Abstract
Accurate prediction of driving risk is challenging due to the rarity of crashes and individual driver heterogeneity. One promising direction of tackling this challenge is to take advantage of telematics data, increasingly available from connected vehicle technology, to obtain dense risk predictors. In this work, we propose a decision-adjusted framework to develop optimal driver risk prediction models using telematics-based driving behavior information. We apply the proposed framework to identify the optimal threshold values for elevated longitudinal acceleration (ACC), deceleration (DEC), lateral acceleration (LAT), and other model parameters for predicting driver risk. The Second Strategic Highway Research Program (SHRP 2) naturalistic driving data were used with the decision rule of identifying the top 1% to 20% of the riskiest drivers. The results show that the decision-adjusted model improves prediction precision by 6.3% to 26.1% compared to a baseline model using non-telematics predictors. The proposed model is superior to models based on a receiver operating characteristic curve criterion, with 5.3% and 31.8% improvement in prediction precision. The results confirm that the optimal thresholds for ACC, DEC and LAT are sensitive to the decision rules, especially when predicting a small percentage of high-risk drivers. This study demonstrates the value of kinematic driving behavior in crash risk prediction and the necessity for a systematic approach for extracting prediction features. The proposed method can benefit broad applications, including fleet safety management, use-based insurance, driver behavior intervention, as well as connected-vehicle safety technology development.
Highlights
Predicting crash risk and identifying high-risk drivers are critical for developing appropriate safety countermeasures, driver education pro grams, and use-based insurance systems
We propose a decision-adjusted modeling framework and develop an optimal driver risk prediction model based on driving telematics data from the SHRP 2 naturalistic driving studies (NDSs)
We focus on incorporating a broader set of fused tele matics data in the risk prediction models, in which the parameters to be adjusted are the thresholds of kinematic signatures, such as elevated longitudinal and lateral acceleration
Summary
Predicting crash risk and identifying high-risk drivers are critical for developing appropriate safety countermeasures, driver education pro grams, and use-based insurance systems. Based on a simulation study, Habtemichael and de Picado-Santos (2013) showed that limiting the risk behavior of 4% to 12% of high-risk drivers would reduce crashes by 9% to 27% in different traffic conditions Predicting and identifying this small portion of high-risk drivers can provide important information for developing targeted safety countermeasures to improve transportation safety. Beside high G-force event, longitudinal jerk, i.e., derivative of acceleration, especially large negative jerks have the po tential to detect aggressive driving behaviors and predict crash risk (Feng et al, 2017; Bagdadi and Varhelyi, 2011; Bagdadi, 2013) Other kinematic measures such mean and volatility are used in risk pre diction (af Wåhlberg, 2006; Wang et al, 2015).
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