Graph Theory-Based Approach to Accomplish Complete Coverage Path Planning Tasks for Reconfigurable Robots

Ku, Ping-Cheng; Mohan, Rajesh Elara; Nhân, Nguyễn Hữu; Le, Anh Vu

doi:10.1109/access.2019.2928467

Cited by 46 publications

(31 citation statements)

References 32 publications

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“…PP problem is modeled differently in reconfigurable robots and in fixed morphology robots. For fixed-morphology robots, exhaustive search such as Dijkstra and A* algorithms are commonly utilized to solve global PP problems; on the other hand, Ant Colony Optimization (ACO) [20], Particle Swarm Optimization (PSO) [21], Neural Network [22], Motion Planning [23], Path Tracking [24], Graph theory [25] and Genetic Algorithm (GA) [26] have been implemented to solve local PP problems. Among the existing PP methods, GA has shown its strength in convenient modeling, easy implementation, and practical problem solving [27] due to its flexibility to perform optimization without prior information [28], and its ability to explore the solution space [29], which hinges on the advantages of both deterministic and probabilistic schemes to improve solutions using operators like crossover and mutation [30].…”

Section: Introductionmentioning

confidence: 99%

Multi-Objective Genetic Algorithm-Based Autonomous Path Planning for Hinged-Tetro Reconfigurable Tiling Robot

Elara

Nhan

et al. 2020

IEEE Access

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Reconfigurable robots have received broad research interest due to the high dexterity they provide and the complex actions they could perform. Robots with reconfigurability are perfect candidates in tasks like exploration or rescue missions in environments with complicated obstacle layout or with dynamic obstacles. However, the automation of reconfigurable robots is more challenging than fix-shaped robots due to the increased possible combinations of robot actions and the navigation difficulty in obstaclerich environments. This paper develops a systematic strategy to construct a model of hinged-Tetromino (hTetro) reconfigurable robot in the workspace and proposes a genetic algorithm-based method (hTetro-GA) to achieve path planning for hTetro robots. The proposed algorithm considers hTetro path planning as a multi-objective optimization problem and evaluates the performance of the outcome based on four customized fitness objective functions. In this work, the proposed hTetro-GA is tested in six virtual environments with various obstacle layouts and characteristics and with different population sizes. The algorithm generates Pareto-optimal solutions that achieve desire robot configurations in these settings, with O-shaped and I-shaped morphologies being the more efficient configurations selected from the genetic algorithm. The proposed algorithm is implemented and tested on real hTetro platform, and the framework of this work could be adopted to other robot platforms with multiple configurations to perform multi-objective based path planning. INDEX TERMS Reconfigurable robot, Tiling robotics, Multi-objective path planning, Genetic algorithm, NSGA-II.

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Section: Introductionmentioning

confidence: 99%

Multi-Objective Genetic Algorithm-Based Autonomous Path Planning for Hinged-Tetro Reconfigurable Tiling Robot

Elara

Nhan

et al. 2020

IEEE Access

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“…Other techniques can slip the map equally based on each sub-region complexity, such as the isolated method used in Morse [17] work. A number of different methods combine the use of graph theory [18], and high-order observers-based LQ control scheme [19]. The other common and popular methods are the standard grid-based probability assignment proposed by Moravec and Elfes [20] and Choset [21].…”

Section: Introductionmentioning

confidence: 99%

Reinforcement Learning-Based Energy-Aware Area Coverage for Reconfigurable hRombo Tiling Robot

Parween

Kyaw

et al. 2020

IEEE Access

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“…There are numerous algorithms proposed towards realizing grid-based coverage such as wavefront algorithm, 13 spanning tree technique, 14 hexagonal grid decomposition, 15 and graph theory-based coverage. 16 Xu 17 presented a graph-based CPP technique, in which he considers the mapped area as a graph and applies robot motion planning to reach every coordinate point in the graph. In recent years, several 3-D area coverage techniques have been proposed and validated in the context of service robots.…”

Section: Introductionmentioning

confidence: 99%

Motion planner for a Tetris-inspired reconfigurable floor cleaning robot

Veerajagadheswar

Elara

et al. 2020

International Journal of Advanced Robotic Systems

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Coverage path planning technique is an essential ingredient in every floor cleaning robotic systems. Even though numerous approaches demonstrate the benefits of conventional coverage motion planning techniques, they are mostly limited to fixed morphological platforms. In this article, we put forward a novel motion planning technique for a Tetris-inspired reconfigurable floor cleaning robot named “hTetro” that can reconfigure its morphology to any of the seven one-sided Tetris pieces. The proposed motion planning technique adapts polyomino tiling theory to tile a defined space, generates reference coordinates, and produces a navigation path to traverse on the generated tile-set with an objective of maximizing the area coverage. We have summarized all these aspects and concluded with experiments in a simulated environment that benchmarks the proposed technique with conventional approaches. The results show that the proposed motion planning technique achieves significantly higher performance in terms of area recovered than the traditional methods.

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Graph Theory-Based Approach to Accomplish Complete Coverage Path Planning Tasks for Reconfigurable Robots

Cited by 46 publications

References 32 publications

Multi-Objective Genetic Algorithm-Based Autonomous Path Planning for Hinged-Tetro Reconfigurable Tiling Robot

Multi-Objective Genetic Algorithm-Based Autonomous Path Planning for Hinged-Tetro Reconfigurable Tiling Robot

Reinforcement Learning-Based Energy-Aware Area Coverage for Reconfigurable hRombo Tiling Robot

Motion planner for a Tetris-inspired reconfigurable floor cleaning robot

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