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Content for
TR 38.828
Word version: 16.1.0
1…
2…
A…
2
References
3
Definitions, symbols and abbreviations
3.1
Definitions
3.2
Symbols
3.3
Abbreviations
4
Background
4.1
General
4.2
WID description
4.3
Dynamic TDD adjacent interference scenarios
4.4
BS-BS interference for zero grid shift scenarios
5
Co-existence analysis
5.1
Scenarios
5.2
Simulation assumptions
5.3
Simulation results
6
Summary and recommendations
6.1
Zero grid shift
6.2
Summary of results for 100% grid shift
6.3
Recommendations
2
References
3
Definitions, symbols and abbreviations
Word‑p. 9
3.1
Definitions
3.2
Symbols
3.3
Abbreviations
4
Background
Word‑p. 10
4.1
General
4.2
WID description
4.2.1
Justification
4.2.2
Objective
Word‑p. 11
4.3
Dynamic TDD adjacent interference scenarios
Word‑p. 12
4.3.1
General
4.3.2
Interference scenarios that occur for both synchronized and unsynchronized TDD (including CLI)
4.3.3
Additional interference scenarios that occur for unsynchronized TDD (including dynamic TDD and CLI)
Word‑p. 13
4.4
BS-BS interference for zero grid shift scenarios
Word‑p. 14
5
Co-existence analysis
5.1
Scenarios
5.1.1
FR1
5.1.2
FR2
Word‑p. 16
5.2
Simulation assumptions
Word‑p. 17
5.2.1
FR1
5.2.1.1
Network layout model
5.2.1.1.1
Urban macro
5.2.1.1.2
Indoor
Word‑p. 18
5.2.1.2
ACIR
Word‑p. 19
5.2.1.3
UE distribution
5.2.1.4
Other simulation parameters
5.2.1.5
Antenna configuration
Word‑p. 20
5.2.1.5.1
Urban macro scenario
5.2.1.5.2
Indoor scenario
5.2.1.5.3
UE antenna element pattern
5.2.2
FR2
Word‑p. 21
5.2.2.1
Network layout model
5.2.2.1.1
Urban macro
5.2.2.1.2
Dense urban
5.2.2.1.3
Indoor
Word‑p. 22
5.2.2.2
ACLR and ACS
5.2.2.3
UE distribution
Word‑p. 23
5.2.2.3.1
Urban Macro (Macro-to-Macro)
5.2.2.3.2
Dense Urban (Micro-to-Micro)
5.2.2.3.3
Indoor-to-Indoor and Indoor-to-Macro
5.2.2.4
Other simulation parameters
5.2.2.5
Antenna configuration
Word‑p. 24
5.2.2.5.1
Urban macro scenario
5.2.2.5.2
Dense urban scenario
Word‑p. 25
5.2.2.5.3
Indoor scenario
5.2.2.5.4
UE antenna element pattern
Word‑p. 26
5.2.3
Common assumptions
5.2.3.1
Propagation model
5.2.3.2
LOS model
Word‑p. 27
5.2.3.3
O-to-I penetration loss
Word‑p. 28
5.2.3.4
Transmission power control model
Word‑p. 29
5.2.3.5
Received signal power model
5.2.3.6
Evaluation metric
Word‑p. 30
5.2.3.7
Antenna modelling
5.2.3.8
Simulation description
5.3
Simulation results
Word‑p. 31
5.3.1
General
5.3.2
Simulation limitations
5.3.3
FR1
Word‑p. 32
5.3.3.1
Scenario 1: 4 GHz Macro → Macro (DL)
5.3.3.2
Scenario 2: 4 GHz Macro → Macro (UL)
Word‑p. 33
5.3.3.3
Scenario 3: 4 GHz Macro → Indoor (DL)
5.3.3.4
Scenario 4: 4 GHz Macro → Indoor (UL)
Word‑p. 34
5.3.3.5
Scenario 5: 4 GHz Indoor → Macro (DL)
5.3.3.6
Scenario 6: 4 GHz Indoor → Macro (UL)
Word‑p. 35
5.3.3.7
Scenario 7: 4 GHz Indoor → Indoor (DL)
5.3.3.8
Scenario 8: 4 GHz Indoor → Indoor (UL)
Word‑p. 36
5.3.4
FR2
Word‑p. 37
5.3.4.1
Scenario 9: 30 GHz Macro → Macro (DL)
5.3.4.2
Scenario 10: 30 GHz Macro → Macro (UL)
5.3.4.3
Scenario 11: 30 GHz Micro → Micro (DL)
Word‑p. 38
5.3.4.4
Scenario 12: 30 GHz Micro → Micro (UL)
5.3.4.5
Scenario 13: 30 GHz Indoor → Macro (DL)
5.3.4.6
Scenario 14: 30 GHz Indoor → Macro (UL)
Word‑p. 39
5.3.4.7
Scenario 15: 30 GHz Indoor → Indoor (DL)
5.3.4.8
Scenario 16: 30 GHz Indoor → Indoor (UL)
Word‑p. 40
6
Summary and recommendations
6.1
Zero grid shift
6.2
Summary of results for 100% grid shift
6.2.1
FR1
6.2.1.1
Macro-to-Macro scenario
6.2.1.2
Indoor-to-Macro scenario
Word‑p. 41
6.2.1.3
Indoor-to-Indoor scenario
6.2.1.4
Macro-to-Indoor scenario
6.2.2
FR2
6.2.2.1
Macro-to-Macro scenario
6.2.2.2
Indoor-to-Macro scenario
6.2.2.3
Indoor-to-Indoor scenario
6.2.2.4
Micro-to-Micro scenario
6.3
Recommendations
Word‑p. 42
6.3.1
FR1
6.3.1.1
Macro-to-Macro scenario
6.3.1.2
Indoor scenarios (Indoor-to-Macro and Indoor-to-Indoor)
6.3.2
FR2
6.3.2.1
Macro-to-Macro scenario
6.3.2.2
Indoor scenarios (Indoor-to-Macro and Indoor-to-Indoor)
6.3.2.3
Micro-to-Micro scenario