DetNet D. Guo
Internet Draft New H3C Technologies Co., Ltd
Intended status: Informational T. Jiang
Expires: 5 February 2025 China Mobile
S. Xu
X. You
S. Zhu
New H3C Technologies Co., Ltd
5 August 2024
Jitter Reduction Mechanism for DetNet
draft-guo-detnet-jitter-reduction-mechanism-03.txt
Abstract
In large-scale deterministic networks (LDN), App-flows need to span
multiple deterministic network domains, and the latency in multiple
domains is added together. The jitter will be increased. In order to
realize the protection service function, App-flows should be
transmitted on multiple paths. The delay difference in data
transmission on different paths is no different from jitter in end-
to-end services. Jitter generated by various factors needs to be
reduced to meet business requirements.
This document describes the end-to-end jitter reduction mechanism in
an LDN. This mechanism can effectively control the end-to-end jitter
to meet specific business needs and make the planning of multiple
paths for service protection more flexible.
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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Table of Contents
1. Introduction...................................................3
2. Terminology....................................................4
3. Architecture...................................................6
4. Proposal Description...........................................7
4.1. Data-Plane Overview......................................10
4.1.1. Residency delay processing method 1.................10
4.1.2. Residency delay processing method 2.................12
4.1.3. residence time adjustment...........................12
4.2. Control-Plane Overview...................................13
5. Robustness considerations.....................................13
6. Security Considerations.......................................14
7. IANA Considerations...........................................15
8. References....................................................15
8.1. Normative References.....................................15
8.2. Informative References...................................15
9. Acknowledgments...............................................16
10. Authors' Addresses...........................................17
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1. Introduction
+---------+
/ \
+ DetNet3 +
\ /
+---------+
/ \
/ \
+---------+ +---------+
/ \ / \
+ DetNet2 + + DetNet4 +
\ / \ /
+---------+ +---------+
| |
| |
+---------+ +---------+
/ \ / \
+ DetNet1 + + DetNet5 +
\ / \ /
+---------+ +---------+
| |
| |
Talker Listener
Figure 1 Multiple domains
In deterministic networks, as stated in [I-D.ietf-detnet-scaling-
requirements], end-to-end service may across multiple network domains
and adopt a variety of different queuing mechanisms within each
domain. For end-to-end services spanning multiple domains, jitter
exists in various factors:
o Scheduling and traffic admission control at domain boundaries may
cause jitter;
o The jitter generated by queuing and forwarding mechanisms in the
DetNet domain, such as the [IEEE 802.1 QCR] asynchronous shaping
method;
o Flow aggregation generates jitter. In [RFC 8938], the DetNet data
plane also allows for the aggregation of DetNet flows, which can
improve scalability by reducing the per-hop state. When the
aggregated flows are scheduled, the jitter of the flows cannot be
precisely controlled.
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At the same time, according to [I-D.ietf-detnet-scaling-
requirements], large-scale deterministic networks should support
cross-domain asynchronous clocks; in addition, multiple domains may
be heterogeneous networks (such as TSN, DetNet IP and 5GS). The
factors all determine that it is difficult to reduce jitter between
domains through a mechanism similar to CSQF[I-D.chen-detnet-sr-
based-bounded-latency] or TCQF[I-D.draft-eckert-detnet-tcqf]. While
the jitter generated by various factors in the end-to-end
transmission path is accumulated, it may not meet the applications'
requirements on jitter.
This document describes a mechanism to reduce the jitter introduced
by a variety of factors in scaling DetNet.
2. Terminology
The following terminology is introduced in this document:
Actual Delay (ActD): The actual transmission delay of a deterministic
data packet passing through a specified network domain is called the
Actual Time.
Reference Delay (RefD): The maximum delay for packets of DetNet flows
to pass through the DetNet domain.
Fixed delay (FixD): The approximately constant part of the end-to-end
transmission delay of the data packets of the App-flows through the
DetNet.
Path Reference Delay (PthRefD): The maximum end-to-end transmission
delay of data packets of App-flows through the DetNet.
Path Actual Delay (PthActD): The end-to-end actual transmission delay
of a certain packet of App-flows through the DetNet.
Compensation Delay (CompD): The delay required to compensate the
actual delay according to the reference delay.
Clock Source: Used as a clock source for subnet time synchronization.
I-Gw: The ingress gateway of the deterministic subnet.
E-Gw: The egress gateway of the deterministic subnet.
HEAD NODE: The I-Gw of the first DetNet domain accessed by the App-
flows in the DetNet forwarding path is HEAD NODE.
COMPENSATION NODE: This node performs calculation and compensation
for time delay.
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INGRESS-RELAY NODE: The I-Gw gateway of each domain except the HEAD
NODE.
EGRESS-RELAY NODE: The E-Gw gateway of each domain except the
COMPENSATION NODE.
Virtual Clock Reference Plane (VCRP): Provides a frequency
synchronization reference for the clock used for DetNet data plane
[DDP] timing.
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3. Architecture
*------------------------------------------------------------*
/ /
/ /
/ Virtual Clock Reference Plane /
/ (VCRP) /
/ /
*------+----------+----------------------+------------+------*
| | | |
| +----+----+ +----+----+ |
| | | | | |
| | Clock | | Clock | |
| | Source2 | | Source3 | |
| | | | | |
| +---------+ +---------+ |
| / \ / \ |
| / \ / \ |
| +-------+ +-------+ +-------+ +-------+ |
| | I-Gw2 +--+ E-Gw2 +---+ I-Gw3 +--+ E-Gw3 | |
| +---+---+ +-------+ +-------+ +---+---+ |
| | | |
| | | |
| +-------+ +------+ |
| | | |
+---+-----+ | | +----+----+
| | | | | |
| Clock | | | | Clock |
| Source1 | | | | Source4 |
| | | | | |
+---------+ | | +---------+
/ \ | | / \
/ \ | | / \
+-------+ +-------+ | | +-------+ +-------+
| I-Gw1 +--+ E-Gw1 +--+ +----+ I-Gw4 +--+ E-Gw4 |
+---+---+ +-------+ +-------+ +---+---+
| |
| |
Talker Listener
Figure 2 Architecture
In Figure 2, the Clock Source is a part of VCRP. I-Gw1 is HEAD NODE.
E-Gw1, E-Gw2, E-Gw3 are EGRESS-RELAY NODE. I-Gw2, I-Gw3 are INGRESS-
RELAY NODE. E-Gw4 is COMPENSATION NODE.
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The I-Gw gateway of each domain except the HEAD NODE should extract
the packet receiving time, and calculate the actual delay of the
previous domain, and carry it into the packet.
The E-Gw gateway of each domain except the COMPENSATION NODE should
save the sending time information of the domain.
It is difficult to improve the accuracy of time synchronization,
because VCRP may have a large geographical span. Clock source of VCRP
provides time synchronization for each DetNet domain. Time
synchronization is required within each DetNet domain, not between
DetNet domains. Each domain is frequency-synchronized with the clock
source provided by VCRP to avoid excessive deviation caused by each
domain due to the influence of the environment. Because the clock
sources that provide synchronization references for each DetNet
domain in VCRP may not physically connected, it is difficult to
achieve time synchronization in VCRP. On the premise that the
transmission delay in each domain is not large, the frequency
accuracy of the clock used for timing is relatively low. It is
relatively easy for VCRP to provide a stable clock source with a
certain accuracy for each DetNet domain for time synchronization.
Each compensation needs a reference value, and compensation
redundancy must be considered. When a data packet undergoes delay
compensation multiple times, the end-to-end delay will be increased.
No matter where delay compensation is performed, there is still the
possibility that multiple transmitted data after compensation need to
be queued, resulting in queuing delay, which reduces the compensation
effect. Compensating at the very edge of the network aims to provide
a standard way to reduce end-to-end jitter, applicable to various
mechanisms, to achieve the best possible results with the smallest
implementation cost.
4. Proposal Description
Basic idea of the scheme: when establishing a deterministic stream
session, obtain the reference delay of the path, obtain the actual
delay of the data packet during transmission, calculate the
compensation delay according to the reference delay and the actual
transmission delay, and compensate the transmission delay at the
COMPENSATION NODE connected to the Listener. The implementation
principle is described in detail below.
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| | | |
+----------T2------------+ +----------T3------------+
| | | |
+----------T'2-----------+ +----------T'3-----------+
| | | |
| | | |
+--------+--------+------+ +--------+--------+------+
| I-Gw2 | DetNet2| E-Gw2|----+ I-Gw2 | DetNet2| E-Gw2+-+
+----+---+--------+------+ +--------+--------+------+ |
| |
| |
| |
+--------------------+ +---------------------------+
| |
| |
| || || |
+----------T1------------+| |+----------T4------------+
| || || |
+----------T'2-----------+| |+----------T'4-----------+
| || || |
| || || |
+--------+--------+------+| |+--------+--------+------+
| I-Gw2 | DetNet2| E-Gw2++ ++ I-Gw4 | DetNet4| E-Gw4|
+----+---+--------+------+ +--------+--------+---+--+
| |
| |
| |
Talker Listener
Figure 3 The timing model of transmission delay
Figure 3 describes the abstract model of multi-domain transmission
delay segmentation timing, where Tn (n=1~4 in Figure 3) is the
reference delay RefDn of each domain, and this value is obtained
according to the selection of queuing mechanism combined with
engineering applications.
For a specific deterministic path, there is a master clock in the
same domain, and each node in the path will perform time
synchronization with this clock, and finally obtain intra-domain time
synchronization. The reference delay of the end-to-end path is:
PthRefD = FixD + T1 + T2 + T3 + T4.
If service protection is realized by sending copies of the same data
packet through multiple paths, the reference delay of path i is:
PthRefD_i = FixD_i + T1_i + T2_i + T3_i + T4_i.
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Select the reference delay of the path with the largest one as the
common reference delay of all the paths, and the final reference
delay is:
PthRefD = ceil(PthRefD1, PthRefD2, ..., PthRefDn).
Let T'n (n=1~4 in Figure 3) be the actual transmission delay ActD of
a certain data packet in each domain, and it depends on the time
entering the domain and the time of exiting the domain when the data
packet is actually delivered. The residence time in domain can also
be obtained after the data packet is transmitted. Therefore, the
actual transmission delay of this packet is:
PthActD = FixD + T'1 + T'2 + T'3 + T'4.
The delay of the packet needs to be compensated at CompD:
CompD = PthRefD - PthActD
= (PthRefD - FixD) - (T'1 + T'2 + T'3+ T'4).
If service protection is achieved by sending copies of the same data
packet through multiple paths, the actual delay of path i is
PthActD_i = FixD_i + T'1_i + T'2_i + T'3_i + T'4_i.
The delay of the packet needs to be compensated after transmission in
path i is CompD:
CompD = (PthRefD - FixD_i) - (T'1_i + T'2_i + T'3_i + T'4_i)
The formula can be simplified as:
CompD = Cap - (T'1 + T'2 + T'3 + T'4) (Formula 1),
or
CompD_i = Cap_i - (T'1_i + T'2_i + T'3_i +
T'4_i) (Formula 2),
where (PthRefD - FixD) is Cap, and (PthRefD - FixD_i) is Cap_i. Cap
or Cap_i can be obtained directly or indirectly before deploying a
deterministic streaming session. The specific obtaining method will
be added in subsequent updates. Compensation is performed on E-Gw4
according to Formula 1 or Formula 2 when the DetNet data packet is
transmitted.
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4.1. Data-Plane Overview
In the data plane, it is necessary to obtain the reference delay from
the HEAD NODE to the COMPENSATION NODE. During actual transmission,
collect the actual transmission delay in each domain, and compensate
the delay at the COMPENSATION NODE based on the reference delay.
For delay collection, two methods provide the relevant information
required by each gateway:
Method 1: Specify the operation of the subsequent gateway in the HEAD
NODE. After the HEAD NODE identifies the flow, it encapsulates the
relevant information into a data packet, and the subsequent gateway
node performs corresponding operations according to the information
in the data packet. The advantage of this method is that it
simplifies the subsequent gateway configuration, but the disadvantage
is that the overhead is large.
Method 2: Configure the relevant information in the edge gateway
along the path, and the edge gateway node will identify the DetNet
flow and then obtain the information from the configuration for
corresponding operations. The advantage of this method is that the
overhead is small, and the disadvantage is that subsequent gateways
need flow-by-flow configuration.
The specific operation will be supplemented in subsequent updates.
+-------------+ +-------------+ +-------------+
| HEAD +----+EGRESS RELAY +----+INGRESS RELAY+-+
+-------------+ +-------------+ +-------------+ |
|
+-------------------------------------------------------+
|
| +-------------+ +-------------+ +-------------+
+-+EGRESS RELAY +----|INGRESS RELAY+----+COMPENSATION |
+-------------+ +-------------+ +-------------+
Figure 4 Data Flow
4.1.1. Residency delay processing method 1
In order to obtain more accurate residence time, the timestamp is
obtained at a lower layer (for example, the PMA sublayer of
Ethernet). Only the sending timestamp is filled in EGRESS-RELAY,
and the residence time in the domain is not calculated. Calculation
is performed at the INGRESS-RELAY of the next network domain. On
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the one hand, it can reduce the transmission of metadata within the
device, and on the other hand, it can reduce the calculation
implementation of the hardware layer.
The process required for the different roles of the gateway that
DetNet flows pass through is described as follows.
When receiving a packet, the HEAD NODE performs the following
process:
1. Identify the DetNet flow and obtain the cross-domain information
provided by the control plane. This cross-domain information
includes the actions of the subsequent gateways, which can be
encapsulated in the packet or configured by the control plane to
the subsequent gateways.
2. Obtain the time when this node receives the packet.
3. Fill the cross-domain information and the time that this node
receives the packet into the packet.
When receiving a packet, the INGRESS-RELAY NODE performs the
following process:
4. Identify the DetNet flow and obtain the cross-domain information
provided by the control plane from the packet or from the
configuration. The gateway takes actions according to the
information.
The main procedure is:
a) Obtain the time when this node receives the packet.
b) Calculate the residence delay of the previous domain.
5. Fill the residence delay of the previous domain and the time when
this node receives the packet into the packet.
When receiving a packet, the EGRESS-RELAY NODE performs the following
process:
1. Identify the DetNet flow and obtain the cross-domain information
provided by the control plane from the packet or from the
configuration. The gateway takes actions according to the
information.
The main procedure is:
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a) Fill the sending time of the packet into the specified position of
the packet when a packet is sent.
When receiving a packet, the COMPENSATION NODE performs the following
process:
1. Identify the DetNet flow and obtain the cross-domain information
provided by the control plane from the packet or from the
configuration. The gateway takes actions according to the
information.
The main procedure is:
a) Obtain the time when this node receives the packet and calculate
the residence delay of the packet in this domain.
b) Accumulate the residence delays of the packet in each domain.
c) Calculate the compensation delay.
2. Send out the packet after completing the compensation.
4.1.2. Residency delay processing method 2
The basic processing is similar to Section 4.2.1. The sending
timestamp is obtained in EGRESS-RELAY, and combined with the
receiving timestamp passed by the metadata, the residence time in the
domain is calculated. More metadata is required to be transferred
within the device. At the same time, the device needs additional
hardware layer calculation implementation, which needs to be
carefully implemented to calculate the processing delay after
obtaining the timestamp into the residence delay.
4.1.3. residence time adjustment
In scenarios with high accuracy(tightly bounded jitter) requirements,
it is necessary to consider the timing frequency offset of the clock
source of each domain relative to the final compensation node. For
example, if 10ms in a certain domain is equivalent to 10.1ms in the
compensation node, then the dwell delay needs to be calculated in the
domain, and an adjustment of 1% is added to the calculated value.
This adjustment ratio needs to be obtained before deploying
deterministic flows, and should be considered to be stored in the
message or configured in EGRESS-RELAY or INGRESS-RELAY. When topology
changes affect this adjustment ratio, corresponding updates need to
be made.
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4.2. Control-Plane Overview
The control plane needs to cooperate with the data plane to complete
the following transactions:
1. Define gateway operations along the path and configure data plane
gateways.
2. Cooperate with the data plane to complete the measurement and
calculate the reference delay.
3. Configure the reference delay information to the HEAD NODE or
COMPENSATION NODE.
4. Maintenance during runtime: periodically collect the reference
delay of each domain and calculate the reference delay of the
whole path, and refresh the reference delay to the HEAD NODE or
COMPENSATION NODE.
For delay collection, the control plane has two methods to cooperate
with the data plane to supply the relevant information required by
each gateway:
Method 1: The control plane globally distributes the gateway ID, and
configures the ID to each edge gateway. The control plane configures
the collected delay information to the HEAD NODE.
Method 2: The control plane configures flow-by-flow operations to the
domain edge gateways along the path.
5. Robustness considerations
In a large-scale network, not only the topology changes, but also the
transmission delay, which is regarded as a constant part, changes due
to environmental factors.
In response to topology changes, a certain amount of redundancy is
reserved in the reference value of the compensation delay. For
example, in the multi-path service protection that implements PREOF,
if one of the paths fails, the transmission delay of the alternative
path increases by 1ms (about 200 kilometers). However, if the upper
limit of the reference delay used for compensation reserves a
redundancy of 1ms , after compensation, the business cannot perceive
this change.
However, if the transmission delay considered to be a constant part
changes due to environmental factors, the upper limit of the
reference delay for compensation needs to be adjusted. Considering
that the change in transmission delay caused by environmental changes
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is a gradual change, it is feasible to regularly maintain the
reference value of the compensation delay. The method of collecting
reference delays is described in detail in [I-D.detnet-compensation-
reference].
Before deploying deterministic business flows, it is necessary to
establish a service protection group between HN and CN. After
establishing the service protection group, CN sends the Req_i message
to HN through any path, and HN constructs the response message Ack_i
on each path as described above (i=1~n). PthRefD and Cap_i of each
path are calculated on CN to compensate for the delay of
deterministic flow. After deploying the deterministic flow, CN
periodically sends the Req_i message to HN through any path, and HN
constructs the response message Ack_i on each path as described above
(i=1~n). FixD_i is calculated on CN, and then Cap_i is calculated.
As the transmission delay of the line is asymptotic due to
environmental changes, there is an accumulation process. Therefore,
it is feasible to periodically update Cap_i. The compensation
standard PthRefD remains unchanged, and the reference delay value
adjusts with the line change, providing real-time compensation for
variable delays. Therefore, within a bounded time limit, the
application will not perceive the accumulated changes. The refresh
cycle of Cap_i depends on the precision that the business needs to
achieve and the speed of environmental changes.
Fault isolation will occur first. Therefore, when a fault occurs, not
all protected paths will fail, and the application will not perceive
the change in transmission delay. After recovery, the new Cap_i is
updated before the isolation is lifted. As long as the new path
length does not exceed PthRefD, the application will not perceive the
fault.
When calculating the compensation delay for each path, suppose a data
packet passes through path i and the residence delay in each domain
is ActD_i (ActD_i is a variable delay, which may not be the same each
time it is obtained after transmission). If the upper limit of the
compensation delay is Cap_i, then the delay to be compensated is
CompD_i = Cap_i - ActD_i.
Cap_i can be sent to the HN node, encapsulated into the deterministic
flow data packet, and used in CN for delay compensation by obtaining
Cap_i and ActD_i from the data packet; or Cap_i can be sent to the
flow-related compensation information table on the CN node for delay
compensation.
6. Security Considerations
TBD
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7. IANA Considerations
TBD
8. References
8.1. Normative References
[RFC8655] Finn, N., Thubert, P., Varga, B., and J. Farkas,
"Deterministic Networking Architecture", RFC 8655, DOI
10.17487/RFC8655, October 2019, <https://www.rfc-
editor.org/info/rfc8655>.
[IEEE802.1Qcr] IEEE, "IEEE Standard for Local and Metropolitan
AreaNetworks -- Bridges and Bridged Networks - Amendment
34:Asynchronous Traffic Shaping", IEEE 802.1Qcr-2020, DOI
10.1109/IEEESTD.2020.9253013, 6 November
2020,<https://doi.org/10.1109/IEEESTD.2020.9253013>.
[IEEE802.1AS] IEEE Time-Sensitive Networking (TSN) Task Group., "IEEE
Std 802.1AS-2020: IEEE Standard for Local and Metropolitan
Area Networks - Timing and Synchronization for Time
Sensitive Applications ", 2020.
[IEEE802.1Qci] IEEE Time-Sensitive Networking (TSN) Task Group.,
"IEEE Std 802.1Qci-2017: IEEE Standard for Local and
Metropolitan Area Networks - Bridges and Bridged Networks-
Amendment 28: Per-Stream Filtering and Policing", 2017.
8.2. Informative References
[I-D.ietf-detnet-scaling-requirements] Liu, P., Li, Y., Eckert, T.,
Xiong, Q., and J. Ryoo, "Requirements for Large-Scale
Deterministic Networks", draft-liu-detnet-large-scale-
requirements-05 (work in progress), October 2022.
[I-D.chen-detnet-sr-based-bounded-latency] Chen, M., Geng, X., and Z.
Li, "Segment Routing (SR) Based Bounded Latency", Work in
Progress, Internet-Draft, draft-chen-detnet-sr-based-
bounded-latency, 3 March 2023,
<https://datatracker.ietf.org/doc/draft-chen-detnet-sr-
based-bounded-latency/>
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[I-D.eckert-detnet-tcqf] Eckert, T. , Bryant, S., and A. G. Malis,
"Deterministic Networking (DetNet) Data Plane - Tagged
Cyclic Queuing and Forwarding (TCQF) for bounded latency
with low jitter in large scale DetNets",
https://datatracker.ietf.org/doc/draft-eckert-detnet-tcqf/
[I-D.ietf-detnet-mpls-over-ip-preof] Varga, B., Farkas, J., Malis,
A., "Deterministic Networking(DetNet): DetNet PREOF via
MPLS over UDP/IP", Work in Progress, Internet-Draft,
draft-ietf-detnet-mpls-over-ip-preof-02, 6 November 2022,
< https://www.ietf.org/archive/id/draft-ietf-detnet-mpls-
over-ip-preof-02.txt>.
[I-D.ietf-detnet-controller-plane-framework] Malis, A., Geng, X.,
Chen, M., Qin, F., arga, B., "Deterministic Networking
(DetNet) Controller Plane Framework" , Work in Progress,
Internet-Draft, draft-ietf-detnet-controller-plane-
framework-02, 29 June 2022,
<https://www.ietf.org/archive/id/draft-ietf-detnet-
controller-plane-framework-02.txt>.
[I-D.detnet-compensation-reference] Guo, D. You, X., Liu.R,
Zhu, S., "Compensation Reference for Jitter Reduction
Mechanism", Work in Progress, Internet-Draft, draft-guo-
detnet-compensation-reference-00.txt, 11 December 2023,
<https://www.ietf.org/archive/id/draft-guo-detnet-
compensation-reference-00.txt>
9. Acknowledgments
The editor wishes to thank and acknowledge the following contributors
for contributing text to this document.
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Rubing Liu
New H3C Technologies Co., Ltd
100094
Email: liurubing@h3c.com
Ning Pan
New H3C Technologies Co., Ltd
100094
Email: panning@h3c.com
Xusheng Chen
New H3C Technologies Co., Ltd
100094
Email: cxs@h3c.com
Wei Wang
New H3C Technologies Co., Ltd
100094
Email: david_wang@h3c.com
10. Authors' Addresses
Daorong Guo
New H3C Technologies Co., Ltd
Beijing
100094
China
Email: guodaorong@h3c.com
Tianji Jiang
China Mobile
Email: tianjijiang@chinamobile.com
Shenchao Xu
New H3C Technologies Co., Ltd
Hangzhou
310052
China
Email: xushenchao@h3c.com
XUEJUN YOU
New H3C Technologies Co., Ltd
Beijing
100094
China
Email: yoe@h3c.com
Shiyin Zhu
New H3C Technologies Co., Ltd
Guo, et al. Expires February 5, 2025 [Page 17]
Internet-Draft Jitter Reduction Mechanism for DetNet August 2024
Beijing
100094
China
Email: zhushiyin@h3c.com
Guo, et al. Expires February 5, 2025 [Page 18]