TY - GEN
T1 - Enhancing Road Safety Evaluation with AI
T2 - 6th International Conference on Computer Vision, Image and Deep Learning, CVIDL 2025
AU - Zahran, Omar Elsaid
AU - Xin, Yiwen
AU - Zahran, Elsaid Mamdouh Mahmoud
AU - Cheah, Wooi Ping
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Road traffic accidents result from a complex interplay of various conditions, making it difficult to pinpoint key factors that influence their occurrence and severity. This study employs Bayesian Belief Networks (BBNs) to construct robust predictive models capable of handling incomplete data via probabilistic inference, providing transparent and interpretable insights. Unlike traditional machine learning methods, which often struggle with missing values, BBNs efficiently estimate probabilities from available evidence, offering a cohesive framework for assessing road safety risks. Using the UK government's 2022 traffic accident dataset, we developed a BBNbased accident probability model, identifying significant variables such as road type, speed limits, junction configurations, lighting, and weather conditions through expert consultation and literature reviews. Each variable was categorized, quantified by frequency, converted into probabilities, and subsequently integrated multiplicatively to approximate accident likelihood. These probabilities were discretized into ordinal classes, serving as input states for the BBN. The model was validated using the 2021 accident dataset, demonstrating its predictive reliability across temporal variations. Further, we extended our model to accident severity classification. The combined probability-severity BBN approach offers actionable insights for targeted road safety interventions, such as improved lighting or drainage. This methodology exemplifies a practical, interpretable, and scalable solution for guiding policymakers in optimizing road safety interventions.
AB - Road traffic accidents result from a complex interplay of various conditions, making it difficult to pinpoint key factors that influence their occurrence and severity. This study employs Bayesian Belief Networks (BBNs) to construct robust predictive models capable of handling incomplete data via probabilistic inference, providing transparent and interpretable insights. Unlike traditional machine learning methods, which often struggle with missing values, BBNs efficiently estimate probabilities from available evidence, offering a cohesive framework for assessing road safety risks. Using the UK government's 2022 traffic accident dataset, we developed a BBNbased accident probability model, identifying significant variables such as road type, speed limits, junction configurations, lighting, and weather conditions through expert consultation and literature reviews. Each variable was categorized, quantified by frequency, converted into probabilities, and subsequently integrated multiplicatively to approximate accident likelihood. These probabilities were discretized into ordinal classes, serving as input states for the BBN. The model was validated using the 2021 accident dataset, demonstrating its predictive reliability across temporal variations. Further, we extended our model to accident severity classification. The combined probability-severity BBN approach offers actionable insights for targeted road safety interventions, such as improved lighting or drainage. This methodology exemplifies a practical, interpretable, and scalable solution for guiding policymakers in optimizing road safety interventions.
KW - Accident Severity Classification
KW - Bayesian Belief Networks
KW - Probabilistic Inference
KW - Road Safety Modeling
KW - Traffic Accident Probability
UR - https://www.scopus.com/pages/publications/105013059254
U2 - 10.1109/CVIDL65390.2025.11085562
DO - 10.1109/CVIDL65390.2025.11085562
M3 - Conference contribution
AN - SCOPUS:105013059254
T3 - 2025 6th International Conference on Computer Vision, Image and Deep Learning, CVIDL 2025
SP - 701
EP - 706
BT - 2025 6th International Conference on Computer Vision, Image and Deep Learning, CVIDL 2025
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 23 May 2025 through 25 May 2025
ER -
