Sage Journals: Discover world-class research

Abstract

To address the issue of excessive energy consumption in traditional lighting control systems, this study proposes a segmented dynamic tunnel lighting (SDTL) control system based on a fuzzy neural network (FNN) optimized by the sparrow search algorithm (SSA). When sensors detect a vehicle entering the tunnel, the SSA-FNN model dynamically predicts the required luminance for six tunnel segments including threshold zone one (TH1), threshold zone two (TH2), transition zone (TR), interior zone (IN), exit zone one (EX1) and exit zone two (EX2), by integrating real-time data on tunnel exterior luminance, vehicle speed and traffic volume. If no vehicles are present in the tunnel or within a specific tunnel segment, the lighting control system adjusts the luminaires in that segment to their base illumination power. Experimental results demonstrate that the proposed SDTL system achieves an overall energy-saving rate of 71.5%, outperforming the traditional dynamic tunnel lighting system at 58.0% and the manual segmented tunnel lighting system at 47.9%. Key findings include: (1) lighting demand in the TH1 and TH2 segments is predominantly influenced by exterior luminance in a tunnel, whereas in the segment, it is more sensitive to traffic volume and vehicle speed; and (2) due to the higher lighting requirements caused by the ‘black hole effect’, the energy-saving performance in the TH1, TH2 and TR segments is relatively lower compared to the IN, EX1 and EX2 segments. These insights provide valuable guidance for optimizing tunnel lighting strategies through zone-specific adaptive control, contributing to the development of sustainable transportation infrastructure.

Get full access to this article

View all access options for this article.

References

Zeng

, et al. Traffic safety improvement via optimizing light environment in highway tunnels. International Journal of Environmental Research and Public Health 2022; 19: 8517.

Cai

Fang

Tian

, et al. Research on energy saving in highway tunnel lighting. In Liu

, editor. 2024 the 8th International Conference on Energy and Environmental Science (ICEES 2024). Cham: Springer Nature Switzerland, 2024: 599–610.

Ministry of Transport of the People’s Republic of China. Statistical bulletin on the development of the transportation industry in 2022. Retrieved 19 December 2024 from https://xxgk.mot.gov.cn/2020/jigou/zhghs/202306/t20230615_3847023.html

Liu

Xin

Liu

, et al. Cooling and lighting effects of new plastic optical fiber lighting system based on high-transmittance heat-insulating film. Energy and Buildings 2024; 307: 113972.

Ministry of Transport of the People’s Republic of China. Guidelines for Design of Lighting of Highway Tunnels. JTG/T D70/2-01-2014. Beijing: China Communications Press, 2016.

Guo

Hui

Application of intelligent lighting control systems in highway tunnels. China Transportation Information Industry 2010; (10): 91–94.

China Journal of Highway and Transport, Editorial Department. Review of academic research on China’s traffic tunnel engineering & middot; 2022. China Journal of Highway and Transport 2022; 35: 1–40.

Chen

Zeng

, et al. Research on energy-saving lighting standards for the interior zone of highway tunnels in the western Sichuan plateau. Journal of Underground Space and Engineering 2021; 17: 457–462.

Nagai

Ishida

Nakagawa

Energy-saving lighting system for road tunnel. Retrieved 19 December 2024 from https://www.semanticscholar.org/paper/Energy-saving-lighting-system-for-road-tunnel-Nagai-Ishida/9bec7618c76d4eb87dab4c53ef257b8203d8d255

10.

Huang

Luo

Energy saving tunnel lighting system based on PLC. 2006 China International Conference on Electricity Distribution (CICED 2006), Beijing, China, 2006: CP0414.

11.

Sha

Research on energy-saving technology of LED light sources in tunnel lighting of Huangyan expressway. Highway Engineering 2018; 43: 299–303.

12.

Yang

Fan

Wang

, et al. Application of fuzzy control method in a tunnel lighting system. Mathematical and Computer Modelling 2011; 54: 931–937.

13.

Musa

Nallagownden

Chiu

, et al. Design and development of intelligent adaptive tunnel lighting system. 2015 IEEE Conference on Energy Conversion (CENCON), Johor Bahru, Malaysia, 2015, pp. 289–292.

14.

Niu

Liang

, et al. Long tunnel lighting environment improvement method based on multiple-parameter intelligent control: considering dynamic changes in luminance difference. Tunnelling and Underground Space Technology 2022; 128: 104637.

15.

Qin

Dong

, et al. A ‘vehicle in, light brightens; vehicle out, light darkens’ energy-saving control system of highway tunnel lighting. Tunnelling and Underground Space Technology 2017; 66: 147–156.

16.

An optimal model for tunnel lighting control systems. Tunnelling and Underground Space Technology 2015; 49: 328–335.

17.

Xin

Wei

Zhao

, et al. Tunnel lighting optimisation study based on sunshade. Tunnelling and Underground Space Technology 2024; 151: 105863.

18.

Zeng

Qiu

Shen

, et al. Fuzzy control of LED tunnel lighting and energy conservation. Tsinghua Science & Technology 2011; 16: 576–582.

19.

Zhang

Qin

, et al. Fuzzy control system for energy-saving in highway tunnel lighting. Journal of Electronic Measurement and Instrumentation 2017; 31: 2049–2055.

20.

Qiu

Qin

Research on energy-saving control system for highway tunnel lighting based on fuzzy neural network. Automation and Instrumentation 2024; 2024: 149–152, 157.

21.

Wang

You

Chen

, et al. The impact of different service states of tunnel lighting on traffic safety. Accident Analysis & Prevention 2023; 192: 107237.

22.

Chen

You

Yang

, et al. Traffic safety assessment and prediction under different lighting service states in road tunnels. Tunnelling and Underground Space Technology 2023; 134: 105001.

23.

Schmidhuber

Deep learning in neural networks: an overview. Neural Networks 2015; 61: 85–117.

24.

Xing

Zhang

, et al. Levenberg–Marquardt backpropagation training of multilayer neural networks for state estimation of a safety-critical cyber-physical system. IEEE Transactions on Industrial Informatics 2018; 14: 3436–3446.

25.

Tang

Pedrycz

, et al. Oriented to a multi-learning mode: establishing trend-fuzzy-granule-based LSTM neural networks for time series forecasting. Applied Soft Computing 2024; 166: 112195.

26.

Fan

Yang

Wang

Automatic control system for highway tunnel lighting. In Li

Liu

Chen

, editors. Computer and Computing Technologies in Agriculture IV. Berlin, Heidelberg: Springer, 2011: 116–123.

27.

Gharehchopogh

Namazi

Ebrahimi

, et al. Advances in sparrow search algorithm: a comprehensive survey. Archives of Computational Methods in Engineering 2023; 30: 427–455.

28.

Asghari

Masdari

Gharehchopogh

, et al. Multi-swarm and chaotic whale-particle swarm optimization algorithm with a selection method based on roulette wheel. Expert Systems 2021; 38: e12779.

29.

Sharma

Khodadadi

Saha

, et al. Non-dominated sorting advanced butterfly optimization algorithm for multi-objective problems. Journal of Bionic Engineering 2023; 20: 819–843.

30.

Abdel-Salam

Çelik

, et al. Chaotic RIME optimization algorithm with adaptive mutualism for feature selection problems. Computers in Biology and Medicine 2024; 179: 108803.

31.

Zhou

Wang

, et al. An improved farmland fertility algorithm with hyper-heuristic approach for solving travelling salesman problem. CMES – Computer Modeling in Engineering and Sciences 2022; 135: 1981–2006.

32.

Gharehchopogh

FS.

An improved boosting Bald Eagle Search algorithm with improved African vultures optimization algorithm for data clustering. Annals of Data Science 2025; 12: 605–637.

33.

Xue

Shen

A survey on sparrow search algorithms and their applications. International Journal of Systems Science 2024; 55: 814–832.

34.

Salata

Golasi

Bovenzi

, et al. Energy optimization of road tunnel lighting systems. Sustainability 2015; 7: 9664–9680.

35.

Commission Internationale de l’Éclairage. Guide for the Lighting of Road Tunnels and Underpasses. CIE 88:2004. Vienna: CIE, 2004.

36.

Lokhande

Sahu

Analysis and implementation of PID controller design. IOSR Journal Of Electrical And Electronics Engineering 2022; 17: 56–63.

Segmented dynamic control method for highway tunnel lighting: A sparrow search algorithm-optimized fuzzy neural network

Abstract

Get full access to this article

References