Enhanced Robot Motion Block of A-Star Algorithm for Robotic Path Planning

Kabir, Raihan; Watanobe, Yutaka; Islam, Md Rashedul; Naruse, Keitaro

doi:10.3390/s24051422

Cited by 3 publications

(1 citation statement)

References 34 publications

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“…The investigation's authors [31] enhanced the A-Star algorithm because the performance of the typical A-Star algorithm is suboptimal for the space, time, and number of search routes, thus relying on the robot motion block. However, this algorithm's effectiveness is often hampered by factors such as the total number of search routes, the overall cost of the path, and the algorithm's complexity of time, especially when tailored to a specific robot motion block.…”

Section: Related Workmentioning

confidence: 99%

Optimizing Mobile Robot Navigation Based on A-Star Algorithm for Obstacle Avoidance in Smart Agriculture

Chatzisavvas,

Dossis,

Dasygenis

2024

Electronics

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The A-star algorithm (A*) is a traditional and widely used approach for route planning in various domains, including robotics and automobiles in smart agriculture. However, a notable limitation of the A-star algorithm is its tendency to generate paths that lack the desired smoothness. In response to this challenge, particularly in agricultural operations, this research endeavours to enhance the evaluation of individual nodes within the search procedure and improve the overall smoothness of the resultant path. So, to mitigate the inherent choppiness of A-star-generated paths in agriculture, this work adopts a novel approach. It introduces utilizing Bezier curves as a postprocessing step, thus refining the generated paths and imparting their smoothness. This smoothness is instrumental for real-world applications where continuous and safe motion is imperative. The outcomes of simulations conducted as part of this study affirm the efficiency of the proposed methodology. These results underscore the capability of the enhanced technique to construct smooth pathways. Furthermore, they demonstrate that the generated paths enhance the overall planning performance. However, they are also well suited for deployment in rural conditions, where navigating complex terrains with precision is a critical necessity.

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Section: Related Workmentioning

confidence: 99%

Optimizing Mobile Robot Navigation Based on A-Star Algorithm for Obstacle Avoidance in Smart Agriculture

Chatzisavvas,

Dossis,

Dasygenis

2024

Electronics

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Equipment control algorithm for cooling plant based on graph theory and path planning

Lin,

Zhang,

Yang

et al. 2024

Energy and Buildings

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Research on Unmanned Vehicle Path Planning Based on the Fusion of an Improved Rapidly Exploring Random Tree Algorithm and an Improved Dynamic Window Approach Algorithm

Wang,

Li,

Liu

2024

WEVJ

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Aiming at the problem that the traditional rapidly exploring random tree (RRT) algorithm only considers the global path of unmanned vehicles in a static environment, which has the limitation of not being able to avoid unknown dynamic obstacles in real time, and that the traditional dynamic window approach (DWA) algorithm is prone to fall into a local optimum during local path planning, this paper proposes a path planning method for unmanned vehicles that integrates improved RRT and DWA algorithms. The RRT algorithm is improved by introducing strategies such as target-biased random sampling, adaptive step size, and adaptive radius node screening, which enhance the efficiency and safety of path planning. The global path key points generated by the improved RRT algorithm are used as the subtarget points of the DWA algorithm, and the DWA algorithm is optimized through the design of an adaptive evaluation function weighting method based on real-time obstacle distances to achieve more reasonable local path planning. Through simulation experiments, the fusion algorithm shows promising results in a variety of typical static and dynamic mixed driving scenarios, can effectively plan a path that meets the driving requirements of an unmanned vehicle, avoids unknown dynamic obstacles, and shows higher path optimization efficiency and driving stability in complex environments, which provides strong support for an unmanned vehicle’s path planning in complex environments.

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Enhanced Robot Motion Block of A-Star Algorithm for Robotic Path Planning

Cited by 3 publications

References 34 publications

Optimizing Mobile Robot Navigation Based on A-Star Algorithm for Obstacle Avoidance in Smart Agriculture

Optimizing Mobile Robot Navigation Based on A-Star Algorithm for Obstacle Avoidance in Smart Agriculture

Equipment control algorithm for cooling plant based on graph theory and path planning

Research on Unmanned Vehicle Path Planning Based on the Fusion of an Improved Rapidly Exploring Random Tree Algorithm and an Improved Dynamic Window Approach Algorithm

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