Real-time prediction of secondary incident occurrences using vehicle probe data

•Bayesian structure equation model recognizes congestion patterns using INRIX Data.•An adjustment of the boxplot captures queued segments.•The likelihood of classified secondary incidents is sequentially predicted.•The principled Bayesian learning approach to neural networks outperforms the logistic...

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Bibliographic Details
Published in:Transportation research. Part C, Emerging technologies Emerging technologies, 2016-09, Vol.70, p.69-85
Main Authors: Park, Hyoshin, Haghani, Ali
Format: Article
Language:English
Subjects:
Adjusted boxplot
Bayesian analysis
Bayesian neural network
Clustering
Congestion
Emergencies
Incident duration
Mathematical models
Neural networks
Queues
Roads
Rule extraction
Secondary Incident
Segments
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Summary:•Bayesian structure equation model recognizes congestion patterns using INRIX Data.•An adjustment of the boxplot captures queued segments.•The likelihood of classified secondary incidents is sequentially predicted.•The principled Bayesian learning approach to neural networks outperforms the logistic model.•A pedagogical rule extraction approach will improve the ability to understand secondary incidents. Effective incident management system requires quantifying non-recurring congestion and detecting a secondary incident under the negative influence of a primary incident. Previously suggested thresholds and measurement parameters provide no universal definition of a secondary incident, regardless of discussions on the topic. To solve this dilemma, we propose a Bayesian structure equation model to recognize congestion patterns for road segments using INRIX Data. An adjustment of the boxplot is applied to capture segments at the tail of the queue and at the head of the queue where secondary incidents might occur. The resulting contour plot provides temporal–spatial area under congestion to identify secondary incidents. The likelihood of classified secondary incidents are sequentially predicted from the point of incident response to the road clearance. The prediction performance of the principled Bayesian learning approach to neural networks outperforms the logistic model. The quality of predictions improve as new information (e.g. notification-arrival of response units, speed) becomes available. A pedagogical rule extraction approach will improve the ability to understand secondary incidents by extracting comprehensible rules from the neural networks. The symbolic description represents a series of decisions to assist emergency operators in their decision-making capabilities.
ISSN:0968-090X
1879-2359
DOI:10.1016/j.trc.2015.03.018