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Content for  TR 25.942  Word version:  16.0.0

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8 Results, implementation issues, and recommendations9 Additional Coexistence studies10 Antenna-to-Antenna Isolation11 Modulation accuracy12 UE active set size13 Informative and general purpose material14 Rationales for unwanted emission specifications15 Link Level performances$ Change history

 

8  Results, implementation issues, and recommendationsWord‑p. 55

8.1  FDD/FDD

8.1.1  ACIR for 21 dBm terminals

8.1.1.1  UL Speech (8 kbps): ACIR Intermediate macro to macro case

8.1.1.2  UL Speech (8 kbps): ACIR worst macro to macro caseWord‑p. 56

8.1.1.3  DL Speech (8 kbps): ACIR intermediate macro to macro case

8.1.1.4  DL Speech (8 Kbps): ACIR worst macro to macro caseWord‑p. 57

8.1.2  ACIR for 24 dBm terminalsWord‑p. 58

8.1.2.1  UL Speech (8 kbps): macro to macro

8.1.2.2  UL Data (144 kbps): macro to macroWord‑p. 59

8.1.3  BTS Receiver Blocking

8.1.3.1  Simulation Results for 1 Km cell radius

8.1.3.2  Simulation Results for 5 Km cell radiusWord‑p. 61

8.1.3.3  Simulation Results for macro-micro simulation scenario with 1 and 2 Km interfering macro cell radiusWord‑p. 64

8.1.4  Transmit intermodulation for the UE

8.1.5  Rational on test parameters for UE adjacent channel selectivityWord‑p. 65

8.1.5.1  Macro / Micro Scenario

8.1.5.2  OnOff CharacteristicWord‑p. 66

8.1.5.2.1  Macro-Micro (38dBm) with UE ACS OnOff CharacteristicWord‑p. 67
8.1.5.2.2  Macro- Single Micro (38dBm) with UE ACS OnOff Characteristic

8.1.5.3  UE ACS Mask CharacteristicWord‑p. 68

8.1.5.3.1  Macro-Micro with UE ACS Mask CharacteristicWord‑p. 69

8.2  FDD/TDD

8.2.1  Evaluation of the FDD/TDD interference

8.2.1.1  Simulation results

8.2.1.2  Summary and ConclusionsWord‑p. 73

8.2.2  Evaluation of FDD/TDD interference yielding relative capacity loss

8.2.2.1  Simulation results

8.3  TDD/TDD

8.3.1  Evaluation of the TDD/TDD interference

8.3.1.1  Simulation results

8.3.1.2  Summary and ConclusionsWord‑p. 76

8.3.2  Evaluation of FDD/TDD interference yielding relative capacity loss

8.3.2.1  Simulation results

8.3.3  ACIR

8.3.3.1  Synchronised operators

8.3.3.1.1  Speech (8 kbps): UL and DL macro to macro case
8.3.3.1.2  Comparison with the FDD/FDD coexistence analysis resultsWord‑p. 78

8.3.3.2  Non synchronised operatorsWord‑p. 79

8.4  Site engineering solutions for co-location of UTRA-FDD with UTRA-TDDWord‑p. 80

8.4.1  General

8.4.2  Interference Mechanism

8.4.2.1  Unwanted UTRA-TDD emissions

8.4.2.2  Blocking of UTRA-FDD BS receiver

8.4.3  Site engineering solutionsWord‑p. 81

8.4.3.1  Antenna installation

8.4.3.2  RF filters

8.4.3.2.1  UTRA-TDD base station transmitter filter
8.4.3.2.2  UTRA-FDD base station receiver filter

8.4.4  Scenario ExamplesWord‑p. 82

8.4.4.1  General

8.4.4.2  Scenario 1: Both TDD and FDD adjacent to 1920 MHz

8.4.4.3  Scenario 2a: TDD 1900-1915 MHz and FDD 1920-1940 MHz

8.4.4.4  Scenario 2b: TDD 1900-1920 MHz and FDD 1930-1980 MHzWord‑p. 83

9  Additional Coexistence studiesWord‑p. 84

9.1  Simulation results on TDD local area BS and FDD wide area BS coexistence

9.1.1  Introduction

9.1.2  Simulator DescriptionWord‑p. 85

9.1.2.1  Simulation procedure overview

9.1.2.2  System Scenario

9.1.2.3  Propagation ModelWord‑p. 86

9.1.2.3.1  TDD BS to TDD UE
9.1.2.3.2  FDD UE to FDD BS
9.1.2.3.3  TDD UE to FDD BS
9.1.2.3.4  FDD UE to TDD UE
9.1.2.3.5  FDD UE to TDD BS
9.1.2.3.6  TDD BS to FDD BS

9.1.2.4  Power ControlWord‑p. 87

9.1.2.5  Interference Modelling Methodology

9.1.3  Capacity Calculations

9.1.3.1  Calculation of Single Operator Capacity for TDD and FDD

9.1.3.2  Calculation of Multi Operator CapacityWord‑p. 88

9.1.3.3  Calculation of relative capacity loss

9.1.4  Simulation ParametersWord‑p. 89

9.1.5  Simulation results

9.1.6  ConclusionsWord‑p. 90

10  Antenna-to-Antenna Isolation

10.1  Rationale for MCL value for co-located base stations

10.2  Rationale for MCL value for operation of base stations in the same geographic areaWord‑p. 91

10.2.1  Wide Area and Geneal Purpose Base Station

10.2.2  Local Area Base Station

10.3  Rationale for MCL values for co-sited base stations of different classesWord‑p. 92

11  Modulation accuracyWord‑p. 93

11.1  Downlink modulation accuracy

11.1.1  Simulation Condition and Definition

11.1.2  Simulation Results

11.1.3  ConsiderationsWord‑p. 94

11.1.4  Conclusion

11.2  Uplink Modulation AccuracyWord‑p. 95

11.2.1  Value for Modulation Accuracy

11.2.2  References for minimum requirements

12  UE active set size

12.1  Introduction

12.2  Simulation assumptionsWord‑p. 96

12.3  Simulation results

12.3.1  Case 1: Three sectored, 65° antennaWord‑p. 97

12.3.2  Case 2: Three sectored, 90° antennaWord‑p. 98

12.3.3  Case 3: Three sectored, 65° antenna, bad planningWord‑p. 99

12.3.4  Cases 4: Standard omni scenarioWord‑p. 100

12.3.4.1  Case 4a: WINDOW_ADD = 5 dB

12.3.4.2  Case 4b: WINDOW_ADD = 3 dBWord‑p. 101

12.3.4.3  Case 4c: WINDOW_ADD = 7 dB

12.3.5  Case 5: Realistic mapWord‑p. 102

12.4  ConclusionsWord‑p. 103

13  Informative and general purpose material

13.1  CDMA definitions and equations

13.1.1  CDMA-related definitionsWord‑p. 104

13.1.2  CDMA equationsWord‑p. 105

13.1.2.1  BS Transmission Power

13.1.2.2  Rx Signal Strength for UE Not in Handoff (Static propagation conditions)

13.1.2.3  Rx Strength for UE Not in Handoff (Static propagation conditions)Word‑p. 106

13.1.2.4  Rx Signal Strength for UE in two-way HandoverWord‑p. 107

13.2  Amplitude statistics for TM1, TM5 and TM6

14  Rationales for unwanted emission specificationsWord‑p. 109

14.1  Out of band Emissions

14.1.1  Adjacent Channel Leakage Ratio

14.1.2  Spectrum mask

14.1.2.1  Spectrum mask for 43 dBm base station output power per carrier

14.1.2.2  Spectrum masks for other base station output powersWord‑p. 110

14.1.2.2.1  Output power > 43 dBm
14.1.2.2.2  39 dBm ≤ Output power ≤ 43 dBm
14.1.2.2.3  31 dBm ≤ Output power < 39 dBmWord‑p. 111
14.1.2.2.4  Output Power < 31 dBm
14.1.2.2.5  Frequency range

14.2  Spurious EmissionsWord‑p. 112

14.2.1  Mandatory requirements

14.2.2  Regional requirements

14.2.2.1  Co-existence with adjacent services

14.2.2.2  Co-existence with other systems

14.2.3  Background of Spurious emission limits (Category B)

14.2.3.1  Old Category B spurious emission limits (until 2006-12)Word‑p. 113

14.2.3.2  Implications for Evolved UTRA (Long Term Evolution in 3GPP)Word‑p. 115

14.2.3.3  New Category B spurious emission limits (after 2006-12)

14.2.3.4  Co-existence studies performed for UTRAWord‑p. 117

15  Link Level performancesWord‑p. 118

15.1  Propagation Models

15.1.1  Rationale for the choice of multipath fading Case 2

15.2  Simulation results for UE TDD performance testWord‑p. 119

15.2.1  Downlink Simulation assumptions

15.2.1.1  General

15.2.1.2  Additional downlink parameters

15.2.2  Downlink Simulation results and discussionWord‑p. 120

15.2.3  Uplink Simulation assumptionsWord‑p. 122

15.2.3.1  General

15.2.3.2  Additional uplink parameters

15.2.4  Uplink Simulation results and discussion

15.3  Simulation results for UE FDD performance testWord‑p. 123

15.3.1  BTFD performance simulation

15.3.1.1  Introduction

15.3.1.2  Assumption

15.3.1.3  Simulation resultsWord‑p. 125

15.3.1.4  ConclusionWord‑p. 128

15.4  Simulation results for compressed modeWord‑p. 129

15.4.1  Simulation assumptions for compressed mode by spreading factor reduction

15.4.2  Simulation results for compressed mode by spreading factor reductionWord‑p. 130

15.4.2.1  Summary of performance results

15.4.2.2  ResultsWord‑p. 131

$  Change historyWord‑p. 135

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