Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model

Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model

Motor vehicle crashes remain a leading cause of life and property loss to society. Autonomous vehicles can mitigate the losses by making appropriate emergency decision, and the crash injury severity prediction model is the basis for autonomous vehicles to make decisions in emergency situations. In t...

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Bibliographic Details
Main Authors: Yaping Liao, Junyou Zhang, Shufeng Wang, Sixian Li, Jian Han
Format: Article
Language:English
Published: MDPI AG 2018-12-01
Series:Electronics
Subjects:
autonomous vehicle
crash injury severity prediction
support vector machine model
emergency decisions
relative speed
total vehicle mass of the front vehicle
Online Access:https://www.mdpi.com/2079-9292/7/12/381
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spelling doaj-aa53572cf27c4786af4c049a3a57ee9e2020-11-24T21:22:26ZengMDPI AGElectronics2079-92922018-12-0171238110.3390/electronics7120381electronics7120381Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine ModelYaping Liao0Junyou Zhang1Shufeng Wang2Sixian Li3Jian Han4College of Transportation, Shandong University of Science and Technology, Huangdao District, Qingdao 266590, ChinaCollege of Transportation, Shandong University of Science and Technology, Huangdao District, Qingdao 266590, ChinaCollege of Transportation, Shandong University of Science and Technology, Huangdao District, Qingdao 266590, ChinaCollege of Transportation, Shandong University of Science and Technology, Huangdao District, Qingdao 266590, ChinaCollege of Transportation, Shandong University of Science and Technology, Huangdao District, Qingdao 266590, ChinaMotor vehicle crashes remain a leading cause of life and property loss to society. Autonomous vehicles can mitigate the losses by making appropriate emergency decision, and the crash injury severity prediction model is the basis for autonomous vehicles to make decisions in emergency situations. In this paper, based on the support vector machine (SVM) model and NASS/GES crash data, three SVM crash injury severity prediction models (B-SVM, T-SVM, and BT-SVM) corresponding to braking, turning, and braking + turning respectively are established. The vehicle relative speed (REL_SPEED) and the gross vehicle weight rating (GVWR) are introduced into the impact indicators of the prediction models. Secondly, the ordered logit (OL) and back propagation neural network (BPNN) models are established to validate the accuracy of the SVM models. The results show that the SVM models have the best performance than the other two. Next, the impact of REL_SPEED and GVWR on injury severity is analyzed quantitatively by the sensitivity analysis, the results demonstrate that the increase of REL_SPEED and GVWR will make vehicle crash more serious. Finally, the same crash samples under normal road and environmental conditions are input into B-SVM, T-SVM, and BT-SVM respectively, the output results are compared and analyzed. The results show that with other conditions being the same, as the REL_SPEED increased from the low (0⁻20 mph) to middle (20⁻45 mph) and then to the high range (45⁻75 mph), the best emergency decision with the minimum crash injury severity will gradually transition from braking to turning and then to braking + turning.https://www.mdpi.com/2079-9292/7/12/381autonomous vehiclecrash injury severity predictionsupport vector machine modelemergency decisionsrelative speedtotal vehicle mass of the front vehicle
collection DOAJ
language English
format Article
sources DOAJ
author Yaping Liao
Junyou Zhang
Shufeng Wang
Sixian Li
Jian Han
spellingShingle Yaping Liao
Junyou Zhang
Shufeng Wang
Sixian Li
Jian Han
Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
Electronics
autonomous vehicle
crash injury severity prediction
support vector machine model
emergency decisions
relative speed
total vehicle mass of the front vehicle
author_facet Yaping Liao
Junyou Zhang
Shufeng Wang
Sixian Li
Jian Han
author_sort Yaping Liao
title Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
title_short Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
title_full Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
title_fullStr Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
title_full_unstemmed Study on Crash Injury Severity Prediction of Autonomous Vehicles for Different Emergency Decisions Based on Support Vector Machine Model
title_sort study on crash injury severity prediction of autonomous vehicles for different emergency decisions based on support vector machine model
publisher MDPI AG
series Electronics
issn 2079-9292
publishDate 2018-12-01
description Motor vehicle crashes remain a leading cause of life and property loss to society. Autonomous vehicles can mitigate the losses by making appropriate emergency decision, and the crash injury severity prediction model is the basis for autonomous vehicles to make decisions in emergency situations. In this paper, based on the support vector machine (SVM) model and NASS/GES crash data, three SVM crash injury severity prediction models (B-SVM, T-SVM, and BT-SVM) corresponding to braking, turning, and braking + turning respectively are established. The vehicle relative speed (REL_SPEED) and the gross vehicle weight rating (GVWR) are introduced into the impact indicators of the prediction models. Secondly, the ordered logit (OL) and back propagation neural network (BPNN) models are established to validate the accuracy of the SVM models. The results show that the SVM models have the best performance than the other two. Next, the impact of REL_SPEED and GVWR on injury severity is analyzed quantitatively by the sensitivity analysis, the results demonstrate that the increase of REL_SPEED and GVWR will make vehicle crash more serious. Finally, the same crash samples under normal road and environmental conditions are input into B-SVM, T-SVM, and BT-SVM respectively, the output results are compared and analyzed. The results show that with other conditions being the same, as the REL_SPEED increased from the low (0⁻20 mph) to middle (20⁻45 mph) and then to the high range (45⁻75 mph), the best emergency decision with the minimum crash injury severity will gradually transition from braking to turning and then to braking + turning.
topic autonomous vehicle
crash injury severity prediction
support vector machine model
emergency decisions
relative speed
total vehicle mass of the front vehicle
url https://www.mdpi.com/2079-9292/7/12/381
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AT junyouzhang studyoncrashinjuryseveritypredictionofautonomousvehiclesfordifferentemergencydecisionsbasedonsupportvectormachinemodel
AT shufengwang studyoncrashinjuryseveritypredictionofautonomousvehiclesfordifferentemergencydecisionsbasedonsupportvectormachinemodel
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AT jianhan studyoncrashinjuryseveritypredictionofautonomousvehiclesfordifferentemergencydecisionsbasedonsupportvectormachinemodel
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