Tech-
invite
3GPP
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IETF
space
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Content for
TR 36.843
Word version: 12.0.1
1…
2…
2
References
3
Definitions and abbreviations
4
Public Safety Use Cases and Scenarios
5
Requirements
6
General design assumptions
7
Synchronization
8
Discovery
9
Communication
10
Evaluation results for D2D
11
Conclusion
A
Simulation model
$
Change History
2
References
Word‑p. 7
3
Definitions and abbreviations
Word‑p. 8
3.1
Definitions
3.2
Abbreviations
4
Public Safety Use Cases and Scenarios
Word‑p. 9
5
Requirements
Word‑p. 10
6
General design assumptions
6.1
Multiple access scheme
6.1.1
UE transmitter performance
Word‑p. 11
6.1.2
UE receiver performance
6.2
Multiplexing of signals
6.3
Signal design details
Word‑p. 12
7
Synchronization
Word‑p. 13
7.1
Signal design
7.2
Procedure
7.2.1
Transmission of D2DSS
7.2.2
Selection of timing reference D2D Synchronization Source
Word‑p. 14
7.2.3
Transmission timing offset
8
Discovery
Word‑p. 16
8.1
Types of Discovery
8.2
Physical layer design
8.2.1
Signal design
8.2.2
Resource allocation
Word‑p. 17
8.2.3
Transmission timing offset
Word‑p. 18
8.3
Upper layer aspects
Word‑p. 19
8.3.1
General
8.3.2
Radio protocol architecture
Word‑p. 20
8.3.3
Radio resource management aspect
Word‑p. 21
8.3.3.1
Protocol states
8.3.3.2
Radio resource allocation
8.3.3.3
Procedure
9
Communication
Word‑p. 22
9.1
Physical layer design
9.1.1
Signal design
9.1.2
Resource allocation
9.2
Upper layer aspects
Word‑p. 23
9.2.1
General
9.2.2
Radio protocol architecture
Word‑p. 24
9.2.2.1
Control-plane
9.2.2.2
User-plane
9.2.3
Radio resource management aspect
9.2.3.1
Protocol states
9.2.3.2
Radio resource allocation
9.2.3.3
Procedure
Word‑p. 25
10
Evaluation results for D2D
Word‑p. 26
10.1
Evaluation results for discovery
10.2
Evaluation results for communication
Word‑p. 29
11
Conclusion
Word‑p. 32
A
Simulation model
Word‑p. 33
A.1
Link simulation Scenarios
A.2
System simulation Scenarios
A.2.1
System simulation assumptions
A.2.1.1
Reference system deployments
A.2.1.1.1
Dropping and Association for Unicast
Word‑p. 37
A.2.1.1.2
Dropping and Association for Groupcast
Word‑p. 38
A.2.1.1.3
Dropping and Association for Broadcast
A.2.1.2
Channel models
Word‑p. 39
A.2.1.2.1
Doppler modelling
Word‑p. 41
A.2.1.2.1.1
System level
A.2.1.2.1.2
Link level
A.2.1.3
Traffic models
Word‑p. 43
A.2.1.4
Performance evaluation metrics
A.2.1.4.1
Metrics for discovery
A.2.1.4.2
Metrics for communication
Word‑p. 44
A.2.1.5
In-band emissions model
Word‑p. 45
A.2.1.6
Power consumption model
Word‑p. 46
A.2.2
System level simulator calibration
A.3
Detailed simulation results
A.4
Public Safety ProSe Communication Use Cases
Word‑p. 47
A.4.1
Typical Public Safety Use Cases and Scenarios of ProSe Communication
A.4.1.1
General Description of Public Safety ProSe Communication Scenarios
A.4.1.2
Typical Use Cases of Public Safety ProSe Communication
Word‑p. 48
A.4.2
Typical performance values and E-UTRAN characteristics for Public Safety of ProSe Communication
Word‑p. 49
A.4.2.1
Basic operations
A.4.2.2
Coverage
A.4.2.3
Applications
A.4.2.4
System Aspects
$
Change History
Word‑p. 50