Vehicle collision avoidance motion planning strategy using artificial potential field with adaptive multi-speed scheduler

This study presents an adaptive motion planning strategy for automated vehicle collision avoidance systems to be associated with the variation of collision speed region based on the position of the obstacle. This is done by designing the motion planner using an artificial potential field (APF) with...

Full description

Bibliographic Details
Published in:IET Intelligent Transport Systems
Main Author: Wahid N.; Zamzuri H.; Amer N.H.; Dwijotomo A.; Saruchi S.A.; Mazlan S.A.
Format: Article
Language:English
Published: Institution of Engineering and Technology 2020
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85091397506&doi=10.1049%2fiet-its.2020.0048&partnerID=40&md5=32fa966b43af266583b4506dc616882c
Description
Summary:This study presents an adaptive motion planning strategy for automated vehicle collision avoidance systems to be associated with the variation of collision speed region based on the position of the obstacle. This is done by designing the motion planner using an artificial potential field (APF) with the incorporation of an adaptive multi-speed scheduler using fuzzy system in the motion planning structure. The knowledge database information is developed based on the risk perception of the driver that consists of APF parameters and was optimised by using particle swarm optimisation algorithm. This study contributes to the improvement of a feasible reference motion generated by the motion planner that can be converted into desired control signals. The reference motion resulted to provide the control command that managed to avoid collision successfully by evasive manoeuvre without lane departure when adapting to variation in the vehicle speeds with different obstacle positions. The results indicated the reduction of the lateral error with respect to the reference avoidance trajectory data of up to 87% compared to base-type APF with maximum reference lateral motion is reduced of up to 26%. Then, a hardware-in-loop test is conducted to verify the proposed strategy using a steering wheel system. © The Institution of Engineering and Technology 2020
ISSN:1751956X
DOI:10.1049/iet-its.2020.0048