Exploiting Subgraph Structure in Multi-Robot Path Planning

This paper presents a new methodology based on neural dynamics for optimal robot path planning by drawing an analogy between cellular neural network (CNN) and path planning of mobile robots. The target activity is treated as an energy source injected into the neural system and is propagated through the local connectivity of cells in the state space by neural dynamics. By formulating the local connectivity of cells as the local interaction of harmonic functions, an improved CNN model is established to propagate the target activity within the state space in the manner of physical heat conduction, which guarantees that the target and obstacles remain at the peak and the bottom of the activity landscape of the neural network. The proposed methodology cannot only generate real-time, smooth, optimal, and collision-free paths without any prior knowledge of the dynamic environment, but it can also easily respond to the real-time changes in dynamic environments. Further, the proposed methodology is parameter-independent and has an appropriate physical meaning.

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Optimal Robot Path Planning With Cellular Neural Network

Rapid Automation ◽

10.4018/978-1-5225-8060-7.ch023 ◽

2019 ◽

pp. 491-511

Author(s):

Yongmin Zhong ◽

Bijan Shirinzadeh ◽

Xiaobu Yuan

Keyword(s):

Neural Network ◽

Path Planning ◽

State Space ◽

Real Time ◽

Cellular Neural Network ◽

Neural Dynamics ◽

Robot Path Planning ◽

Local Connectivity ◽

Target Activity ◽

Robot Path

This paper presents a new methodology based on neural dynamics for optimal robot path planning by drawing an analogy between cellular neural network (CNN) and path planning of mobile robots. The target activity is treated as an energy source injected into the neural system and is propagated through the local connectivity of cells in the state space by neural dynamics. By formulating the local connectivity of cells as the local interaction of harmonic functions, an improved CNN model is established to propagate the target activity within the state space in the manner of physical heat conduction, which guarantees that the target and obstacles remain at the peak and the bottom of the activity landscape of the neural network. The proposed methodology cannot only generate real-time, smooth, optimal, and collision-free paths without any prior knowledge of the dynamic environment, but it can also easily respond to the real-time changes in dynamic environments. Further, the proposed methodology is parameter-independent and has an appropriate physical meaning.

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Multi-robot path planning using an improved self-adaptive particle swarm optimization

International Journal of Advanced Robotic Systems ◽

10.1177/1729881420936154 ◽

2020 ◽

Vol 17 (5) ◽

pp. 172988142093615

Author(s):

Biwei Tang ◽

Kui Xiang ◽

Muye Pang ◽

Zhu Zhanxia

Keyword(s):

Particle Swarm Optimization ◽

Path Planning ◽

Evolutionary Game ◽

Particle Swarm ◽

Computation Time ◽

Robot Path Planning ◽

Swarm Optimization ◽

Robot Path ◽

Self Adaptive ◽

Multi Robot

Path planning is of great significance in motion planning and cooperative navigation of multiple robots. Nevertheless, because of its high complexity and nondeterministic polynomial time hard nature, efficiently tackling with the issue of multi-robot path planning remains greatly challenging. To this end, enhancing a coevolution mechanism and an improved particle swarm optimization (PSO) algorithm, this article presents a coevolution-based particle swarm optimization method to cope with the multi-robot path planning issue. Attempting to well adjust the global and local search abilities and address the stagnation issue of particle swarm optimization, the proposed particle swarm optimization enhances a widely used standard particle swarm optimization algorithm with the evolutionary game theory, in which a novel self-adaptive strategy is proposed to update the three main control parameters of particles. Since the convergence of particle swarm optimization significantly influences its optimization efficiency, the convergence of the proposed particle swarm optimization is analytically investigated and a parameter selection rule, sufficiently guaranteeing the convergence of this particle swarm optimization, is provided in this article. The performance of the proposed planning method is verified through different scenarios both in single-robot and in multi-robot path planning problems. The numerical simulation results reveal that, compared to its contenders, the proposed method is highly promising with respect to the path optimality. Also, the computation time of the proposed method is comparable with those of its peers.

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