Abstract
The bacterial foraging optimization (BFO) algorithm successfully searches for an optimal path from start to finish in the presence of obstacles over a flat surface map. However, the algorithm suffers from getting stuck in the local minima whenever non-circular obstacles are encountered. The retrieval from the local minima is crucial, as otherwise, it can cause the failure of the whole task. This research proposes an improved version of BFO called robust bacterial foraging (RBF), which can effectively avoid obstacles, both of circular and non-circular shape, without falling into the local minima. The virtual obstacles are generated in the local minima, causing the robot to retract and regenerate a safe path. The proposed method is easily extendable to multiple robots that can coordinate with each other. The information related to the virtual obstacles is shared with the whole swarm, so that they can escape the same local minima to save time and energy. To test the effectiveness of the proposed algorithm, a comparison is made against the existing BFO algorithm. Through the results, it was witnessed that the proposed approach successfully recovered from the local minima, whereas the BFO got stuck.
Highlights
The advancements in the field of robotics have a long history that dates back to the 1960s, when the first industrial robot was developed
All mobile robots are supposed to maneuver in their surroundings in the presence of obstacles
The main focus of this study is to develop an improved version of the bacterial foraging algorithm to bypass multiple types of obstacles without falling into a local minimum
Summary
The advancements in the field of robotics have a long history that dates back to the 1960s, when the first industrial robot was developed. Path planning (PP) is considered the most critical task that defines the success or failure of the whole process
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