Content for TR 36.942 Word version: 16.0.0
2 References
3 Definitions, symbols and abbreviations
4 General assumptions
5 Methodology description
6 System scenarios
7 Results
8 Rationales for co-existence requirements
9 Deployment aspects
10 Multi-carrier BS requirements
11 Rationale for unwanted emission specifications
12 LTE-Advanced co-existence
A Link Level Performance Model
B Smart Antenna Model for UTRA 1.28 Mcps TDD
C Simulation assumptions for LTE-A coexistence
$ Change History
2 References
3 Definitions, symbols and abbreviations Word‑p. 8
4 General assumptions Word‑p. 9
4.1 Interference scenarios Word‑p. 10
4.2 Antenna Models
4.2.1 BS antennas
4.2.1.1 BS antenna radiation pattern
4.2.1.2 BS antenna heights and antenna gains for macro cells Word‑p. 11
4.2.2 UE antenna
4.2.3 MIMO antenna Characteristics
4.3 Cell definitions
4.4 Cell layouts Word‑p. 12
4.5 Propagation conditions and channel models Word‑p. 14
4.5.1 Received signal
4.5.2 Macro cell propagation model - Urban Area
4.5.3 Macro cell propagation model - Rural Area Word‑p. 15
4.6 Base-station model
4.7 UE model Word‑p. 17
4.8 RRM models Word‑p. 18
4.9 Link level simulation assumptions
4.10 System simulation assumptions
5 Methodology description
5.1 Methodology for co-existence simulations
5.1.1 Simulation assumptions for co-existence simulations
5.1.1.1 Scheduler
5.1.1.2 Simulated services Word‑p. 19
5.1.1.3 ACIR value and granularity
5.1.1.4.1 Uplink Asymmetrical Bandwidths ACIR (Aggressor with larger bandwidth)
5.1.1.4.2 Uplink Asymmetrical Bandwidths ACIR (Aggressor with smaller bandwidth) Word‑p. 22
5.1.1.4 Frequency re-use and interference mitigation schemes for E-UTRA
5.1.1.5 CQI estimation Word‑p. 23
5.1.1.6 Power control modelling for E-UTRA and 3.84 Mcps TDD UTRA
5.1.1.7 SIR target requirements for simulated services
5.1.1.8 Number of required snapshots
5.1.1.9 Simulation output
5.1.2 Simulation description Word‑p. 24
6 System scenarios Word‑p. 26
7 Results
7.1 Radio reception and transmission
7.1.1 FDD coexistence simulation results
7.1.1.1 ACIR downlink 5MHz E-UTRA interferer - UTRA victim
7.1.1.2 ACIR downlink 10MHz E-UTRA interferer - 10MHz E-UTRA victim Word‑p. 27
7.1.1.3 ACIR uplink 5MHz E-UTRA interferer - UTRA victim Word‑p. 29
7.1.1.4 ACIR uplink 10MHz E-UTRA interferer - 10MHz E-UTRA victim Word‑p. 31
7.1.2 TDD coexistence simulation results Word‑p. 34
7.1.2.1 ACIR downlink 5MHz E-UTRA interferer - UTRA 3.84 Mcps TDD victim
7.1.2.2 ACIR downlink 10MHz E-UTRA interferer - 10MHz E-UTRA TDD victim Word‑p. 36
7.1.2.3 ACIR downlink 1.6 MHz E-UTRA interferer - UTRA 1.28 Mcps TDD victim Word‑p. 38
7.1.2.4 ACIR uplink 5MHz E-UTRA interferer - UTRA 3.84 Mcps TDD victim Word‑p. 41
7.1.2.5 ACIR uplink 10MHz E-UTRA interferer - 10MHz E-UTRA TDD victim Word‑p. 43
7.1.2.6 ACIR uplink 10MHz E-UTRA interferer - 10MHz E-UTRA TDD victim (LCR frame structure based) Word‑p. 45
7.1.2.7 ACIR downlink 10MHz E-UTRA interferer - 10MHz E-UTRA TDD victim (LCR frame structure based) Word‑p. 46
7.1.3 Additional coexistence simulation results Word‑p. 48
7.1.3.1 ACIR downlink E-UTRA interferer - GSM victim
7.1.3.2 ACIR uplink E-UTRA interferer - GSM victim Word‑p. 50
7.1.3.3 Asymmetric coexistence 20 MHz and 5 MHz E-UTRA Word‑p. 51
7.1.3.4 Impact of cell range and simulation frequency on ACIR Word‑p. 53
7.1.3.5 Uplink Asymmetric coexistence TDD E-UTRA to TDD E-UTRA Word‑p. 54
7.1.4 Base station blocking simulation results Word‑p. 56
7.2 RRM Word‑p. 58
8 Rationales for co-existence requirements
9 Deployment aspects
10 Multi-carrier BS requirements Word‑p. 62
10.1 Unwanted emission requirements for multi-carrier BS
10.1.1 General
10.1.2 Multi-carrier BS of different E-UTRA channel bandwidths Word‑p. 63
10.1.3 Multi-carrier BS of E-UTRA and UTRA
10.2 Receiver requirements for multi-carrier BS Word‑p. 64
11 Rationale for unwanted emission specifications
11.1 Out of band Emissions
11.1.1 Operating band unwanted emission requirements for E-UTRA BS (spectrum emission mask)
11.1.2 ACLR requirements for E-UTRA BS Word‑p. 67
11.2 Spurious emissions Word‑p. 69
12 LTE-Advanced co-existence Word‑p. 71
12.1 Methodology and simulation assumptions for co-existence simulations
12.1.1 Simulation scenarios
12.1.2 Number of UEs per sub-frame
12.1.3 ACIR model Word‑p. 72
12.1.4 Uplink power control Word‑p. 76
12.2 Results Word‑p. 77
12.2.1 Radio reception and transmission
12.2.1.1 ACIR Downlink 40 MHz Advanced E-UTRA interferer - 10 MHz E-UTRA victim
12.2.1.2 ACIR Uplink 40 MHz Advanced E-UTRA interferer - 10 MHz E-UTRA victim Word‑p. 79
12.2.1.3 ACIR Downlink 40 MHz Advanced E-UTRA interferer - 40 MHz Advanced E-UTRA victim Word‑p. 83
12.2.1.4 ACIR Uplink 40 MHz Advanced E-UTRA interferer - 40 MHz Advanced E-UTRA victim Word‑p. 85
12.2.1.5 ACIR Downlink 40 MHz Advanced E-UTRA interferer - 5 MHz UTRA victim Word‑p. 89
12.2.1.6 ACIR Uplink 40 MHz Advanced E-UTRA interferer - 5 MHz UTRA victim Word‑p. 90
12.2.1.7 ACIR Downlink 40 MHz Advanced E-UTRA interferer - 1.6 MHz UTRA victim Word‑p. 92
12.2.1.8 ACIR Uplink 40 MHz Advanced E-UTRA interferer - 1.6 MHz UTRA victim Word‑p. 93
A Link Level Performance Model Word‑p. 96
A.1 Description
A.2 Modelling of Link Adaptation Word‑p. 98
A.3 UTRA 3.84 Mcps TDD HSDPA Link Level Performance Word‑p. 99
A.4 Link Level Performance for E-UTRA TDD (LCR TDD frame structure based) Word‑p. 101
B Smart Antenna Model for UTRA 1.28 Mcps TDD Word‑p. 103
C Simulation assumptions for LTE-A coexistence Word‑p. 107
$ Change History Word‑p. 109
