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http://dx.doi.org/10.14346/JKOSOS.2018.33.4.98

Macro-Level Accident Prediction Model using Mobile Phone Data  

Kwak, Ho-Chan (Future Transport Policy Research Division, Korea Railroad Research Institute)
Song, Ji Young (Future Transport Policy Research Division, Korea Railroad Research Institute)
Lee, In Mook (Future Transport Policy Research Division, Korea Railroad Research Institute)
Lee, Jun (Future Transport Policy Research Division, Korea Railroad Research Institute)
Publication Information
Journal of the Korean Society of Safety / v.33, no.4, 2018 , pp. 98-104 More about this Journal
Abstract
Macroscopic accident analyses have been conducted to incorporate transportation safety into long-term transportation planning. In macro-level accident prediction model, exposure variable(e.g. a settled population) have been used as fundamental explanatory variable under the concept that each trip will be subjected to a probable risk of accident. However, a settled population may be embedded error by exclusion of active population concept. The objective of this research study is to develop macro-level accident prediction model using floating population variable(concept of including a settled population and active population) collected from mobile phone data. The concept of accident prediction models is introduced utilizing exposure variable as explanatory variable in a generalized linear regression with assumption of a negative binomial error structure. The goodness of fit of model using floating population variable is compared with that of the each models using population and the number of household variables. Also, log transformation models are additionally developed to improve the goodness of fit. The results show that the log transformation model using floating population variable is useful for capturing the relationships between accident and exposure variable and generally perform better than the models using other existing exposure variables. The developed model using floating population variable can be used to guide transportation safety policy decision makers to allocate resources more efficiently for the regions(or zones) with higher risk and improve urban transportation safety in transportation planning step.
Keywords
floating population; macro-level accident prediction model; mobile phone data; negative binomial regression model; urban transportation safety;
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Times Cited By KSCI : 3  (Citation Analysis)
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