Content for TR 22.829 Word version: 17.1.0
5 Use cases
5.1 Use case of UAV supporting high resolution video live broadcast application
5.2 Radio Access Node on-board UAV
5.3 Use case for UAS Commands and Control (C2) Communication
5.4 Use case for simultaneously support data transmission for UAVs and eMBB users
5.5 Use case for autonomous UAVs controlled by AI
5.6 Isolated deployment of Radio Access Through UAV
5.7 Radio Access through UAV
5.8 Separation of UAV service area
5.9 Use case for service experience assurance
5.10 Use case for service availability to UAVs needs
5.11 Swarm of UAVs in logistics
5.12 Changing UAV Controller
5.13 Framework for steering KPIs of UAV
7 Consolidated potential requirements
8 Conclusions and Recommendations
A Computation of UAV Density and Range of Inspection
B Time Delay Calculation of Unmanned Aerial Vehicle
C UAV Information
$ Change history
5 Use cases p. 8
5.1 Use case of UAV supporting high resolution video live broadcast application p. 8
5.1.1 Description p. 8
5.1.2 Pre-conditions p. 9
5.1.3 Service Flows p. 9
5.1.4 Post-conditions p. 9
5.1.5 Existing features partly or fully covering the use case functionality p. 9
5.1.6 Potential New Requirements needed to support the use case p. 9
5.2 Radio Access Node on-board UAV p. 10
5.2.1 Description p. 10
5.2.2 Pre-conditions p. 11
5.2.3 Service Flows p. 11
5.2.4 Post-conditions p. 11
5.2.5 Existing features partly or fully covering the use case functionality p. 12
5.2.6 Potential New Requirements needed to support the use case p. 12
5.3 Use case for UAS Commands and Control (C2) Communication p. 12
5.3.1 Description p. 12
5.3.2 Pre-conditions p. 14
5.3.3 Service Flows p. 15
5.3.4 Post-conditions p. 15
5.3.5 Existing features partly or fully covering the use case functionality p. 15
5.3.6 Potential New Requirements needed to support the use case p. 15
5.4 Use case for simultaneously support data transmission for UAVs and eMBB users p. 16
5.4.1 Description p. 16
5.4.2 Pre-conditions p. 16
5.4.3 Service Flows p. 17
5.4.4 Post-conditions p. 17
5.4.5 Existing features partly or fully covering the use case functionality p. 17
5.4.6 Potential New Requirements needed to support the use case p. 17
5.5 Use case for autonomous UAVs controlled by AI p. 17
5.5.1 Description p. 17
5.5.2 Pre-conditions p. 18
5.5.3 Service Flows p. 18
5.5.4 Post-conditions p. 19
5.5.5 Existing features partly or fully covering the use case functionality p. 19
5.5.6 Potential New Requirements needed to support the use case p. 19
5.6 Isolated deployment of Radio Access Through UAV p. 19
5.6.1 Description p. 19
5.6.2 Pre-conditions p. 20
5.6.3 Service Flows p. 20
5.6.4 Post-conditions p. 20
5.6.5 Existing features partly or fully covering the use case functionality p. 20
5.6.6 Potential New Requirements needed to support the use case p. 21
5.7 Radio Access through UAV p. 21
5.7.1 Description p. 21
5.7.2 Pre-conditions p. 22
5.7.3 Service Flows p. 22
5.7.4 Post-conditions p. 23
5.7.5 Potential Impacts or Interactions with Existing Services/Features p. 23
5.7.6 Potential new requirements p. 23
5.8 Separation of UAV service area p. 24
5.8.1 Description p. 24
5.8.2 Pre-conditions p. 25
5.8.3 Service Flows p. 26
5.8.4 Post-conditions p. 26
5.8.5 Potential Impacts or Interactions with Existing Services/Features p. 26
5.8.6 Potential new requirements p. 27
5.9 Use case for service experience assurance p. 27
5.9.1 Description p. 27
5.9.2 Pre-conditions p. 27
5.9.3 Service Flows p. 28
5.9.4 Post-conditions p. 28
5.9.5 Existing features partly or fully covering the use case functionality p. 28
5.9.6 Potential New Requirements needed to support the use case p. 29
5.10 Use case for service availability to UAVs needs p. 29
5.10.1 Description p. 29
5.10.2 Pre-conditions p. 29
5.10.3 Service Flows p. 29
5.10.4 Post-conditions p. 30
5.10.5 Existing features partly or fully covering the use case functionality p. 31
5.10.6 Potential New Requirements needed to support the use case p. 31
5.11 Swarm of UAVs in logistics p. 31
5.12 Changing UAV Controller p. 32
5.12.1 Description p. 32
5.12.2 Pre-conditions p. 33
5.12.3 Service Flows p. 33
5.12.4 Post-conditions p. 33
5.12.5 Existing features partly or fully covering the use case functionality p. 33
5.12.6 Potential New Requirements needed to support the use case p. 34
5.13 Framework for steering KPIs of UAV p. 34
5.13.1 Description p. 34
5.13.2 Pre-conditions p. 34
5.13.3 Service Flows p. 34
5.13.4 Post-conditions p. 35
5.13.5 Existing features partly or fully covering the use case functionality p. 35
5.13.6 Potential New Requirements needed to support the use case p. 35
5.13.6.1 Service level requirements p. 35
5.13.6.2 KPIs p. 35
6 Void
7 Consolidated potential requirements p. 36
7.1 Changing UAV Controller p. 36
7.1.1 KPIs for UAV services p. 36
7.1.2 KPIs for UAV periodic control p. 37
7.1.3 Other KPIs for UAV p. 37
7.2 Requirement for Network exposure p. 38
7.5 C2 communication p. 38
8 Conclusions and Recommendations p. 38
A Computation of UAV Density and Range of Inspection p. 39
A.1 Overview p. 39
A.2 Determining the Minimum Cruise Radius of UAV p. 39
A.3 Merged Data Processing of Elevation Data Set p. 40
A.4 Internal cruise modes in key areas p. 41
A.5 External cruise modes in key areas p. 41
A.6 Result p. 42
B Time Delay Calculation of Unmanned Aerial Vehicle p. 44
C UAV Information p. 46
C.1 UAV load capacity p. 46
C.2 UAV performance p. 46
C.3 Endurance capacity p. 46
C.4 Environmental requirements p. 46
$ Change history p. 47
