2026: Online first section
Articles

Targeted Intersection Safety in Data-Sparse Cities: A Discrete-Time Microsimulation and Decision-Making Framework Applied to a Hazardous Urban Junction in Libya

Ibrahim Badi
Libyan Academy, Misrata, Libya
Mouhamed Bayane Bouraima
School of Civil Engineering, Southwest Jiao Tong University, Chengdu, Sichuan Province, China
Sam Aberi Okemwa
Zalika Greentech, Nairobi County, Kenya

Published 2026-06-07

Keywords

  • Urban Traffic Operations,
  • Intersection Safety Application,
  • Transportation Research,
  • Discrete-Time Microsimulation,
  • Technique for Order Preference by Similarity to the Ideal Solution,
  • Surrogate Safety Measures
  • ...More
    Less

How to Cite

Badi, I., Bayane Bouraima, M., & Okemwa, S. A. (2026). Targeted Intersection Safety in Data-Sparse Cities: A Discrete-Time Microsimulation and Decision-Making Framework Applied to a Hazardous Urban Junction in Libya. Applied Research Advances, 1-11. https://doi.org/10.65069/ara21202617

Abstract

Urban safety policy choices in low-data contexts frequently face both high uncertainty and pressing timelines. This paper suggests a lightweight and reproducible framework that combines a discrete-time microsimulation of a single, high-risk four-leg intersection with multi-criteria decision-making. In the model, vehicles and pedestrians are generated via Poisson arrival processes, while behavioral variability such as speeding, red-light running, jaywalking, and driver yielding is modeled using probabilistic parameters calibrated to local Libyan traffic conditions. Four low-cost interventions (i.e., speed bumps, a red-light camera, an improved pedestrian crosswalk, and a one-lane roundabout) are evaluated against the baseline. Each strategy is evaluated using four main simulation-based criteria (i.e., reduction in accidents, effect on vehicle delay, cost of implementation, and a pedestrian safety measure) that combine near-miss and waiting-time changes. These outputs are fed into a Technique for Order Preference by Similarity to the Ideal Solution (TOPSIS) analysis under safety-first, cost-sensitive, and pedestrian-focused stakeholder perspectives. Outcomes exhibit clear, mechanism-consistent trends. By reporting uncertainty explicitly and providing scenario-dependent rankings, the framework translates limited local data into clear, defensible decision guidance. The contribution is both practical and methodological; i.e., a sparse-data pipeline that urban areas can readily implement to prioritize first-step safety spending at high-risk intersections.

Downloads

Download data is not yet available.

References

  1. Coll, B., Moutari, S., & Marshall, A. H. (2013). Hotspots identification and ranking for road safety improvement: An alternative approach. Accident Analysis & Prevention, 59, 604-617. https://doi.org/10.1016/j.aap.2013.07.012.
  2. Polders, E., Daniels, S., Hermans, E., Brijs, T., & Wets, G. (2015). Crash patterns at signalized intersections. Transportation Research Record, 2514(1), 105-116. https://doi.org/10.3141/2514-12.
  3. Schneider, R. J., Proulx, F. R., Sanders, R. L., & Moayyed, H. (2021). United States fatal pedestrian crash hot spot locations and characteristics. Journal of Transport Land Use, 14(1), 1-23. https://doi.org/10.5198/jtlu.2021.1825.
  4. Mitra, S., Neki, K., Mbugua, L. W., Gutierrez, H., Bakdash, L., Winer, M., Balasubramaniyan, R., Roberts, J., Vos, T., Hamilton, E., Naghavi, M., Harrison, J. E., Soames Job, R. F., & Bhalla, K. (2021). Availability of population-level data sources for tracking the incidence of deaths and injuries from road traffic crashes in low-income and middle-income countries. BMJ Global Health, 6(11), e007296. https://doi.org/10.1136/bmjgh-2021-007296.
  5. Arun, A., Haque, M. M., Bhaskar, A., Washington, S., & Sayed, T. (2021). A systematic mapping review of surrogate safety assessment using traffic conflict techniques. Accident Analysis & Prevention, 153, 106016. https://doi.org/10.1016/j.aap.2021.106016.
  6. Strauss, J., Zangenehpour, S., Miranda-Moreno, L. F., & Saunier, N. (2017). Cyclist deceleration rate as surrogate safety measure in Montreal using smartphone GPS data. Accident Analysis & Prevention, 99, 287-296. https://doi.org/10.1016/j.aap.2016.11.019.
  7. Goldenbeld, C., Daniels, S., & Schermers, G. (2019). Red light cameras revisited. Recent evidence on red light camera safety effects. Accident Analysis & Prevention, 128, 139-147. https://doi.org/10.1016/j.aap.2019.04.007.
  8. Gross, F., Lyon, C., Persaud, B., & Srinivasan, R. (2013). Safety effectiveness of converting signalized intersections to roundabouts. Accident Analysis & Prevention, 50, 234-241. https://doi.org/10.1016/j.aap.2012.04.012.
  9. Yannis, G., Kopsacheili, A., Dragomanovits, A., & Petraki, V. (2020). State-of-the-art review on multi-criteria decision-making in the transport sector. Journal of Traffic Transportation Engineering, 7(4), 413-431.
  10. Martins, M. A., & Garcez, T. V. (2021). A multidimensional and multi-period analysis of safety on roads. Accident Analysis & Prevention, 162, 106401. https://doi.org/10.1016/j.aap.2021.106401.
  11. Fancello, G., Carta, M., & Fadda, P. (2019). Road intersections ranking for road safety improvement: Comparative analysis of multi-criteria decision making methods. Transport Policy, 80, 188-196. https://doi.org/10.1016/j.tranpol.2018.04.007.
  12. Trivedi, P., & Shah, J. (2022). Identification of road crash severity ranking by integrating the multi-criteria decision-making approach. Journal of Road Safety, 33(2), 33-44. https://doi.org/10.33492/JRS-D-21-00055.
  13. Ciardiello, F., & Genovese, A. (2023). A comparison between TOPSIS and SAW methods. Annals of Operations Research, 325(2), 967-994. https://doi.org/10.1007/s10479-023-05339-w.
  14. Özekenci, E. K., Topcuoglu Onat, K., & Pamucar, D. (2026). A Comprehensive Bibliometric Analysis of Objective Weighting Methods in Multi-Criterion Decision-Making. Management Science Advances, 3(1), 246-265. https://doi.org/10.31181/msa31202645.
  15. Kumar, R. (2025). A comprehensive review of MCDM methods, applications, and emerging trends. Decision Making Advances, 3(1), 185-199. https://doi.org/10.31181/dma31202569.
  16. Badi, I., & Bouraima, M. B. (2023). Development of MCDM-based frameworks for proactively managing the most critical risk factors for transport accidents: a case study in Libya. Spectrum of Engineering Management Sciences, 1(1), 38-47. https://doi.org/10.31181/sems1120231b.
  17. Elmansouri, O., Almhroog, A., & Badi, I. (2020). Urban transportation in Libya: An overview. Transportation Research Interdisciplinary Perspectives, 8, 100161. https://doi.org/10.1016/j.trip.2020.100161.
  18. Mostafa, S., & Bakar, M. (2025). Two Decades of Road Traffic Injuries in Libya: Trends in Trauma Severity and Clinical Outcomes. Tobruk University Journal of Medical Sciences, 9(2), 15-20.
  19. Song, M., Stević, Ž., Badi, I., Marinković, D., Lv, Y., & Zhong, K. (2025). Assessing public acceptance of autonomous vehicles using a novel IRN PIPRECIA-IRN AROMAN model. Facta Universitatis, Series: Mechanical Engineering, 23(1), 127-145. https://doi.org/10.22190/FUME240729040S.
  20. Badi, I., Stević, Ž., Radović, D., Ristić, B., Cakić, A., & Sremac, S. (2023). A new methodology for treating problems in the field of traffic safety: case study of Libyan cities. Transport, 38(4), 190-203. https://doi.org/10.3846/transport.2023.20609.