Routing problem in rectangular mesh network using shortest path based Greedy method

Adzhar, Noraziah; Salleh, Shaharuddin; Yusof, Yudariah Mohammad; Ahmad, Muhammad Azrin

doi:10.1088/1742-6596/1358/1/012079

Cited by 2 publications

(4 citation statements)

References 8 publications

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“…In the visibility graph, the obstacles are represented as polygons [ 50 ], and the vertical nodes of the polygonal obstacles are connected in such a way that the path length is minimized while the lines remain close to the obstacles. In contrast, the Voronoi graph uses the two closest points of the edges of the obstacles for planning and divides the domain into subdomains.…”

Section: Classic Approachesmentioning

confidence: 99%

“…Then, based on Darwinian evolutionary theory, they generate a new population using the three genetic operators (mutation, crossover, and selection). The new populations are created until the stopping conditions are met [ 50 ]. Such stopping conditions are a time limit, the required fitness value, and the maximum number of generations.…”

Section: Heuristic Approachmentioning

confidence: 99%

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Obstacle Avoidance and Path Planning Methods for Autonomous Navigation of Mobile Robot

Katona,

Neamah,

Korondi

2024

Sensors

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Path planning creates the shortest path from the source to the destination based on sensory information obtained from the environment. Within path planning, obstacle avoidance is a crucial task in robotics, as the autonomous operation of robots needs to reach their destination without collisions. Obstacle avoidance algorithms play a key role in robotics and autonomous vehicles. These algorithms enable robots to navigate their environment efficiently, minimizing the risk of collisions and safely avoiding obstacles. This article provides an overview of key obstacle avoidance algorithms, including classic techniques such as the Bug algorithm and Dijkstra’s algorithm, and newer developments like genetic algorithms and approaches based on neural networks. It analyzes in detail the advantages, limitations, and application areas of these algorithms and highlights current research directions in obstacle avoidance robotics. This article aims to provide comprehensive insight into the current state and prospects of obstacle avoidance algorithms in robotics applications. It also mentions the use of predictive methods and deep learning strategies.

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Section: Classic Approachesmentioning

confidence: 99%

Section: Heuristic Approachmentioning

confidence: 99%

Obstacle Avoidance and Path Planning Methods for Autonomous Navigation of Mobile Robot

Katona,

Neamah,

Korondi

2024

Sensors

View full text Add to dashboard Cite

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“…In the visibility graph, the obstacles are represented as polygons [15]. Te vertical of the polygonal obstacles have nodes connected.…”

Section: Artifcial Potential Field Khatibmentioning

confidence: 99%

“…An improvement of this method and its application in path planning have been presented in Fan and Shi [14], and it has been shown that the upgrades are reasonable and practical. Finally, in [15], the path planning problem in rectangular mesh networks was addressed by fnding the shortest link between each pair of sites using a Dijkstra-based greedy algorithm. [16] introduced the artifcial potential feld (APF) method for the mobile robotics problem by believing the divergences between attraction and repulsion forces help robot movement inside the environment.…”

Section: Dijkstra's Algorithm Edsger Wybe Dijkstra Introducedmentioning

confidence: 99%

A Review on Path Planning and Obstacle Avoidance Algorithms for Autonomous Mobile Robots

Rafai

Adzhar

Jaini

2022

Journal of Robotics

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Mobile robots have been widely used in various sectors in the last decade. A mobile robot could autonomously navigate in any environment, both static and dynamic. As a result, researchers in the robotics field have offered a variety of techniques. This paper reviews the mobile robot navigation approaches and obstacle avoidance used so far in various environmental conditions to recognize the improvement of path planning strategists. Taking into consideration commonly used classical approaches such as Dijkstra algorithm (DA), artificial potential field (APF), probabilistic road map (PRM), cell decomposition (CD), and meta-heuristic techniques such as fuzzy logic (FL), neutral network (NN), particle swarm optimization (PSO), genetic algorithm (GA), cuckoo search algorithm (CSO), and artificial bee colony (ABC). Classical approaches have limitations of trapping in local minima, failure to handle uncertainty, and many more. On the other hand, it is observed that heuristic approaches can solve most real-world problems and perform well after some modification and hybridization with classical techniques. As a result, many methods have been established worldwide for the path planning strategy for mobile robots. The most often utilized approaches, on the other hand, are offered below for further study.

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Routing problem in rectangular mesh network using shortest path based Greedy method

Cited by 2 publications

References 8 publications

Obstacle Avoidance and Path Planning Methods for Autonomous Navigation of Mobile Robot

Obstacle Avoidance and Path Planning Methods for Autonomous Navigation of Mobile Robot

A Review on Path Planning and Obstacle Avoidance Algorithms for Autonomous Mobile Robots

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