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Content for  TR 36.785  Word version:  14.0.0

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2 References3 Definitions, symbols and abbreviations4 Background5 Deployment and co-existence studies6 V2V transmitter characteristics7 V2V receiver characteristics8 Other specification impacts (if applicable)9 Performance requirementsA Link level simulation mapping model for V2V systemB Reference Sensitivity requirements for V2V communication$ Change History

 

2  References

3  Definitions, symbols and abbreviationsWord‑p. 7

3.1  Definitions

3.2  Abbreviations

4  Background

4.1  Justification

4.2  ObjectiveWord‑p. 8

4.3  V2V operating ScenariosWord‑p. 9

4.3.1  General Description

4.3.2  Operation Aspects

5  Deployment and co-existence studiesWord‑p. 10

5.1  General

5.2  Operating bandsWord‑p. 11

5.2.1  Regulatory Background

5.2.1.1  ITU Region 1

5.2.1.1.1  TX requirements
5.2.1.1.2  RX RequirementsWord‑p. 12

5.2.1.2  ITU Region 2Word‑p. 13

5.2.1.2.1  RF out put powerWord‑p. 14

5.2.1.3  ITU Region 3

5.2.1.3.1  Korea

5.2.1.4  ComparisonWord‑p. 15

5.2.2  V2V operating bands

5.3  Channel bandwidthsWord‑p. 16

5.3.1  Channel bandwidths per operating band for V2V service

5.4  Adjacent Channel Co-existence evaluations

5.4.1  Coexistence scenarios

5.4.2  Simulation AssumptionsWord‑p. 18

5.4.2.1  General for LTE system in 2GHz

5.4.2.2  General for DSRC/ITS system in 5.9GHzWord‑p. 19

5.4.2.3  Detail parameters for V2V communications in both frequency bandsWord‑p. 20

5.4.2.4  PRR performance metricsWord‑p. 21

5.4.3  Simulation ResultsWord‑p. 22

5.4.3.1  V2V Communications in 2GHz

5.4.3.1.1  Case1: V2V UE-to-LTE BS
5.4.3.1.2  Case2: LTE BS-to-V2V UEWord‑p. 24

5.4.3.2  V2V Communications in 5.9GHzWord‑p. 26

5.4.3.2.1  Case3: V2V UE-to-DSRC UE
5.4.3.2.2  Case4: DSRC UE-to-V2V UEWord‑p. 31

5.5  Additional scenariosWord‑p. 35

5.6  Conclusion of V2V coexistence evaluationsWord‑p. 36

6  V2V transmitter characteristics

6.1  Maximum output power for V2V UE

6.2  UE maximum output power for modulation / channel bandwidth

6.2.1  Case 1: PSCCH and PSSCH on adjacent PRBsWord‑p. 37

6.2.1.1  Summary of results

6.2.1.2  Results from Huawei

6.2.2  Case 2: PSCCH and PSSCH on non-adjacent PRBsWord‑p. 38

6.3  UE maximum output power with additional requirements

6.3.1  Case 1: PSCCH and PSSCH on adjacent PRBs

6.3.1.1  Summary of results

6.3.1.2  Results from Huawei

6.3.2  Case 2: PSCCH and PSSCH on non-adjacent PRBsWord‑p. 39

6.4  Configured transmitted power for V2V UE

6.5  UE Minimum output power for V2V UE

6.6  Transmit OFF power V2V UE

6.7  ON/OFF time mask for V2V UE

6.8  Power control for V2V UEWord‑p. 40

6.8.1  Absolute power tolerance

6.9  Transmit signal quality for V2V UE

6.9.1  Frequency error

6.9.2  Transmit modulation quality

6.9.2.1  Error Vector Magnitude

6.9.2.2  Carrier leakage

6.9.2.3  In-band emissions

6.9.2.4  EVM equalizer spectrum flatnessWord‑p. 41

6.10  spectrum emission mask for V2V UE

6.10.1  Additional spectrum emission mask for V2V UE

6.11  ACLR requirements for V2V UEWord‑p. 42

6.12  Spurious emission for V2V UE

6.13  Spurious emission band UE co-existence for V2V UE

7  V2V receiver characteristicsWord‑p. 43

7.1  Reference sensitivity power level

7.2  Maximum input levelWord‑p. 44

7.3  Adjacent Channel Selectivity (ACS)

7.4  Blocking characteristicsWord‑p. 45

7.4.1  In-band blocking

7.4.2  Out-of-band blockingWord‑p. 46

7.4.3  Narrow band blockingWord‑p. 47

7.5  Spurious response

7.6  Intermodulation characteristics

7.7  RX spurious emissionsWord‑p. 48

8  Other specification impacts (if applicable)Word‑p. 49

9  Performance requirementsWord‑p. 50

A  Link level simulation mapping model for V2V systemWord‑p. 51

B  Reference Sensitivity requirements for V2V communicationWord‑p. 55

$  Change HistoryWord‑p. 57

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