ETSI TR 103 515 V1.1.1 (2018-03)

TECHNICAL REPORT
Digital Enhanced Cordless Telecommunications (DECT);
Study on URLLC use cases of vertical industries
for DECT evolution and DECT-2020

2 ETSI TR 103 515 V1.1.1 (2018-03)

Reference
DTR/DECT-URLLC1
Keywords
DECT, use case, PMSE, IoT
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3 ETSI TR 103 515 V1.1.1 (2018-03)
Contents
Intellectual Property Rights . 8
Foreword . 8
Modal verbs terminology . 8
Introduction . 8
1 Scope . 9
2 References . 9
2.1 Normative references . 9
2.2 Informative references . 9
3 Definitions, symbols and abbreviations . 12
3.1 Definitions . 12
3.2 Symbols . 13
3.3 Abbreviations . 13
4 Overview, general concepts and methodology . 13
4.1 Overall intention and initial assumptions . 13
4.2 Sources and methodology for media and entertainment industry use cases . 14
4.3 Sources and methodology for home automation and industry automation use cases . 14
4.4 The STF 537 survey on use cases for license-exempt radio in IoT . 15
4.5 Classifications of Reliability, Latency and Data-rate . 15
4.5.1 Definitions . 15
4.5.2 Classifications . 15
4.6 5G visions for the different vertical domains . 16
4.6.1 Overview and 5G PPP vision . 16
4.6.2 Scenarios for low latency and high reliability. 18
4.6.2.1 Overview . 18
4.6.2.2 Candidate scenarios for URLLC . 18
5 Description of use cases and their Requirements . 20
5.1 List of use cases considered as candidate for DECT evolution or DECT-2020 solutions . 20
5.2 Use cases for home and building automation . 21
5.2.1 Description of vertical . 21
5.2.2 Environmental monitoring . 23
5.2.2.1 Description . 23
5.2.2.2 Preconditions . 23
5.2.2.3 Service flows . 23
5.2.2.4 Post-conditions . 23
5.2.2.5 Potential requirements . 23
5.2.3.6 Notes on possible DECT implementation . 23
5.2.3 Fire detection . 23
5.2.3.1 Description . 23
5.2.3.2 Preconditions . 24
5.2.3.3 Service flows . 24
5.2.3.4 Post-conditions . 24
5.2.3.5 Potential requirements . 24
5.2.3.6 Notes on possible DECT implementation . 24
5.2.4 Feedback control . 24
5.2.4.1 Description . 24
5.2.4.2 Preconditions . 24
5.2.4.3 Service flows . 24
5.2.4.4 Post-conditions . 25
5.2.4.5 Potential requirements . 25
5.2.4.6 Notes on possible DECT implementation . 25
5.3 Use cases for factories of the future . 25
5.3.1 Description of vertical . 25
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4 ETSI TR 103 515 V1.1.1 (2018-03)
5.3.1.1 Overview . 25
5.3.1.2 Major challenges and particularities . 27
5.3.1.3 Deployment aspects . 28
5.3.2 Motion control . 29
5.3.2.1 Description . 29
5.3.2.2 Preconditions . 30
5.3.2.3 Service flows . 30
5.3.2.4 Post-conditions . 30
5.3.2.5 Challenges to the 5G system . 30
5.3.2.6 Potential requirements . 31
5.3.2.7 Notes on possible DECT implementation . 31
5.3.3 Motion control - transmission of non-real-time data . 31
5.3.3.1 Description . 31
5.3.3.2 Preconditions . 32
5.3.3.3 Service flows . 32
5.3.3.4 Post-conditions . 32
5.3.3.5 Challenges to the 5G system . 32
5.3.3.6 Potential requirements . 33
5.3.3.7 Notes on possible DECT implementation . 33
5.3.4 Motion control - seamless integration with Industrial Ethernet . 33
5.3.4.1 Description . 33
5.3.4.2 Preconditions . 34
5.3.4.3 Service flows . 34
5.3.4.4 Post-conditions . 34
5.3.4.5 Challenges to the 5G system . 35
5.3.4.6 Potential requirements . 35
5.3.4.7 Notes on possible DECT implementation . 35
5.3.5 Control-to-control communication (motion subsystems) . 35
5.3.5.1 Description . 35
5.3.5.2 Preconditions . 36
5.3.5.3 Service flows . 36
5.3.5.4 Post-conditions . 36
5.3.5.5 Challenges to the 5G system . 36
5.3.5.6 Potential requirements . 37
5.3.5.7 Notes on possible DECT implementation . 37
5.3.6 Mobile control panels with safety functions . 37
5.3.6.1 Description . 37
5.3.6.2 Preconditions . 38
5.3.6.3 Service flows . 38
5.3.6.4 Post-conditions . 39
5.3.6.5 Challenges to the 5G system . 39
5.3.6.6 Potential requirements . 40
5.3.6.7 Notes on possible DECT implementation . 40
5.3.7 Mobile robots . 40
5.3.7.1 Description . 40
5.3.7.2 Preconditions . 41
5.3.7.3 Service flows . 42
5.3.7.4 Post-conditions . 42
5.3.7.5 Challenges to the 5G system . 42
5.3.7.6 Potential requirements . 43
5.3.7.7 Notes on possible DECT implementation . 43
5.3.8 Massive wireless sensor networks . 44
5.3.8.1 Description . 44
5.3.8.2 Preconditions . 47
5.3.8.3 Service flows . 47
5.3.8.4 Post-conditions . 48
5.3.8.5 Challenges to the 5G system . 48
5.3.8.6 Potential requirements . 49
5.3.8.7 Notes on possible DECT implementation . 49
5.3.9 Remote access and maintenance . 50
5.3.9.1 Description . 50
5.3.9.2 Preconditions . 51
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5 ETSI TR 103 515 V1.1.1 (2018-03)
5.3.9.3 Service flows . 51
5.3.9.4 Post-conditions . 52
5.3.9.5 Challenges to the 5G system . 52
5.3.9.6 Potential requirements . 53
5.3.9.7 Notes on possible DECT implementation . 53
5.3.10 Augmented reality . 53
5.3.10.1 Description . 53
5.3.10.2 Preconditions . 54
5.3.10.3 Service flows . 54
5.3.10.4 Post-conditions . 55
5.3.10.5 Challenges to the 5G system . 55
5.3.10.6 Potential requirements . 55
5.3.10.7 Notes on possible DECT implementation . 55
5.3.11 Process automation - closed-loop control . 56
5.3.11.1 Description . 56
5.3.11.2 Preconditions . 56
5.3.11.3 Service flows . 56
5.3.11.4 Post-conditions . 56
5.3.11.5 Challenges to the 5G system . 56
5.3.11.6 Potential requirements . 56
5.3.11.7 Notes on possible DECT implementation . 56
5.3.12 Process automation - process monitoring . 57
5.3.12.1 Description . 57
5.3.12.2 Preconditions . 57
5.3.12.3 Service flows . 57
5.3.12.4 Post-conditions . 57
5.3.12.5 Challenges to the 5G system . 57
5.3.12.6 Potential requirements . 57
5.3.12.7 Notes on possible DECT implementation . 57
5.3.13 Process automation - plant asset management . 58
5.3.13.1 Description . 58
5.3.13.2 Preconditions . 58
5.3.13.3 Service flows . 58
5.3.13.4 Post-conditions . 58
5.3.13.5 Challenges to the 5G system . 58
5.3.13.6 Potential requirements . 59
5.3.13.7 Notes on possible DECT implementation . 59
5.3.14 Connectivity for the factory floor . 59
5.3.14.1 Description . 59
5.3.14.2 Pre-conditions . 60
5.3.14.3 Service flows . 60
5.3.14.4 Post-conditions . 60
5.3.14.5 Challenges to the 5G system . 60
5.3.14.6 Potential requirements . 61
5.3.14.7 Notes on possible DECT implementation . 61
5.3.15 Inbound logistics for manufacturing . 61
5.3.15.1 Description . 61
5.3.15.2 Pre-conditions . 61
5.3.15.3 Service Flows . 62
5.3.15.4 Post-conditions . 62
5.3.15.5 Challenges to the 5G system . 62
5.3.15.5.1 Identification of private networks and method of connection . 62
5.3.15.6 Potential requirements . 63
5.3.15.7 Notes on possible DECT implementation . 63
5.3.16 Variable message reliability . 63
5.3.16.1 Description . 63
5.3.16.2 Preconditions . 64
5.3.16.3 Service flows . 64
5.3.16.4 Post-conditions . 64
5.3.16.5 Challenges to the 5G system . 64
5.3.16.6 Potential requirements . 64
5.3.16.7 Notes on possible DECT implementation . 64
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5.3.17 Flexible, modular assembly area . 65
5.3.17.1 Description . 65
5.3.17.2 Preconditions . 65
5.3.17.3 Service flows . 65
5.3.17.4 Post-conditions . 66
5.3.17.5 Challenges to the 5G system . 66
5.3.17.6 Potential requirements . 66
5.3.17.7 Notes on possible DECT implementation . 66
5.3.18 Plug and produce for field devices . 67
5.3.18.1 Description . 67
5.3.18.2 Preconditions . 68
5.3.18.3 Service flows . 69
5.3.18.4 Post-conditions . 70
5.3.18.5 Challenges to the 5G system . 70
5.3.18.6 Potential requirements . 71
5.3.18.7 Notes on possible DECT implementation . 71
5.3.19 Private-public interaction . 71
5.3.19.1 Description . 71
5.3.19.2 Pre-conditions . 71
5.3.19.3 Service Flows . 72
5.3.19.4 Post-conditions . 72
5.3.19.5 Potential Requirements . 73
5.3.19.7 Notes on possible DECT implementation . 73
5.4 Use cases for Smart Living - Health Care . 74
5.4.1 Description of vertical . 74
5.4.2 Telecare data traffic between home and remote monitoring centre . 74
5.4.2.1 Description . 74
5.4.2.2 Preconditions . 74
5.4.2.3 Service flows . 74
5.4.2.4 Post-conditions . 75
5.4.2.5 Challenges to the 5G system . 75
5.4.2.6 Potential requirements . 76
5.4.2.7 Notes on possible DECT implementation . 76
5.5 Use cases for Programme Making and Special Events (PMSE) . 76
5.5.1 Description of vertical . 76
5.5.1.1 Overview . 76
5.5.1.2 Major challenges and particularities . 78
5.5.2 Low-latency audio streaming for live performance . 78
5.5.2.1 Description . 78
5.5.2.2 Pre-conditions . 81
5.5.2.3 Service Flows . 81
5.5.2.4 Post-conditions . 81
5.5.2.5 Challenges to the 5G System . 81
5.5.2.6 Potential Requirements . 82
5.5.2.7 Notes on possible DECT implementation . 82
5.5.3 Low-latency audio streaming for local conference systems . 82
5.5.3.1 Description . 82
5.5.3.2 Pre-conditions . 84
5.5.3.3 Service Flows . 84
5.5.3.4 Post-conditions . 84
5.5.3.5 Challenges to the 5G System . 84
5.5.3.6 Potential Requirements . 84
5.5.3.7 Notes on possible DECT implementation . 85
5.5.4 High data rate video streaming / professional video production . 85
5.5.4.1 Description . 85
5.5.4.2 Pre-conditions . 87
5.5.4.3 Service Flows . 87
5.5.4.4 Post-conditions . 87
5.5.4.5 Challenges to the 5G System . 87
5.5.4.6 Potential Requirements . 87
5.5.4.7 Notes on possible DECT implementation . 87
5.6 Use cases not (yet) considered . 88
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5.7 Classification of the use cases regarding reliability and latency and feasibility for DECT implementation . 88
6 Initial thoughts on use case implementation . 91
6.1 General . 91
6.2 Overview of existing DECT standard architecture . 91
6.3 DECT evolution and DECT-2020 development paths . 91
6.4 Identification of use cases for DECT evolution and DECT-2020 development paths . 92
6.5 Possible standard structure for DECT evolution (based on DECT technology) . 92
6.6 Possible standard structure for DECT-2020 (based on new 5G radio interface) . 93
Annex A: Survey conducted by STF 537 . 94
A.1 Survey on Internet of Things (IoT) use cases for license exempt radio . 94
A.1.1 Scope of the survey . 94
A.1.2 Content of the survey . 94
A.1.3 Presentation of the survey . 99
Annex B: Bibliography . 103
History . 104

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8 ETSI TR 103 515 V1.1.1 (2018-03)
Intellectual Property Rights
Essential patents
IPRs essential or potentially essential to normative deliverables may have been declared to ETSI. The information
pertaining to these essential IPRs, if any, is publicly available for ETSI members and non-members, and can be found
in ETSI SR 000 314: "Intellectual Property Rights (IPRs); Essential, or potentially Essential, IPRs notified to ETSI in
respect of ETSI standards", which is available from the ETSI Secretariat. Latest updates are available on the ETSI Web
server (https://ipr.etsi.org/).
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can be given as to the existence of other IPRs not referenced in ETSI SR 000 314 (or the updates on the ETSI Web
server) which are, or may be, or may become, essential to the present document.
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Foreword
This Technical Report (TR) has been produced by ETSI Technical Committee Digital Enhanced Cordless
Telecommunications (DECT).
The present document presents a study of use cases and vertical scenarios for Ultra-Reliable Low-Latency
Communications (URLLC) based on different developments paths evolving DECT technology.
The present document is a preparation of follow-up technical specifications within DECT, DECT ULE, DECT
evolution and DECT-2020.
Modal verbs terminology
In the present document "should", "should not", "may", "need not", "will", "will not", "can" and "cannot" are to be
interpreted as described in clause 3.2 of the ETSI Drafting Rules (Verbal forms for the expression of provisions).
"must" and "must not" are NOT allowed in ETSI deliverables except when used in dir
...