Improved sparrow search algorithm for RFID network planning

doi:10.19682/j.cnki.1005-8885.2023.2010

中国邮电高校学报(英文) ›› 2023, Vol. 30 ›› Issue (1): 93-102.doi: 10.19682/j.cnki.1005-8885.2023.2010

• Wireless • 上一篇

Improved sparrow search algorithm for RFID network planning

Zhang Jiangbo, Zheng Jiali, Quan Yixuan, Lin Zihan, Xie Xiaode

1. School of Computer, Electrics and Information, Guangxi University, Nanning 530004, China
2. Guangxi Key Laboratory of Multimedia Communications and Network Technology, Guangxi University, Nanning 530004, China

收稿日期:2021-08-10 修回日期:2022-03-19 接受日期:2023-02-13 出版日期:2023-02-28 发布日期:2023-02-28
通讯作者: Zheng Jiali, E-mail: zjl@gxu.edu.cn E-mail:zjl@gxu.edu.cn
基金资助:
This work was supported by the National Natural Science Foundation of China (61761004).

Improved sparrow search algorithm for RFID network planning

Zhang Jiangbo, Zheng Jiali, Quan Yixuan, Lin Zihan, Xie Xiaode

1. School of Computer, Electrics and Information, Guangxi University, Nanning 530004, China
2. Guangxi Key Laboratory of Multimedia Communications and Network Technology, Guangxi University, Nanning 530004, China

Received:2021-08-10 Revised:2022-03-19 Accepted:2023-02-13 Online:2023-02-28 Published:2023-02-28
Contact: Zheng Jiali, E-mail: zjl@gxu.edu.cn E-mail:zjl@gxu.edu.cn
Supported by:
This work was supported by the National Natural Science Foundation of China (61761004).

摘要/Abstract

摘要： To solve the problem that the performance of the coverage, interference rate, load balance andweak power in the radio frequency identification (RFID) network planning. This paper proposes an elite opposition-based learning and Levy flight sparrow search algorithm (SSA), which is named elite opposition-based learning and Levy flight SSA (ELSSA). First, the algorithm initializes the population by an elite opposed-based learning strategy to enhance the diversity of the population. Second, Levy flight is introduced into the scrounger's position update formula to solve the situation that the algorithm falls into the local optimal solution. It has a probability that the current position is changed by Levy flight. This method can jump out of the local optimal solution. In the end, the proposed method is compared with particle swarm optimization (PSO) algorithm, grey wolf optimzer (GWO) algorithm and SSA in the multiple simulation tests. The simulated results showed that, under the same number of readers, the average fitness of the ELSSA is improved respectively by 3.36%, 5.67% and 18.45%. By setting the different number of readers, ELSSA uses fewer readers than other algorithms. The conclusion shows that the proposed method can ensure a satisfying coverage by using fewer readers and achieving higher comprehensive performance.

关键词: radio frequency identification, network planning, sparrow search algorithm, elite opposition-based learning, Levy flight

Abstract: To solve the problem that the performance of the coverage, interference rate, load balance andweak power in the radio frequency identification (RFID) network planning. This paper proposes an elite opposition-based learning and Levy flight sparrow search algorithm (SSA), which is named elite opposition-based learning and Levy flight SSA (ELSSA). First, the algorithm initializes the population by an elite opposed-based learning strategy to enhance the diversity of the population. Second, Levy flight is introduced into the scrounger's position update formula to solve the situation that the algorithm falls into the local optimal solution. It has a probability that the current position is changed by Levy flight. This method can jump out of the local optimal solution. In the end, the proposed method is compared with particle swarm optimization (PSO) algorithm, grey wolf optimzer (GWO) algorithm and SSA in the multiple simulation tests. The simulated results showed that, under the same number of readers, the average fitness of the ELSSA is improved respectively by 3.36%, 5.67% and 18.45%. By setting the different number of readers, ELSSA uses fewer readers than other algorithms. The conclusion shows that the proposed method can ensure a satisfying coverage by using fewer readers and achieving higher comprehensive performance.

Key words: radio frequency identification, network planning, sparrow search algorithm, elite opposition-based learning, Levy flight

中图分类号:

TP301.6

Zhang Jiangbo, Zheng Jiali, Quan Yixuan, Lin Zihan, Xie Xiaode. Improved sparrow search algorithm for RFID network planning[J]. The Journal of China Universities of Posts and Telecommunications, 2023, 30(1): 93-102.

参考文献

References
[1] GUAN Q, LIU Y, YANG Y P, et al. Genetic approach for network planning in the RFID systems. Proceedings of the 6th International Conference on Intelligent Systems Design and Applications (ISDA'06): Vol 2, 2006, Oct 16 - 18, Jinan, China. Piscataway, NJ, USA: IEEE, 2006: 567 -572.
[2] GONG Y J, SHEN M E, ZHANG J, et al. Optimizing RFID network planning by using a particle swarm optimization algorithm
with redundant reader elimination. IEEE Transactions on Industrial Informatics, 2012, 8(4): 900 -912.
[3] MA L B, HU K Y, ZHU Y L, et al. Cooperative artificial bee colony algorithm for multi-objective RFID network planning. Journal of Network and Computer Applications, 2014, 42: 143 -162.
[4] ZHANG T, LIU J. An efficient and fast kinematics-based algorithm for RFID network planning. Computer Networks, 2017, 121: 13 -24.
[5] HASNAN K, TALIB N H, NAWAWI A. Analysis of gradient-based cuckoo search for the large scale optimal RFID network planning. Proceedings of the 2018 International Conference on Mechanical and Manufacturing Engineering (ICME'18), 2018, Jul 16 - 17, Johor, Malaysia. Journal of Physics: Conference Series, 2019, 1150: Article 012008.
[6] KONG H, YU B. Modeling and optimization of RFID networks planning problem. Wireless Communications and Mobile Computing, 2019, Dec 7: Article ID 2745160.
[7] QUAN Y X, ZHENG J L, LUO W C, et al. Improved grey wolf optimzer for RFID network planning. Computer Science, 2021, 48(1): 253 -257 (in Chinese).
[8] CAO Y, LIU J, XU Z. A hybrid particle swarm optimization algorithm for RFID network planning. Soft Computing, 2021, 25(7): 5747 -5761.
[9] XUE J K, SHEN B. A novel swarm intelligence optimization approach: Sparrow search algorithm. Systems Science and Control Engineering, 2020, 8(1): 22 -34.
[10] TANG W L, ZHANG P, TANG S F. Improved firefly K-means algorithm based on elite opposition-based learning. Computer Engineering and Design, 2019, 40 (11): 3164 - 3169 (in Chinese).
[11] ZHANG C, HE X S, YE Y R. Particle swarm optimization algorithm based on elite strategy and Levy flight. Journal of Xi'an
Polytechnic University, 2018, 32(6): 731 -738 (in Chinese).
[12] JABALLAH A, MEDDEB A. A new variant of cuckoo search algorithm with self adaptive parameters to solve complex RFID network planning problem. Wireless Networks, 2019, 25(4): 1585 -1604.
[13] TANG A D, HAN T, XU D W, et al. UAV path planning method based on chaotic sparrow search algorithm. Computer Applications, 2021, 41(7): 2128 -2136 (in Chinese).
[14] YANG Z S, ZHU C S, GAO Y J. Enhanced fireworks algorithm for RFID network planning. Computer Engineering and Applications, 2017, 53(3): 23 -27 (in Chinese).
[15] JABALLAH A, MEDDEB A. A new algorithm based CSP framework for RFID network planning. Journal of Ambient Intelligence and Humanized Computing, 2021, 12(10): 2905 -2914.

Improved sparrow search algorithm for RFID network planning

Improved sparrow search algorithm for RFID network planning

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