.3.2 General p. 367
ZF.3.3 Minimizing execution time p. 367
ZF.3.3.1 General p. 367
ZF.3.3.2 Interferers p. 367
ZF.3.3.2.1 Interferer types p. 367
ZF.3.3.2.2 Minimum number of interferers p. 367
ZF.3.3.2.3 Requirement on modeled energy level p. 368
ZF.3.3.2.4 Conservation of energy p. 368
ZF.3.3.3 Oversampling p. 368
ZF.3.3.4 Pre-generation of bursts p. 368
ZF.3.3.5 Verification p. 368
ZF.4 Simulator for Data traffic and control channel performance p. 370
ZF.4.1 Tdoc reference p. 370
ZF.4.2 Model p. 370
ZF.4.2.1 General p. 370
ZF.4.2.2 Mapping tables p. 371
ZF.4.2.2.1 First stage mapping (SINR → BER) p. 371
ZF.4.2.2.2 Second stage mapping (BER → BLEP) p. 371
ZF.4.2.2.3 Mapping choice p. 371
ZF.4.2.3 SINR handling p. 372
ZF.4.2.3.1 Blind repetition p. 372
ZF.4.2.3.2 MRC (uplink only) p. 373
ZF.4.3 Verification p. 373
ZF.4.3.1 Sensitivity p. 373
ZF.4.3.2 Multi-interference (DTS-2) p. 374
ZF.5 Results for Network synchronization evaluation p. 374
ZF.5.1 GPRS/EGPRS p. 374
ZF.5.1.0 Tdoc reference p. 374
ZF.5.1.1 Simulator configuration p. 375
ZF.5.1.2 Results p. 375
ZF.5.1.3 Discussion and conclusions p. 378
ZF.5.2 EC-GSM-IoT p. 378
ZF.5.2.1 Tdoc reference p. 378
ZF.5.2.2 Simulator configuration p. 378
ZF.5.2.3 Results p. 378
ZF.5.2.4 Conclusions p. 381
ZF.6 Results for Common control channel evaluation p. 381
ZF.6.1 GPRS/EGPRS p. 381
ZF.6.1.1 Tdoc reference p. 381
ZF.6.1.2 Assumptions p. 381
ZF.6.1.2.1 General p. 381
ZF.6.1.2.2 Network synchronization p. 381
ZF.6.1.2.3 BCCH Power Savings p. 381
ZF.6.1.3.4 Frequency planning p. 381
ZF.6.1.4 Simulations p. 382
ZF.6.1.5 Results p. 382
ZF.6.1.5.1 Resource Usage p. 382
ZF.6.1.5.2 Common control channel delay p. 383
ZF.6.1.5.3 Failed Attempts p. 383
ZF.6.1.6 Discussion p. 383
ZF.6.1.7 Conclusions p. 383
ZF.6.2 EC-GSM-IoT p. 383
ZF.6.2.1 Tdoc reference p. 383
ZF.6.2.2 Assumptions p. 384
ZF.6.2.2.1 Link model p. 384
ZF.6.2.2.2 Blind transmissions p. 384
ZF.6.2.2.3 Network synchronization p. 384
ZF.6.2.2.4 Coverage class adaptation p. 384
ZF.6.2.2.5 BCCH Power Savings p. 384
ZF.6.2.2.6 Frequency planning p. 384
ZF.6.2.3 Simulations p. 384
ZF.6.2.4 Results p. 385
ZF.6.2.4.1 General p. 385
ZF.6.2.4.2 Resource Usage p. 385
ZF.6.2.4.3 Common control channel delay p. 387
ZF.6.2.4.4 Failed Attempts p. 387
ZF.6.2.4.5 Coverage class distribution p. 387
ZF.6.2.5 Discussion p. 388
ZF.6.2.6 Conclusions p. 388
ZF.7 Results for Data traffic and control channel evaluation p. 388
ZF.7.1 GPRS/EGPRS p. 388
ZF.7.1.1 Tdoc reference p. 388
ZF.7.1.2 Assumptions p. 388
ZF.7.1.2.1 Traffic generation p. 388
ZF.7.1.2.2 RACH interference p. 388
ZF.7.1.2.3 BCCH Power Savings p. 389
ZF.7.1.3 Simulations p. 389
ZF.7.1.3.1 Simulation assumptions p. 389
ZF.7.1.3.1.1 System parameters p. 390
ZF.7.1.3.1.2 Cell selection and coding scheme selection p. 390
ZF.7.1.3.1.3 Control signaling p. 390
ZF.7.1.3.1.4 Simulated scenarios p. 391
ZF.7.1.3.2 Results p. 391
ZF.7.1.4 Discussion and conclusions p. 393
ZF.7.2 EC-GSM-IoT p. 393
ZF.7.2.1 Assumptions p. 393
ZF.7.2.1.1 Traffic generation p. 393
ZF.7.2.1.2 EC-RACH interference p. 394
ZF.7.2.1.3 BCCH Power Savings p. 394
ZF.7.2.1.4 Uplink Power Backoff p. 394
ZF.7.2.2 Simulations p. 394
ZF.7.2.2.1 Simulation assumptions p. 394
ZF.7.2.2.1.1 System parameters p. 395
ZF.7.2.2.1.2 Cell selection and uplink coverage class selection p. 395
ZF.7.2.2.1.3 Downlink coverage class selection and coding scheme selection p. 396
ZF.7.2.2.1.4 Control signaling p. 396
ZF.7.2.2.1.5 Simulated scenarios p. 396
ZF.7.2.2.2 Results p. 396
ZF.7.2.2.2.1 TS Usage p. 397
ZF.7.2.2.2.2 Latency of MAR periodic reports p. 398
ZF.7.2.2.2.3 Latency of Downlink Application Ack p. 398
ZF.7.2.2.2.4 Failed Attempts p. 398
ZF.7.2.2.2.5 Capacity p. 398
ZF.7.2.2.3 DL and UL Coverage Class Distribution p. 399
ZF.7.2.3 Discussion and conclusions p. 400
ZF.7.2.3.1 Impact from frequency re-use p. 400
ZF.7.2.3.2 SINR vs carrier based measurements p. 400
ZF.7.2.3.2.1 General p. 400
ZF.7.2.3.2.2 Coverage class distribution p. 400
ZF.7.2.3.2.3 BLER p. 401
ZF.7.2.4 Conclusion p. 402
ZF.8 Traffic model for legacy GPRS MTC p. 402
ZF.8.1 Tdoc reference p. 402
ZF.8.2 Legacy GRPS MTC uses cases and scenarios p. 402
ZF.8.3 Aggregated traffic model of MTC over Legacy GPRS p. 403
ZF.9 Simulator model for wanted signal level and SINR estimation error p. 404
ZF.9.1 Tdoc reference p. 404
ZF.9.2 Model p. 404
ZF.9.3 Noise-limited case p. 405
ZF.9.4 Interference-limited case p. 406
ZF.9.5 Discussion and conclusions p. 407
$ Change history p. 408
