Reinforcement Learning Based Control Domain Division in LEO Satellite Networks

Feilong Tang; Xue Li; Long Chen; Jiacheng Liu; Ming Gao; Yanqin Yang; Wenchao Xu; Heteng Zhang

doi:10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

Reinforcement Learning Based Control Domain Division in LEO Satellite Networks

Feilong Tang, Xue Li, Long Chen, Jiacheng Liu, Ming Gao, Yanqin Yang, Wenchao Xu, Heteng Zhang

School of Data Science and Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The performance of SDN-based LEO satellite networks significantly depends on the control domain division approaches. The dynamical topology in LEO networks results in the time-varying delay for network management. Therefore, the control domain division is very challenging and should be dynamical. In this paper, we propose a control domain division approach based on reinforcement learning (RL), which aims at reducing the average management delay of controllers during the control period, and as well as minimizing the number of control domain handovers. Firstly, we analyze the factors that need to be paid attention to in controller deployment, such as delay, load and controller switching cost, and formulate the controller deployment. By relaxing the constraints, we prove that the problem is NP-hard. Secondly, we propose an approach that considers future motion trajectory based on reinforcement learning (FMT _ RL) to deploy controllers. Since the dimension of the neural network in reinforcement learning is fixed, we use the improved K-Means algorithm to select the set of mechanisms to determine the dimension of the neural network. Particularly, in order to obtain the node composition control domain, the observation including both future motion trajectory and history controller selection information are input into the neural network to calculate the control domain division results. The experimental results demonstrate that our approach significantly outperforms related approaches, with better stability and average control cost.

Original language	English
Title of host publication	Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023
Editors	Jinjun Chen, Laurence T. Yang
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	303-310
Number of pages	8
ISBN (Electronic)	9798350330014
DOIs	https://doi.org/10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049
State	Published - 2023
Event	25th IEEE International Conferences on High Performance Computing and Communications, 9th International Conference on Data Science and Systems, 21st IEEE International Conference on Smart City and 9th IEEE International Conference on Dependability in Sensor, Cloud and Big Data Systems and Applications, HPCC/DSS/SmartCity/DependSys 2023 - Melbourne, Australia Duration: 13 Dec 2023 → 15 Dec 2023

Publication series

Name	Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023

Conference

Conference	25th IEEE International Conferences on High Performance Computing and Communications, 9th International Conference on Data Science and Systems, 21st IEEE International Conference on Smart City and 9th IEEE International Conference on Dependability in Sensor, Cloud and Big Data Systems and Applications, HPCC/DSS/SmartCity/DependSys 2023
Country/Territory	Australia
City	Melbourne
Period	13/12/23 → 15/12/23

Keywords

Control domain division
Dynamical topology
LEO
Reinforcement learning
SDN

Access to Document

10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

Cite this

Tang, F., Li, X., Chen, L., Liu, J., Gao, M., Yang, Y., Xu, W., & Zhang, H. (2023). Reinforcement Learning Based Control Domain Division in LEO Satellite Networks. In J. Chen, & L. T. Yang (Eds.), Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023 (pp. 303-310). (Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

Tang, Feilong ; Li, Xue ; Chen, Long et al. / Reinforcement Learning Based Control Domain Division in LEO Satellite Networks. Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023. editor / Jinjun Chen ; Laurence T. Yang. Institute of Electrical and Electronics Engineers Inc., 2023. pp. 303-310 (Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023).

@inproceedings{a3aad1b5e2bd4ac1bf5a12cd0d5559f2,

title = "Reinforcement Learning Based Control Domain Division in LEO Satellite Networks",

abstract = "The performance of SDN-based LEO satellite networks significantly depends on the control domain division approaches. The dynamical topology in LEO networks results in the time-varying delay for network management. Therefore, the control domain division is very challenging and should be dynamical. In this paper, we propose a control domain division approach based on reinforcement learning (RL), which aims at reducing the average management delay of controllers during the control period, and as well as minimizing the number of control domain handovers. Firstly, we analyze the factors that need to be paid attention to in controller deployment, such as delay, load and controller switching cost, and formulate the controller deployment. By relaxing the constraints, we prove that the problem is NP-hard. Secondly, we propose an approach that considers future motion trajectory based on reinforcement learning (FMT \_ RL) to deploy controllers. Since the dimension of the neural network in reinforcement learning is fixed, we use the improved K-Means algorithm to select the set of mechanisms to determine the dimension of the neural network. Particularly, in order to obtain the node composition control domain, the observation including both future motion trajectory and history controller selection information are input into the neural network to calculate the control domain division results. The experimental results demonstrate that our approach significantly outperforms related approaches, with better stability and average control cost.",

keywords = "Control domain division, Dynamical topology, LEO, Reinforcement learning, SDN",

author = "Feilong Tang and Xue Li and Long Chen and Jiacheng Liu and Ming Gao and Yanqin Yang and Wenchao Xu and Heteng Zhang",

note = "Publisher Copyright: {\textcopyright} 2023 IEEE.; 25th IEEE International Conferences on High Performance Computing and Communications, 9th International Conference on Data Science and Systems, 21st IEEE International Conference on Smart City and 9th IEEE International Conference on Dependability in Sensor, Cloud and Big Data Systems and Applications, HPCC/DSS/SmartCity/DependSys 2023 ; Conference date: 13-12-2023 Through 15-12-2023",

year = "2023",

doi = "10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049",

language = "英语",

series = "Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

pages = "303--310",

editor = "Jinjun Chen and Yang, \{Laurence T.\}",

booktitle = "Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023",

address = "美国",

}

Tang, F, Li, X, Chen, L, Liu, J, Gao, M, Yang, Y, Xu, W & Zhang, H 2023, Reinforcement Learning Based Control Domain Division in LEO Satellite Networks. in J Chen & LT Yang (eds), Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023. Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023, Institute of Electrical and Electronics Engineers Inc., pp. 303-310, 25th IEEE International Conferences on High Performance Computing and Communications, 9th International Conference on Data Science and Systems, 21st IEEE International Conference on Smart City and 9th IEEE International Conference on Dependability in Sensor, Cloud and Big Data Systems and Applications, HPCC/DSS/SmartCity/DependSys 2023, Melbourne, Australia, 13/12/23. https://doi.org/10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

Reinforcement Learning Based Control Domain Division in LEO Satellite Networks. / Tang, Feilong; Li, Xue; Chen, Long et al.
Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023. ed. / Jinjun Chen; Laurence T. Yang. Institute of Electrical and Electronics Engineers Inc., 2023. p. 303-310 (Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Reinforcement Learning Based Control Domain Division in LEO Satellite Networks

AU - Tang, Feilong

AU - Li, Xue

AU - Chen, Long

AU - Liu, Jiacheng

AU - Gao, Ming

AU - Yang, Yanqin

AU - Xu, Wenchao

AU - Zhang, Heteng

PY - 2023

Y1 - 2023

N2 - The performance of SDN-based LEO satellite networks significantly depends on the control domain division approaches. The dynamical topology in LEO networks results in the time-varying delay for network management. Therefore, the control domain division is very challenging and should be dynamical. In this paper, we propose a control domain division approach based on reinforcement learning (RL), which aims at reducing the average management delay of controllers during the control period, and as well as minimizing the number of control domain handovers. Firstly, we analyze the factors that need to be paid attention to in controller deployment, such as delay, load and controller switching cost, and formulate the controller deployment. By relaxing the constraints, we prove that the problem is NP-hard. Secondly, we propose an approach that considers future motion trajectory based on reinforcement learning (FMT _ RL) to deploy controllers. Since the dimension of the neural network in reinforcement learning is fixed, we use the improved K-Means algorithm to select the set of mechanisms to determine the dimension of the neural network. Particularly, in order to obtain the node composition control domain, the observation including both future motion trajectory and history controller selection information are input into the neural network to calculate the control domain division results. The experimental results demonstrate that our approach significantly outperforms related approaches, with better stability and average control cost.

AB - The performance of SDN-based LEO satellite networks significantly depends on the control domain division approaches. The dynamical topology in LEO networks results in the time-varying delay for network management. Therefore, the control domain division is very challenging and should be dynamical. In this paper, we propose a control domain division approach based on reinforcement learning (RL), which aims at reducing the average management delay of controllers during the control period, and as well as minimizing the number of control domain handovers. Firstly, we analyze the factors that need to be paid attention to in controller deployment, such as delay, load and controller switching cost, and formulate the controller deployment. By relaxing the constraints, we prove that the problem is NP-hard. Secondly, we propose an approach that considers future motion trajectory based on reinforcement learning (FMT _ RL) to deploy controllers. Since the dimension of the neural network in reinforcement learning is fixed, we use the improved K-Means algorithm to select the set of mechanisms to determine the dimension of the neural network. Particularly, in order to obtain the node composition control domain, the observation including both future motion trajectory and history controller selection information are input into the neural network to calculate the control domain division results. The experimental results demonstrate that our approach significantly outperforms related approaches, with better stability and average control cost.

KW - Control domain division

KW - Dynamical topology

KW - LEO

KW - Reinforcement learning

KW - SDN

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U2 - 10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

DO - 10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

M3 - 会议稿件

AN - SCOPUS:85189857887

T3 - Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023

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EP - 310

BT - Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023

A2 - Chen, Jinjun

A2 - Yang, Laurence T.

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 25th IEEE International Conferences on High Performance Computing and Communications, 9th International Conference on Data Science and Systems, 21st IEEE International Conference on Smart City and 9th IEEE International Conference on Dependability in Sensor, Cloud and Big Data Systems and Applications, HPCC/DSS/SmartCity/DependSys 2023

Y2 - 13 December 2023 through 15 December 2023

ER -

Tang F, Li X, Chen L, Liu J, Gao M, Yang Y et al. Reinforcement Learning Based Control Domain Division in LEO Satellite Networks. In Chen J, Yang LT, editors, Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023. Institute of Electrical and Electronics Engineers Inc. 2023. p. 303-310. (Proceedings - 2023 IEEE International Conference on High Performance Computing and Communications, Data Science and Systems, Smart City and Dependability in Sensor, Cloud and Big Data Systems and Application, HPCC/DSS/SmartCity/DependSys 2023). doi: 10.1109/HPCC-DSS-SmartCity-DependSys60770.2023.00049

Reinforcement Learning Based Control Domain Division in LEO Satellite Networks

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