Urban rail transit, as an important part of a city, mainly includes a series of rail related transportation systems such as subway systems, light rail systems, and trams. It has the advantages of energy conservation, land saving, large traffic volume, and almost pollution-free, and is the backbone of urban public transportation. However, there are many problems in the operation and maintenance of urban rail transit vehicles, which require a series of means to assist in their management. Therefore, this article would design an intelligent operation and maintenance system to assist in the management of urban rail transit vehicles. After a series of research and design in this article, the experimental product was finally applied to a parking lot in a certain city for testing. Compared with another parking lot, the difference in traffic flow before the experiment was not significant, with only about 270 times. After the experimental subjects were loaded with the new system, the average traffic flow reached 305.4 vehicles, while the control group only had 272.7 vehicles. Such a significant increase in traffic flow undoubtedly reflects the practicality of the new system.

Zhihe Wu, Ku Qian. Design of Intelligent Operation and Maintenance System for Urban Rail Transit Vehicles Based on IoT-5G Technology. Academic Journal of Engineering and Technology Science (2023) Vol. 6, Issue 9: 49-56. https://doi.org/10.25236/AJETS.2023.060908.

[1] Chettri Lalit, Rabindranath Bera. A comprehensive survey on Internet of Things (IoT) toward 5G wireless systems. IEEE Internet of Things Journal, 2019, 7(1):16-32

[2] Dolgui Alexandre, Dmitry Ivanov. 5G in digital supply chain and operations management: Fostering flexibility, end-to-end connectivity and real-time visibility through internet-of-everything. International Journal of Production Research, 2022, 60(2): 442-451

[3] Xiao M L, Du X W, Cai L Y, Yong W. Design and implementation of radio frequency power amplifier for 5G communication base station. Journal of Electronic Measurement and Instrumentation, 2022, 36(12):244-252

[4] Siriwardhana Yushan, et al. A survey on mobile augmented reality with 5G mobile edge computing: architectures, applications, and technical aspects. IEEE Communications Surveys & Tutorials2021, 23(2): 1160-1192

[5] Tao J S, et al. The impact of Internet of Things supported by emerging 5G in power systems: A review. CSEE Journal of Power and Energy Systems, 2019, 6(2): 344-352

[6] Mao S Q, Hong J, Ren H, Ma X, Xu J J. 5G mobile edge computing task unloading method for power Internet of Things. Electrical Measurement and Instrumentation, 2022, 59(2):105-111

[7] Bešinović Nikola. Resilience in railway transport systems: a literature review and research agenda. Transport Reviews, 2020, 40(4): 457-478

[8] Abduljabbar Rusul, et al. Applications of artificial intelligence in transport: An overview. Sustainability, 2019, 11(1):1-24

[9] Liu Y, Chao Y, Li J, Xie S L, Zhang Y. Intelligent edge computing for IoT-based energy management in smart cities. IEEE network, 2019, 33(2): 111-117

[10] Zhu F H, Lv Y S, Chen Y Y, Wang X, Xiong G, Wang F Y. Parallel transportation systems: Toward IoT-enabled smart urban traffic control and management. IEEE Transactions on Intelligent Transportation Systems, 2019, 21(10): 4063-4071

[11] Wijethilaka Shalitha, Madhusanka Liyanage. Survey on network slicing for Internet of Things realization in 5G networks. IEEE Communications Surveys & Tutorials, 2021, 23(2): 957-994

[12] Deng B, Xu J J, Gao J, Zhu J W. Analysis of Monitoring Content for Intelligent Operation and Maintenance Construction of Urban Rail Transit. Information Technology, 2022, 51(3):4-11

[13] Guo J W, Si J M, Zhao M L, Zhang L Y. Intelligent operation and maintenance system for urban rail transit vehicles based on full element and full process data fusion. Urban Mass Transit, 2022, 25(1):210-215

[14] Wang W. Internet of Things Communication Technology and Challenges Based on 5G Network. Internet Communication, 2022, 24(22):13-15

[15] Lu Z P, Chen F C, Cheng G Z. Design and implementation of the controller scheduling-time in SDN. Chinese Journal of Network and Information Security, 2018, 4(1):36-44

[16] Gong F, Cheng W B. Development Status and Challenges of Network Functions Virtualization. Industrialization, 2018, 8(6):45-50

[17] Ma H Y, Zhou W, Fu Y, Shao Y P, Li D. Discussion on the evolution of architecture of the core network of cellular Internet of things. Journal of Electronics and Information Technology, 2022, 44(9):8

[18] Ai X Y, Traceability and Abnormal Data Warning System Based on Blockchain and 5G Internet of Things. Electronic Design Engineering, 2020, 28(10):108-112

[19] Chen F T, Tang C, Liu Y F. Energy efficiency optimization based on NOMA IoT communication. Communication and Network, 2018, 44(7):117-121

[20] Xiang X Y. Research on Task Access Security Authentication of Power Internet of Things Terminal Based on 5G Data Coding Algorithm. Network & Communication Technology, 2023, 45(1):81-83

[21] Lv, Zhihan, Liang Qiao, and Sun You. "6G-Enabled Network in Box for Internet of Connected Vehicles." IEEE Transactions on Intelligent Transportation Systems (2020). 

[22] Reddy, M. R., Srinivasa, K. G., and Reddy, B. E. 2018. "Smart Vehicular System Based on the Internet of Things" Journal of Organizational and End User Computing (30:3), pp. 45-62.