The cellular traffic capacity model of toll station square

Authors

DOI:

https://doi.org/10.5604/01.3001.0053.7075

Keywords:

highway toll station, traffic capacity, microscopic simulation, toll plaza

Abstract

Traffic capacity is an important index to measure the operation efficiency of expressway toll stations. In order to provide relevant theoretical support for accurately evaluating the congestion degree and service level of toll stations, this paper establishes a traffic capacity calculation model for the square in front of expressway toll stations based on the traditional cellular transmission method. Firstly, by dividing the square in front of the station into regular cells, the process of calculating the traffic capacity is simplified; Secondly, the capacity model of the square in front of the station is established based on cellular transmission, and a large amount of data is collected through the monitoring videos of several toll stations. The theoretical capacity of the square in front of the station is calculated by using the important parameters of the model calibrated by the measured data under different lengths of the square in front of the station and the configuration of toll lanes. Then, the simulation platform of VISSIM software is used, and many experiments are carried out with relevant measured data to verify the accuracy of the model in multiple scenarios. Finally, the simulation value of the capacity of the square in front of the station is obtained, and the error is calculated by using the simulation value and the calculation value. The results show that the error of the verification result is 5.19%, and the error is within the allowable range, which shows that the model is accurate and feasible. The theoretical capacity calculated by the capacity model of the square in front of the toll station established in this paper is compared with the actual capacity, which can be used as a standard to judge the congestion degree of the square in front of the toll station and further provide a theoretical reference for evacuation of congestion.

References

Wang, K., Peng, W., Xin, C., & Lu, T. Z. (2020). Multiobjective optimization design of toll plaza, Mathematical Problems in Engineering, 2324894, 9 pages, 2020.

Lu, X. Y., Varaiya, P., Horowitz, R. (2010). A new approach for combined freeway variable speed limits and coordinated ramp metering. Intelligent Transportation Systems (ITSC).

Kumar, A., Thakare, A., & Tawalare, A.(2020). Strategy to reduce queuing time at toll plaza. Lecture Notes in Civil Engineering, 453-464.

Liu, C. L., Sha, T., Zhao, C., Ji, Y. X., & Du, Y. C. (2022). Optimal deployment of electronic toll collection lanes for freeway network. China Journal of Highway and Transport, 35(05), 179-188.

Saad, M., Abdel-Aty, & Mohamed L. (2019). Analysis of driving behavior at expressway toll plazas. Transportation Research Part F: Traffic Psychology and Behaviour, 163-177.

Wang, H. Y. (2017). Study on the capacity and lane configuration strategy of expressway toll station. Southwest Jiaotong University.

Chintaman, S. B., Satish C., Ashish D., Shriniwas A., & Yogeshwar V. N. (2021). Service time variability at manual operated tollbooths under mixed traffic environment: Towards level-of-service thresholds. Transport Policy, 106, 11-24.

Li, J. X., Zhou, Y. C., Gao, Z. B., Shen, Z. B., & Wu Z. Z. (2021). Analysis on capacity of expressway toll station based on toll data. Journal of Highway and Transportation Research and Development, 38(11), 106-116+125.

Navandar, Y. V., Dhamaniya, A., Patel, D. A., & Chandra, S. (2019). Traffic flow analysis at manual tollbooth operation under mixed traffic conditions. Journal of Transportation Engineering, Part A: Systems, 145(6), 04019023.

Navandar, Y. V., Dhamaniya, A., Patel, D. A. (2020). A quick method for estimation of level of service at manually operated tollbooths under mixed traffic conditions. Transportation Research Procedia, 48(), 3107-3120.

Liu, X. Q., & Wang, Y. H. (2011). Study of manual-toll-collection-lane capacity at highway toll station based on mathematical statistics- Taken highway toll stations in Shanghai as an example. Journal of Shanghai Jiaotong University, 45(S1), 79-82.

Zhao, Z. X., & Zheng, L. (2022). Study on traffic capacity of expressway mixed toll station lane. Shandong Traffic Technology, 2022(04), 135-137.

Mahdi, M. B., Leong, L. V., & Sadullah, A. F. M. (2019). Use of microscopic traffic simulation software to determine heavy-vehicle influence on queue lengths at toll plazas. Arab J Sci Eng, 44, 7297-7311.

Bari, C. S., Navandar, Y. V., & Dhamaniya, A. (2020). Delay modelling at manually operated toll plazas under mixed traffic conditions. International Journal of Transportation Science and Technology, S2046043020300629.

Zarrillo, M. L., & Radwan, A. E. (2009). Methodology SHAKER and the capacity analysis of five toll plazas. Journal of Transportation Engineering, 135(3), 83-93.

Zhao, S. J. (2012). The charging capacity and key designing parameters of freeway. Hebei University of Technology.

Yong, G., Zhang, J., Su, N., & X. Feng. (2021). Capacity design and pareto improvement of highway toll plaza in a competitive transport system, IEEE Access, 9, 113642-113652.

Yu, S. C., Du, Y. C., Wang, J. D., Li. Y. S., & Zhu, Y. (2021). Simulation-based optimization for the operation of toll plaza at car park exit with mixed types of tollbooths and waiting-time-dependent service. Journal of Advanced Transportation, 6674037, 27 pages.

Qian, Y. S., Shao, X. M., & Zeng, J. W. (2013). An improved cellular automaton model with the consideration of a multi-point tollbooth. Physica A: Statistical Mechanics and its Applications, 392(23), 5874-5878.

Kim, C., Kim, D. K., Kho, S. Y., Kang, S., & Chung, K. (2016). Dynamically determining the toll plaza capacity by monitoring approaching traffic conditions in real-time. Applied Sciences, 6(3), 87.

Yu, B., & Mwaba, D. (2020). Toll plaza lane choice and lane configuration strategy for autonomous vehicles in mixed traffic. Journal of Transportation Engineering, Part A: Systems, 146(12), 04020133.

Dong, C. Y., Wang, H., Chen, Q., Ni, D. H., & Li, Y. (2019). Simulation-based assessment of multilane separate freeways at toll station area: A case study from Huludao toll station on Shenshan freeway. Sustainability, 11(11), 3057.

Bains, M. S., Arkatkar, S. S., Anbumani, K. S., & Subramaniam, S. (2017). Optimizing and modeling tollway operations using microsimulation: Case study sanand toll plaza. Transportation Research Record, 2615(1), 43-54.

Bartin, B. (2019). Use of learning classifier systems in microscopic toll plaza simulation models. IET Intelligent Transport Systems, 13(5), 860-869.

Wang, J., Lu, L. L., Srinivas, P., & He, Z. B. (2021). Optimal toll design problems under mixed traffic flow of human-driven vehicles and connected and autonomous vehicles. Transportation Research Part C: Emerging Technologies, 125(2021), 102952.

Daganzo, C. (1993). The cell transmission model. Acta Polymerica, 40(8), 553-554.

Tampere, C., & Immers, B. (2007). Traffic state estimation and prediction using the cell transmission model with implicit mode switching and dynamic parameters.

Jorge, A., Laval, C. F., & Daganzo. (2005). Lane-changing in traffic streams. Transportation Research Part B, 40(3), 251-264.

Luo, Z. M., Ma, F. H. (2018). Research on the traffic capacity of ETC and MTC lane in composite toll station. Highway, 63(07), 239-244.

Cheng, J. L. (2015). Study of capacity for ETC and MTC hybrid toll station. Southwest Jiaotong University.

Downloads

Published

2023-09-30

Issue

Section

Original articles

How to Cite

Bai, Y., Wang, K., Yi, L., & Peng, B. (2023). The cellular traffic capacity model of toll station square. Archives of Transport, 67(3), 35-47. https://doi.org/10.5604/01.3001.0053.7075

Share

Most read articles by the same author(s)

1 2 3 4 5 6 7 8 9 10 > >> 

Similar Articles

21-30 of 257

You may also start an advanced similarity search for this article.