Path Planning for a Space-Based Manipulator System Based on Quantum Genetic Algorithm

Chen, Zhengcang; Zhou, Weijia

doi:10.1155/2017/3207950

Cited by 16 publications

(9 citation statements)

References 11 publications

(9 reference statements)

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“…Chen and Zohu [17] explained the problem of defining a path planning algorithm using the Quantum Genetic Algorithm. The solution works effectively for space based manipulators and help astronauts to avoid the harsh conditions faced when in space.…”

Section: Literature Surveymentioning

confidence: 99%

Motion Planning for a Chain of Mobile Robots Using A* and Potential Field

2018

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Traditionally, motion planning involved navigating one robot from source to goal for accomplishing a task. Now, tasks mostly require movement of a team of robots to the goal site, requiring a chain of robots to reach the desired goal. While numerous efforts are made in the literature for solving the problems of motion planning of a single robot and collective robot navigation in isolation, this paper fuses the two paradigms to let a chain of robot navigate. Further, this paper uses SLAM to first make a static map using a high-end robot, over which the physical low-sensing robots run. Deliberative Planning uses A* algorithm to plan the path. Reactive planning uses the Potential Field Approach to avoid obstacles and stay as close to the initial path planned as possible. These two algorithms are then merged to provide an algorithm that allows the robot to reach its goal via the shortest path possible while avoiding obstacles. The algorithm is further extended to multiple robots so that one robot is followed by the next robot and so on, thus forming a chain. In order to maintain the robots in a chain form, the Elastic Strip model is used. The algorithm proposed successfully executes the above stated when tested on Amigobot robots in an office environment using a map made by the Pioneer LX robot. The proposed algorithm works well for moving a group of robots in a chain in a mapped environment.

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Section: Literature Surveymentioning

confidence: 99%

Motion Planning for a Chain of Mobile Robots Using A* and Potential Field

2018

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“…is contemporary optimization algorithm is in wide-spread use. Silveira et al used QGA to implement a novel approach for ordering optimization problems [37]; Chen et al used QGA for a path planning problem [38]; Guan and Lin implemented a system to obtain a structural optimal design for ships using QGA [39]; Ning et al used QGA to solve a "job shop scheduling problem" in their study [40]; and Konar et al implemented a novel QGA as a hybrid quantum-inspired genetic algorithm to solve the problem of scheduling real-time tasks in multiprocessor systems [41]. DRV-P-MC, the focus of interest in our study, is an optimization problem as well, so this algorithm's efficient run-time performance is employed to determine suitable cluster positions on a 2D map.…”

Section: Related Workmentioning

confidence: 99%

Novel Two-Dimensional Visualization Approaches for Multivariate Centroids of Clustering Algorithms

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Birant

et al. 2018

Scientific Programming

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The dimensionality reduction and visualization problems associated with multivariate centroids obtained by clustering algorithms are addressed in this paper. Two approaches are used in the literature for the solution of such problems, specifically, the self-organizing map (SOM) approach and mapping selected two features manually (MS2Fs). In addition, principle component analysis (PCA) was evaluated as a component for solving this problem on supervised datasets. Each of these traditional approaches has drawbacks: if SOM runs with a small map size, all centroids are located contiguously rather than at their original distances according to the high-dimensional structure; MS2Fs is not an efficient method because it does not take features outside of the method into account, and lastly, PCA is a supervised method and loses the most valuable feature. In this study, five novel hybrid approaches were proposed to eliminate these drawbacks by using the quantum genetic algorithm (QGA) method and four feature selection methods, Pearson’s correlation, gain ratio, information gain, and relief methods. Experimental results demonstrate that, for 14 datasets of different sizes, the prediction accuracy of the proposed weighted clustering approaches is higher than the traditional K-means++ clustering approach. Furthermore, the proposed approach combined with K-means++ and QGA shows the most efficient placements of the centroids on a two-dimensional map for all the test datasets.

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“…In 2007, Zhang et al adaptively adjusted crossover and mutation probabilities by utilizing a clustering-based technique [7]. Preceding this paper, GA and its innovations have been successfully deployed in a wide range of non-trivial complicated real-world issues, from optimization of flight control laws [8] to aerodynamic optimization problems [9]; from small wind turbine design [10] to path planning of a space-based of a manipulator system [11]; and from modeling collinear data [12] to ship navigation in collision situations [13].…”

Section: Introductionmentioning

confidence: 99%

Improved Genetic Algorithm Tuning Controller Design for Autonomous Hovercraft

et al. 2020

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By mimicking the biological evolution process, genetic algorithm (GA) methodology has the advantages of creating and updating new elite parameters for optimization processes, especially in controller design technique. In this paper, a GA improvement that can speed up convergence and save operation time by neglecting chromosome decoding step is proposed to find the optimized fuzzy-proportional-integral-derivative (fuzzy-PID) control parameters. Due to minimizing tracking error of the controller design criterion, the fitness function integral of square error (ISE) was employed to utilize the advantages of the modified GA. The proposed method was then applied to a novel autonomous hovercraft motion model to display the superiority to the standard GA.

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Path Planning for a Space-Based Manipulator System Based on Quantum Genetic Algorithm

Cited by 16 publications

References 11 publications

Motion Planning for a Chain of Mobile Robots Using A* and Potential Field

Motion Planning for a Chain of Mobile Robots Using A* and Potential Field

Novel Two-Dimensional Visualization Approaches for Multivariate Centroids of Clustering Algorithms

Improved Genetic Algorithm Tuning Controller Design for Autonomous Hovercraft

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