Analysis of the influence of expressway emergencies on transmission speeds and travel delays

Authors

DOI:

https://doi.org/10.5604/01.3001.0015.9924

Keywords:

expressway, congestion, propagation, travel time delay, logistic velocity

Abstract

Expressway emergencies tend to cause traffic congestion, and understanding the travel time delays of on-road vehicles under different combinations of event scenarios and road traffic conditions is valuable for guiding the accurate emergency dispatch services. Most existing studies used methods that combine the Lighthill-Whitham-Richards (LWR) theory and basic traffic diagrams to solve this problem, but the discrete traffic flow characteristics caused by the presence of heavy vehicles have not been considered, thus affecting the applicability of those results to road traffic characteristics in China. Moreover, there is a lack of systematic research on multiple combinations of unexpected event scenarios and traffic conditions, and the guidance value of the previously obtained results is limited. In order to improve the applicability of the prediction model and accurately predict the severity of emergencies, based on a logistic model that is applicable to emergencies, a velocity–density model is constructed to describe discrete traffic flow characteristics. Based on LWR theory, the internal driving force of expressway traffic state evolution under emergency conditions is explored. Combined with real-time traffic flow data, the parameters of the logistic model are calibrated, and a logistic velocity-density model is constructed using a goodness-of-fit test and a marching method, including the free-flow velocity, turning density and heavy vehicle mixing ratio. Thus, the problem that existing models lack applicability to road traffic characteristics in China is solved. Travel time delay is associated with the impact range of an emergency, and it is an effective index for evaluating the severity of emergency incidents. Thus, the travel time delays under different scenarios, different numbers of blocked lanes and different orthogonal combinations of approximate saturation conditions are explored, and the impacts of lane blockage on emergency incidents and travel time delays are obtained. The conclusions show that the presented logistic velocity-density model constructed based on discrete traffic flow characteristics can properly quantify the impact of the presence of heavy vehicles. Additionally, the results can provide theoretical support for handling emergencies and emergency rescues.

References

Zhao, Y., Wang, L., Zhao, Q. H. (2020). Study on Emergency Model of Expressway with Time Delay. Journal of Systems Science and Mathematical Sciences, 40(05), 844-856.

Shen, Z., Wang, W., Shen, Q., Zhu, S., Fardoun, H. M., Lou, J. (2019). A novel learning method for multi-intersections aware traffic flow forecasting. Neurocomputing, 398(4), 477-484.

Wang, J., Gu, Q., Wu, J., Liu, G., Xiong, Z. (2016). Traffic speed prediction and congestion source exploration: A deep learning method. In 2016 IEEE 16th international conference on data mining (ICDM), 499-508, IEEE.

Zhang, Y., Ye, N., Wang, R., Malekian, R. (2016). A method for traffic congestion clustering judgment based on grey relational analysis. ISPRS International Journal of Geo-Information, 5(5), 71.

Lopez-Garcia, P., Onieva, E., Osaba, E., Masegosa, A. D., Perallos, A. (2015). A hybrid method for short-term traffic congestion fore-casting using genetic algorithms and cross entropy. IEEE Transactions on Intelligent Transportation Systems, 17(2), 557-569.

Nagy, A. M., Simon, V. (2021). Improving traffic prediction using congestion propagation patterns in smart cities. Advanced Engineering Informatics, 50, 101343.

Zhang, L., Liu, Q., Yang, W., Wei, N., Dong, D. (2013). An improved k-nearest neighbor model for short-term traffic flow prediction. Procedia-Social and Behavioral Sciences, 96, 653-662.

Li, L., Lin, H., Wan, J., Ma, Z., Wang, H. (2020). MF-TCPV: a machine learning and fuzzy comprehensive evaluation-based frame-work for traffic congestion prediction and visualization. IEEE Access, 8, 227113-227125.

Salahdine, F., Aggarwal, S., Nasipuri, A. (2022). Short-Term Traffic Congestion Prediction with Deep Learning for LoRa Networks. In SoutheastCon 2022, 261-268, IEEE.

Sharma, B., Kumar, S., Tiwari, P., Yadav, P., Nezhurina, M. I. (2018). ANN based short-term traffic flow forecasting in undivided two lane highway. Journal of Big Data, 5(1), 1-16.

Elleuch, W., Wali, A., Alimi, A. M. (2019). To-wards an efficient traffic congestion prediction method based on neural networks and big GPS data. IIUM Engineering Journal, 20(1), 108-118.

Huang, Z., Lin, P., Lin, X., Zhou, C., Huang, T. (2022). Spatiotemporal attention mechanism-based multistep traffic volume prediction model for highway toll stations. Archives of Transport, 61(1), 21-38.

Hu, J., Krishnan, R., Bell, M (2011). Incident Duration Prediction for In-vehicle Navigation System. Meeting of the Transportation Re-search Board.

Dinh, T. T. (2022). A fuzzy-based methodology for anticipating trend of incident traffic congestion on expressways. Tạp chí Khoa học Giao thông vận tải, 73(4), 381-396.

Adler, M. W., Van Ommeren, J., Rietveld, P. (2013). Road congestion and incident duration. Economics of transportation, 2(4), 109-118.

Lee, Y., Wei, C. H., Chao, K. C. (2017). Non-parametric machine learning methods for evaluating the effects of traffic accident duration on freeways. Archives of Transport, 43.

Wang, S., Li, R., Guo, M. (2018). Application of nonparametric regression in predicting traffic incident duration. Transport, 33(1), 22-31.

Vlahogianni, E. I., Karlaftis, M. G. (2013). Fuzzy‐entropy neural network freeway incident duration modeling with single and competing uncertainties. Computer‐Aided Civil and Infrastructure Engineering, 28(6), 420-433.

Abhigna, D., Kondreddy, S., Ravi Shankar, K. V. R. (2016). Effect of vehicle composition and delay on roundabout capacity under mixed traffic conditions. Archives of transport, 40.

Al-Kaisy, A. F., Hall, F. L., Reisman, E. S. (2002). Developing passenger car equivalents for heavy vehicles on freeways during queue discharge flow. Transportation Research Part A: Policy and Practice, 36(8), 725-742.

Jo, Y., Choi, H., Jeon, S., Jung, I. (2012). Variable speed limit to improve safety near traffic congestion on urban freeways. In 2012 IEEE International Conference on Information Science and Technology, 43-50.

Ghods, A. H., Saccomanno, F., Guido, G. (2012). Effect of car/truck differential speed limits on two-lane highways safety operation using microscopic simulation. Procedia-Social and Behavioral Sciences, 53, 833-840.

Hu, X., Xu, Y., Guo, J., Zhang, T., Bi, Y., Liu, W., Zhou, X. (2022). A Complete Information Interaction-Based Bus Passenger Flow Control Model for Epidemic Spread Prevention. Sustainability, 14(13), 8032.

Theodoulou, G., Wolshon, B. (2004). Alternative methods to increase the effectiveness of freeway contraflow evacuation. Transportation Research Record, 1865(1), 48-56.

Coifman, B., Kim, S. (2011). Extended bottlenecks, the fundamental relationship, and capacity drop on freeways. Procedia-Social and Behavioral Sciences, 17, 44-57.

Chen, D. S., Wang, K. (2018, July). Data analysis of expressway under single point accident based on dynamic speed control. In Proceedings of the 2018 International Conference on Data Science and Information Technology, 159-164.

Kušić, K., Ivanjko, E., Vrbanić, F., Gregurić, M., Dusparic, I. (2021). Spatial-temporal traffic flow control on motorways using distributed multi-agent reinforcement learning. Mathematics, 9(23), 3081.

National Research Council. (2010). HCM2010 : highway capacity manual. 5th ed. Washington, D.C: Transportation Research Board.

Tanaka, M., Nakatsuji, T. (2011). Shock Waves and Speed Peak Propagations in Stop and Go Car-Following Conditions within Short Distances. Transportation Research Board Meeting.

Li, T., Ni, A., Zhang, C., Xiao, G., Gao, L. (2020). Short‐term traffic congestion prediction with Conv-BiLSTM considering spatio‐temporal features. IET Intelligent Transport Systems, 14(14), 1978-1986.

Do, L. N., Vu, H. L., Vo, B. Q., Liu, Z., Phung, D. (2019). An effective spatial-temporal attention based neural network for traffic flow prediction. Transportation research part C: emerging technologies, 108, 12-28.

Gottschalk, P. G., Dunn, J. R. (2005). The five-parameter logistic: a characterization and comparison with the four-parameter logistic. Analytical biochemistry, 343(1), 54-65.

Aiura, R., Morino, H. (2022). Mitigating Traffic Congestion Due To an Accident with Area-dependent Jam Absorption Driving. In 2022 IEEE International Conference on Pervasive Computing and Communications Workshops and other Affiliated Events (PerCom Work-shops) , 575-580.

Bakar, N., Majid, M. A., Allegra, M., Adam, K., Younis, Y. M. (2018). The simulation on vehicular traffic congestion using discrete event simulation (DES): A case study. In 2018 International Conference on Innovation and Intelligence for Informatics, Computing, and Technologies (3ICT), 1-6.

Shlayan, N., Challapali, K., Cavalcanti, D., Oliveira, T., Yang, Y. (2017). A novel illuminance control strategy for roadway lighting based on green shields macroscopic traffic model. IEEE Photonics Journal, 10(1), 1-11.

Chen, Q., Song, Y., Zhao, J. (2021). Short-term traffic flow prediction based on improved wavelet neural network. Neural Computing and Applications, 33(14), 8181-8190.

Wang, P., Hao, W., Sun, Z., Wang, S., Tan, E., Li, L., Jin, Y. (2018). Regional detection of traffic congestion using in a large-scale surveil-lance system via deep residual TrafficNet. IEEE Access, 6, 68910-68919.

Singh, S., Santhakumar, S. M. (2022). Platoon-based impact assessment of heavy-duty vehicles on traffic stream characteristics of highway lanes under mixed traffic environment. International Journal of Intelligent Transportation Systems Research, 20(1), 29-45.

Guériau, M., Dusparic, I. (2020, September). Quantifying the impact of connected and autonomous vehicles on traffic efficiency and safety in mixed traffic. In 2020 IEEE 23rd International Conference on Intelligent Transportation Systems (ITSC), 1-8.

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Published

2022-09-30

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Original articles

How to Cite

Shi, X., Liu, X., Li, M., & Liu, T. (2022). Analysis of the influence of expressway emergencies on transmission speeds and travel delays. Archives of Transport, 63(3), 7-21. https://doi.org/10.5604/01.3001.0015.9924

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