TSN and Time Sensitive Wireless

July 2023
Inaki Val, MaxLinear
Slide 1
TSN and
 Time Sensitive Wireless
Date: 12-Jul-23
Abstract
Discuss relationship and dependencies between
802.11 and 802.1 Time Sensitive Networking
(TSN)
Clarify the term TSN in the context of 802.11
Define “Time Sensitive Wireless” in 802.11
Slide 2
Inaki Val, MaxLinear
July 2023
Introduction (1/2)
UHR targets the improvement of packet delivery by
reducing the transmission latency and enhancing network
reliability [1]
Reliability in communications implies
Guarantee for receiving the data packet
Guarantee for receiving it 
on time
, within time bounds
In summary, the network traffic must be 
predictable
This target 
can be identified as an overall Quality of
Service (QoS) enhancement
Slide 3
Inaki Val, MaxLinear
July 2023
Introduction (2/2)
Several RTA use cases 
with time-sensitive and
low latency requirements 
have been identified
[2], and many other use cases would benefit
from QoS improvement features
Different features are being proposed for
latency, reliability, and QoS improvement:
Multi-AP [3], preemption [4], and low-latency
scheduling [5]
Slide 4
Inaki Val, MaxLinear
July 2023
Problem Statement
In this context, the term “
Time Sensitive Networking
(TSN) is often used, sometimes as synonymous with
“latency improvement”
Several questions arise:
What do we mean with TSN in UHR?
What is the relationship with existing TSN standards?
Where do we need TSN and Time Sensitive Wireless in
802.11?
Let’s clarify the 
use of these different terms
Slide 5
Inaki Val, MaxLinear
July 2023
Time Sensitive Networking (TSN) - summary
TSN refers to a 
set of IEEE 802.1 standards
 that offer an Ethernet network with
the following characteristics [6]:
TSN can be built on a selection of these standards, depending on the features
needed: 
pick & choose
TSN can be seen as an Ethernet multi-switch network based on a TDMA MAC
(e.g., IEEE 802.1Qbv) and a global common clock (e.g., IEEE 802.1AS) over the
whole network
TSN Ethernet switch allows critical traffic and blocks the rest at certain periodic time windows
Simultaneous time-coordinated TSN switches guarantee end-to-end bounded latency
Slide 6
Inaki Val, MaxLinear
July 2023
E2E Bounded Latency
TSN
IEEE 802.1AS
IEEE 802.1CB
IEEE 802.1Qbv
IEEE 802.1Qbu
IEEE 802.1Qcc
IEEE 802.1Qav
IEEE 802.1Qci
Evolution of TSN
While TSN was originally defined for IEEE 802.3 Ethernet interface, TSN aims to
be extended to other wireless media, such as:
IEEE 802.3 Ethernet, IEEE 802.11, 3GPP 5G
Each of the MAC/PHY interfaces needs to support TSN capabilities
5G integration into TSN is standardized under 3GPP Release 16 and beyond, with
specific enhancements named “Time-Sensitive Communications”
This approach can be called “Generic TSN”
Slide 7
Inaki Val, MaxLinear
July 2023
TSN Common Layer
IEEE 802.3
IEEE 802.11
3GPP 5G/6G
Others
Network Stack
Application
TSN Device
TSN and IEEE 802.11
First steps towards TSN and 802.11 integration already done
802.1AS Time synchronization TSN standard supports 802.11 MAC/PHY interface
802.11 defines time-sensitive feature (i.e., FTM)
802.1 defines the TSN standard (i.e., 802.1AS) building on this 802.11 feature
Additionally, IEEE 802.11 is defining new features that 
could
 be leveraged by
TSN, for instance:
Slide 8
Inaki Val, MaxLinear
July 2023
In summary – TSN and IEEE 802.11
TSN is an ecosystem of standards within 802.1
A “Generic TSN” can be followed allowing a common
IEEE 802.1 TSN layer to make use of TSN tools offered
by each technology
802.11 defines time-sensitive features that can be
leveraged by TSN or can be used in a stand-alone
802.11 network
Slide 9
Inaki Val, MaxLinear
July 2023
Time Sensitive features in UHR (1/2)
Time sensitive features in UHR cover two
different needs:
a)
Real-Time Applications (RTA)
 with bounded-latency requirements
and periodic traffic patterns [2]:
Online gaming, Professional Audio/Video, Industrial Automation,
Augmented and Virtual Reality
T
ime-sensitive requirements 
for correct operation (e.g., VR)
Some RTA use cases may have strict requirements for critical operation
(e.g., Industrial Automation)
Slide 10
Inaki Val, MaxLinear
July 2023
Time Sensitive features in UHR (2/2)
b)
Multi-AP Coordination and QoS enhancement
Some forms of 
Multi-AP coordination need common clock or
time reference
Time-coordinated operations: C-TDMA, Coordinated r-TWT,
C-OFDMA, Joint transmission
UHR needs to provide the tools for coordinating the time-aware
operation in Multi-AP environments
QoS enhancements: IoT, Gaming, Video streaming, Online
Audio/Video, Remote Surveillance, XR, etc.
Slide 11
Inaki Val, MaxLinear
July 2023
TSN Interpretation (1/3)
Discussions around “Time sensitive” in the context
802.11bn could have two different interpretations:
a)
Incorporate IEEE 802.11 into 
Generic TSN
b)
Define a set of 802.11 
time-sensitive features 
to be used in
stand-alone 802.11 networks
Slide 12
Inaki Val, MaxLinear
July 2023
So far, both aspects have been covered by
using “implementing TSN” which does
not seem correct
TSN Interpretation (2/3)
a)
Incorporate IEEE 802.11 into 
Generic TSN
Mainly for 
strict time-critical RTA use cases that require an end-to-
end TSN solution (e.g., Industrial Automation)
For the end user, connecting an Ethernet TSN device or using an
802.11 interface will lead to similar experience, maintaining the
performance 
and requirements
It could imply a high complexity, implementing the selected 802.1
TSN standards for guaranteeing interoperability and strict
deterministic behavior
Probably not directly applicable to time-aware 802.11 features (e.g.,
Multi-AP coordination)
Let’s call this “
Generic TSN incorporating 802.11
Slide 13
Inaki Val, MaxLinear
July 2023
TSN Interpretation (3/3)
b)
Define 
a set of 802.11 time-sensitive features to be used stand-alone in
802.11 networks
Improve the reliability, QoS management, and the behavior of time-
sensitive traffic in 802.11 networks
Provide the tools for coordinating the time-aware operation in Multi-
AP environments
Not necess
arily following/implementing the 802.1 TSN standard
TSN use cases (time-critical) may leverage these capabilities for their
applications
Let’s call this “
Time Sensitive Wireless
” (not TSN)
Slide 14
Inaki Val, MaxLinear
July 2023
Summary
The term TSN is currently used loosely to refer to both
interpretations, leading to possible misunderstandings:
a)
Generic TSN incorporating 802.11
b)
Time Sensitive Wireless
(a) would make use of (b), but (b) could exist
independently
Following the approach for TSN time synchronization over 802.11
with FTM feature
Following the 3GPP approach defining Time Sensitive
Communications enhancements
Slide 15
Inaki Val, MaxLinear
July 2023
Conclusion
UHR 
targets reliable and time-sensitive applications
UHR is proposing new features which will require time-
sensitive tools
These new features and tools could enable TSN capabilities
We have identified two different interpretations of TSN
term in the context 
of 802.11
a)
Generic TSN incorporating 802.11
b)
Time Sensitive Wireless
802.11bn should focus on the time-sensitive wireless (TSW)
features/capabilities that can help 802.11 usages in both
cases stand alone and TSN scenario
Slide 16
Inaki Val, MaxLinear
July 2023
Proposal
UHR should not define time-sensitive features
exclusively within the context of TSN
Time sensitive 
features should be primarily intended
for improving QoS and reliability within an 802.11
network (i.e. Time Sensitive Wireless)
Any work done to leverage 
these features for TSN
extensions will be primarily done by 802.1
“TSN” is not a synonym for “latency improvement”
Slide 17
Inaki Val, MaxLinear
July 2023
References
[1]
 IEEE 802.11-23/0028r6
UHR 
PAR discussion
[2] Kate Meng and et al. (Tencent Technology), “RTA report summary”,
19/0065r6, March 2019.
[3] Liuming Lu and et al. (Oppo), “Multi-AP Coordination for Low Latency
Traffic Delivery: Usage Scenarios and potential features”, 23/0046r2, March 2023.
[4] Juan Fang and et al. (Intel), “Preemption for Low Latency Application”,
23/0092r0, March 2023.
[5] Serhat Erkucuk and et al. (Offino), “Enhanced Scheduling Method for Low
Latency Traffic”, 23/0378r0, May 2023.
[6] IEEE 802.1 TSN, https://1.ieee802.org/
July
 2023
Slide 18
Inaki Val, MaxLinear
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This document explores the relationship between IEEE 802.11 and Time Sensitive Networking (TSN), defining TSN in the context of 802.11 and highlighting the importance of TSN for improving packet delivery, reducing latency, and enhancing network reliability. Various features like Multi-AP, preemption, and low-latency scheduling are discussed, along with clarifying the use of terms like TSN and Time Sensitive Wireless in the 802.11 standard.


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  1. July 2023 doc.: IEEE 802.11-23/1173r1 TSN and Time Sensitive Wireless Date: 12-Jul-23 Name Inaki Val Affiliations email ival@maxlinear.com Marcos Martinez MaxLinear Sigurd Schelstraete Rainer Strobel Submission Slide 1 Inaki Val, MaxLinear

  2. July 2023 doc.: IEEE 802.11-23/1173r1 Abstract Discuss relationship and dependencies between 802.11 and 802.1 Time Sensitive Networking (TSN) Clarify the term TSN in the context of 802.11 Define Time Sensitive Wireless in 802.11 Submission Slide 2 Inaki Val, MaxLinear

  3. July 2023 doc.: IEEE 802.11-23/1173r1 Introduction (1/2) UHR targets the improvement of packet delivery by reducing the transmission latency and enhancing network reliability [1] Reliability in communications implies Guarantee for receiving the data packet Guarantee for receiving it on time, within time bounds In summary, the network traffic must be predictable This target can be identified as an overall Quality of Service (QoS) enhancement Submission Slide 3 Inaki Val, MaxLinear

  4. July 2023 doc.: IEEE 802.11-23/1173r1 Introduction (2/2) Several RTA use cases with time-sensitive and low latency requirements have been identified [2], and many other use cases would benefit from QoS improvement features Different features are being proposed for latency, reliability, and QoS improvement: Multi-AP [3], preemption [4], and low-latency scheduling [5] Submission Slide 4 Inaki Val, MaxLinear

  5. July 2023 doc.: IEEE 802.11-23/1173r1 Problem Statement In this context, the term Time Sensitive Networking (TSN) is often used, sometimes as synonymous with latency improvement Several questions arise: What do we mean with TSN in UHR? What is the relationship with existing TSN standards? Where do we need TSN and Time Sensitive Wireless in 802.11? Let s clarify the use of these different terms Submission Slide 5 Inaki Val, MaxLinear

  6. July 2023 doc.: IEEE 802.11-23/1173r1 Time Sensitive Networking (TSN) - summary TSN refers to a set of IEEE 802.1 standards that offer an Ethernet network with the following characteristics [6]: E2E Bounded Latency Global Clock Reliability Availability IEEE 802.1AS IEEE 802.1CB TSN IEEE 802.1Qcc IEEE 802.1Qav IEEE 802.1Qci Resource Management Bounded Latency IEEE 802.1Qbv IEEE 802.1Qbu TSN can be built on a selection of these standards, depending on the features needed: pick & choose TSN can be seen as an Ethernet multi-switch network based on a TDMA MAC (e.g., IEEE 802.1Qbv) and a global common clock (e.g., IEEE 802.1AS) over the whole network TSN Ethernet switch allows critical traffic and blocks the rest at certain periodic time windows Simultaneous time-coordinated TSN switches guarantee end-to-end bounded latency Submission Slide 6 Inaki Val, MaxLinear

  7. July 2023 doc.: IEEE 802.11-23/1173r1 Evolution of TSN While TSN was originally defined for IEEE 802.3 Ethernet interface, TSN aims to be extended to other wireless media, such as: IEEE 802.3 Ethernet, IEEE 802.11, 3GPP 5G Each of the MAC/PHY interfaces needs to support TSN capabilities 5G integration into TSN is standardized under 3GPP Release 16 and beyond, with specific enhancements named Time-Sensitive Communications This approach can be called Generic TSN Application TSN Device Network Stack Generic TSN TSN Common Layer IEEE 802.3 IEEE 802.11 3GPP 5G/6G Others Submission Slide 7 Inaki Val, MaxLinear

  8. July 2023 doc.: IEEE 802.11-23/1173r1 TSN and IEEE 802.11 First steps towards TSN and 802.11 integration already done 802.1AS Time synchronization TSN standard supports 802.11 MAC/PHY interface 802.11 defines time-sensitive feature (i.e., FTM) 802.1 defines the TSN standard (i.e., 802.1AS) building on this 802.11 feature Additionally, IEEE 802.11 is defining new features that could be leveraged by TSN, for instance: Feature IEEE 802.11 TSN Time Synchronization TSF, TM, FTM IEEE 802.1AS EDCA IEEE 802.1Q VLAN Traffic Classification & Prioritization Stream Classification Service Stream Classification Trigger-based Access Scheduled Operation Restricted TWT IEEE 802.1Qbv TAS Multi-AP Coordination Reliability & Availability Multi-Link Operation IEEE 802.1CB Submission Slide 8 Inaki Val, MaxLinear

  9. July 2023 doc.: IEEE 802.11-23/1173r1 In summary TSN and IEEE 802.11 TSN is an ecosystem of standards within 802.1 A Generic TSN can be followed allowing a common IEEE 802.1 TSN layer to make use of TSN tools offered by each technology 802.11 defines time-sensitive features that can be leveraged by TSN or can be used in a stand-alone 802.11 network Submission Slide 9 Inaki Val, MaxLinear

  10. July 2023 doc.: IEEE 802.11-23/1173r1 Time Sensitive features in UHR (1/2) Time sensitive features in UHR cover two different needs: a) Real-Time Applications (RTA) with bounded-latency requirements and periodic traffic patterns [2]: Online gaming, Professional Audio/Video, Industrial Automation, Augmented and Virtual Reality Time-sensitive requirements for correct operation (e.g., VR) Some RTA use cases may have strict requirements for critical operation (e.g., Industrial Automation) Submission Slide 10 Inaki Val, MaxLinear

  11. July 2023 doc.: IEEE 802.11-23/1173r1 Time Sensitive features in UHR (2/2) b) Multi-AP Coordination and QoS enhancement Some forms of Multi-AP coordination need common clock or time reference Time-coordinated operations: C-TDMA, Coordinated r-TWT, C-OFDMA, Joint transmission UHR needs to provide the tools for coordinating the time-aware operation in Multi-AP environments QoS enhancements: IoT, Gaming, Video streaming, Online Audio/Video, Remote Surveillance, XR, etc. Submission Slide 11 Inaki Val, MaxLinear

  12. July 2023 doc.: IEEE 802.11-23/1173r1 TSN Interpretation (1/3) Discussions around Time sensitive in the context 802.11bn could have two different interpretations: a) Incorporate IEEE 802.11 into Generic TSN b) Define a set of 802.11 time-sensitive features to be used in stand-alone 802.11 networks So far, both aspects have been covered by using implementing TSN which does not seem correct Submission Slide 12 Inaki Val, MaxLinear

  13. July 2023 doc.: IEEE 802.11-23/1173r1 TSN Interpretation (2/3) a) Incorporate IEEE 802.11 into Generic TSN Mainly for strict time-critical RTA use cases that require an end-to- end TSN solution (e.g., Industrial Automation) For the end user, connecting an Ethernet TSN device or using an 802.11 interface will lead to similar experience, maintaining the performance and requirements It could imply a high complexity, implementing the selected 802.1 TSN standards for guaranteeing interoperability and strict deterministic behavior Probably not directly applicable to time-aware 802.11 features (e.g., Multi-AP coordination) Let s call this Generic TSN incorporating 802.11 Submission Slide 13 Inaki Val, MaxLinear

  14. July 2023 doc.: IEEE 802.11-23/1173r1 TSN Interpretation (3/3) b) Define a set of 802.11 time-sensitive features to be used stand-alone in 802.11 networks Improve the reliability, QoS management, and the behavior of time- sensitive traffic in 802.11 networks Provide the tools for coordinating the time-aware operation in Multi- AP environments Not necessarily following/implementing the 802.1 TSN standard TSN use cases (time-critical) may leverage these capabilities for their applications Let s call this Time Sensitive Wireless (not TSN) Submission Slide 14 Inaki Val, MaxLinear

  15. July 2023 doc.: IEEE 802.11-23/1173r1 Summary The term TSN is currently used loosely to refer to both interpretations, leading to possible misunderstandings: a) Generic TSN incorporating 802.11 b) Time Sensitive Wireless (a) would make use of (b), but (b) could exist independently Following the approach for TSN time synchronization over 802.11 with FTM feature Following the 3GPP approach defining Time Sensitive Communications enhancements Submission Slide 15 Inaki Val, MaxLinear

  16. July 2023 doc.: IEEE 802.11-23/1173r1 Conclusion UHR targets reliable and time-sensitive applications UHR is proposing new features which will require time- sensitive tools These new features and tools could enable TSN capabilities We have identified two different interpretations of TSN term in the context of 802.11 a) Generic TSN incorporating 802.11 b) Time Sensitive Wireless 802.11bn should focus on the time-sensitive wireless (TSW) features/capabilities that can help 802.11 usages in both cases stand alone and TSN scenario Submission Slide 16 Inaki Val, MaxLinear

  17. July 2023 doc.: IEEE 802.11-23/1173r1 Proposal UHR should not define time-sensitive features exclusively within the context of TSN Time sensitive features should be primarily intended for improving QoS and reliability within an 802.11 network (i.e. Time Sensitive Wireless) Any work done to leverage these features for TSN extensions will be primarily done by 802.1 TSN is not a synonym for latency improvement Submission Slide 17 Inaki Val, MaxLinear

  18. July 2023 doc.: IEEE 802.11-23/1173r1 References [1] IEEE 802.11-23/0028r6 UHR PAR discussion [2] Kate Meng and et al. (Tencent Technology), RTA report summary , 19/0065r6, March 2019. [3] Liuming Lu and et al. (Oppo), Multi-AP Coordination for Low Latency Traffic Delivery: Usage Scenarios and potential features , 23/0046r2, March 2023. [4] Juan Fang and et al. (Intel), Preemption for Low Latency Application , 23/0092r0, March 2023. [5] Serhat Erkucuk and et al. (Offino), Enhanced Scheduling Method for Low Latency Traffic , 23/0378r0, May 2023. [6] IEEE 802.1 TSN, https://1.ieee802.org/ Submission Slide 18 Inaki Val, MaxLinear

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