面向大规模确定性网络的全局循环排队与转发机制

doi:10.11959/j.issn.1000-0801.2021240

Abstract

Abstract:

Delay and jitter sensitive industrial control and remote driving application-driven network by best-effort to deterministic service.To meet the deterministic application of delay and jitter demands, industry and academia have conducted detailed research on stream filtering shaping and queue forwarding control, implementing microsecond delay and microsecond jitter of light load steady in small-scale ethernet environment.However, the study seldom considers the effects of long-distance topology change, transmission delay fluctuations and short-time traffic overloads, challenging to meet deterministic requirements under large-scale backbone networks.For this challenge, based on cyclic queuing and forwarding, considers source-destination path properties and deterministic traffic intensity, the global cyclic queuing and forwarding three-queue was proposed.The deterministic network simulation system was based on OMNeT++.Experiments compare queue forwarding control mechanisms such as CQF, CQF-three and GCQF-three.Results show that GCQF-three can timely adjust the gatecontrol and queueing priority according to the deterministic traffic state, achieves the best in delay, jitter and network utilization.

Key words: deterministic network, large-scale backbone network, CQF, traffic shaper

CLC Number:

TP393

Yijun MO, Zihan YANG, Huiyu LIU, Tianliu HE. Global cyclic queuing and forwarding mechanism for large-scale deterministic networks[J]. Telecommunications Science, 2021, 37(10): 55-65.

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References 15

[1]	戴彬, 曹园园, 莫益军 . 未来网络场景及需求分析综述[J]. 电信科学, 2019,35(8): 39-48.
	DAI B , CAO Y Y , MO Y J . A survey on future networks:application scenarios and requirements analysis[J]. Telecommunications Science, 2019,35(8): 39-48.
[2]	黄韬, 汪硕, 黄玉栋 ,等. 确定性网络研究综述[J]. 通信学报, 2019,40(6): 160-176.
	HUANG T , WANG S , HUANG Y D ,et al. Survey of the deterministic network[J]. Journal on Communications, 2019,40(6): 160-176.
[3]	MOHAMMADPOUR E , STAI E , MOHIUDDIN M ,et al. Latency and backlog bounds in time-sensitive networking with credit based shapers and asynchronous traffic shaping[C]// 2018 30th International Teletraffic Congress (ITC 30).September 3-7,2018,Vienna,Austria. IEEE, 2018: 1-6.
[4]	NASRALLAH A , THYAGATURU A S , ALHARBI Z ,et al. Performance comparison of IEEE 802.1 TSN time aware shaper (TAS) and asynchronous traffic shaper (ATS)[J]. IEEE Access, 2019(7): 44165-44181.
[5]	ZHOU Z F , YAN Y , BERGER M ,et al. Analysis and modeling of asynchronous traffic shaping in time sensitive networks[C]// Proceedings of 2018 14th IEEE International Workshop on Factory Communication Systems (WFCS). Piscataway:IEEE Press, 2018: 1-4.
[6]	NASRALLAH A , BALASUBRAMANIAN V , THYAGATURU A ,et al. Large scale deterministic networking:a simulation evaluation[EB]. 2019.
[7]	郑秀丽, 蒋胜, 王闯 ,等. 对网络技术跨代发展的思考:网络5.0[J]. 信息通信技术, 2017,11(6): 37-44.
	ZHENG X L , JIANG S , WANG C ,et al. A potential direction of next generation data communication network—network 5.0[J]. Information and Communications Technologies, 2017,11(6): 37-44.
[8]	黄韬, 霍如, 刘江 ,等. 未来网络发展趋势与展望[J]. 中国科学:信息科学, 2019,49(8): 941-948.
	HUANG T , HUO R , LIU J ,et al. Development trends and prospects of future networks[J]. Scientia Sinica (Informationis), 2019,49(8): 941-948.
[9]	LIN Y H , JIN X , ZHANG T ,et al. Queue assignment for fixed-priority real-time flows in time-sensitive networks:Hardness and algorithm[J]. Journal of Systems Architecture, 2021,116: 102141.
[10]	NASRALLAH A , THYAGATURU A S , ALHARBI Z ,et al. Ultra-low latency (ULL) networks:the IEEE TSN and IETF DetNet standards and related 5G ULL research[J]. IEEE Communications Surveys ＆ Tutorials, 2019,21(1): 88-145.
[11]	PUTTNIES H , DANIELIS P , JANCHIVNYAMBUU E ,et al. A simulation model of IEEE 802.1AS gPTP for clock synchronization in OMNeT++[C]// EasyChair.[S.l.:s.n.], 2018: 63-72.
[12]	BOROUJENY M K , MARK B L , EPHRAIM Y . Stochastic traffic regulator for end-to-end network delay guarantees[C]// Proceedings of ICC 2020 - 2020 IEEE International Conference on Communications (ICC). Piscataway:IEEE Press, 2020: 1-6.
[13]	Alexej Grigorjew , Florian Metzger , Tobias Ho?feld ,et al. Asynchronous traffic shaping with jitter control[EB]. 2020.
[14]	THIELE D , ERNST R . Formal worst-case timing analysis of Ethernet TSN's burst-limiting shaper[C]// Proceedings of the 2016 Design,Automation ＆ Test in Europe Conference ＆Exhibition (DATE). Piscataway:IEEE Press, 2016: 187-192.
[15]	ADDANKI V , IANNONE L . Moving a step forward in the quest for Deterministic Networks (DetNet)[C]// 2020 IFIP Networking Conference (Networking). Piscataway:IEEE Press, 2020: 458-466.

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类型	符号	描述
输入	Sid	流标识
	Pid_i	路径标识
输出	T	门控周期
	Repeat_k	单位周期调蓄次数
过程	Exp D_i	确定性流预期时延
	N_i	确定性总跳数
	Tr _ij	确定性流预期总流量
	Exp J_i	确定性流预期抖动
	Hop_i	路径下游总跳数
	Length_i	路径下游总长
	TTL_ij	下游逐跳往返时间
	Cap _ij	下游逐跳队列容量
	Ratio _ij	下游跳队列负载率

Global cyclic queuing and forwarding mechanism for large-scale deterministic networks

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