Vehicle profile optimization using central composite design for pedestrian injury mitigation

Pedestrian injury poses a significant problem throughout the world. Pedestrians contribute to the second largest category of motor vehicle deaths accounting for about 13% of fatalities, after occupant injuries. Therefore is vital to design pedestrian friendly vehicles to mitigate injuries and fatali...

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Published in:Applied Mathematics and Information Sciences
Main Author: Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
Format: Article
Language:English
Published: Natural Sciences Publishing Co. 2015
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-84907228532&doi=10.12785%2famis%2f090125&partnerID=40&md5=343017f2a5f4b9bc94320434c47965db
id 2-s2.0-84907228532
spelling 2-s2.0-84907228532
Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
Vehicle profile optimization using central composite design for pedestrian injury mitigation
2015
Applied Mathematics and Information Sciences
9
1
10.12785/amis/090125
https://www.scopus.com/inward/record.uri?eid=2-s2.0-84907228532&doi=10.12785%2famis%2f090125&partnerID=40&md5=343017f2a5f4b9bc94320434c47965db
Pedestrian injury poses a significant problem throughout the world. Pedestrians contribute to the second largest category of motor vehicle deaths accounting for about 13% of fatalities, after occupant injuries. Therefore is vital to design pedestrian friendly vehicles to mitigate injuries and fatalities. A statistical methodology employing the Design of Experiments (DoE) is adopted in this work to obtain the optimum design parameters for the vehicle front end geometry. The work studies the feasibility of the use of Central Composite Designs (CCD) between a Circumscribed design (CCC) and a Faced design (CCF). A total of 100 simulation runs are performed and the response is tabulated. Multi linear regression analysis is performed following which, quadratic programming is used to carry out the optimization task using the Response Surface models obtained. It is concluded that the CCC offers a better prediction for the optimum values in comparison to the CCF design. The SSR value for the CCC design offers a better fit for the model yielding the value of 2.68 which is lesser than CCF's value of 2.87. In addition, the practical error margin between the predicted CCC designs and observed experimental values are 43.68 for CCC and 187.66 for CCF respectively, thus affirming the conclusion made. © 2015 NSP.
Natural Sciences Publishing Co.
19350090
English
Article

author Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
spellingShingle Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
Vehicle profile optimization using central composite design for pedestrian injury mitigation
author_facet Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
author_sort Kausalyah V.; Shasthri S.; Abdullah K.A.; Idres M.M.; Shah Q.H.; Wong S.V.
title Vehicle profile optimization using central composite design for pedestrian injury mitigation
title_short Vehicle profile optimization using central composite design for pedestrian injury mitigation
title_full Vehicle profile optimization using central composite design for pedestrian injury mitigation
title_fullStr Vehicle profile optimization using central composite design for pedestrian injury mitigation
title_full_unstemmed Vehicle profile optimization using central composite design for pedestrian injury mitigation
title_sort Vehicle profile optimization using central composite design for pedestrian injury mitigation
publishDate 2015
container_title Applied Mathematics and Information Sciences
container_volume 9
container_issue 1
doi_str_mv 10.12785/amis/090125
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-84907228532&doi=10.12785%2famis%2f090125&partnerID=40&md5=343017f2a5f4b9bc94320434c47965db
description Pedestrian injury poses a significant problem throughout the world. Pedestrians contribute to the second largest category of motor vehicle deaths accounting for about 13% of fatalities, after occupant injuries. Therefore is vital to design pedestrian friendly vehicles to mitigate injuries and fatalities. A statistical methodology employing the Design of Experiments (DoE) is adopted in this work to obtain the optimum design parameters for the vehicle front end geometry. The work studies the feasibility of the use of Central Composite Designs (CCD) between a Circumscribed design (CCC) and a Faced design (CCF). A total of 100 simulation runs are performed and the response is tabulated. Multi linear regression analysis is performed following which, quadratic programming is used to carry out the optimization task using the Response Surface models obtained. It is concluded that the CCC offers a better prediction for the optimum values in comparison to the CCF design. The SSR value for the CCC design offers a better fit for the model yielding the value of 2.68 which is lesser than CCF's value of 2.87. In addition, the practical error margin between the predicted CCC designs and observed experimental values are 43.68 for CCC and 187.66 for CCF respectively, thus affirming the conclusion made. © 2015 NSP.
publisher Natural Sciences Publishing Co.
issn 19350090
language English
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accesstype
record_format scopus
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