Smooth collision avoidance for the formation control of first order multi-agent systems

Jaime González-Sierra; E. G. Hernandez-Martinez; Mario Ramírez-Neria; Guillermo Fernandez-Anaya

doi:10.1016/j.robot.2023.104433

Smooth collision avoidance for the formation control of first order multi-agent systems

Jaime González-Sierra, E. G. Hernandez-Martinez, Mario Ramírez-Neria, Guillermo Fernandez-Anaya

Unidad Profesional Interdisciplinaria de Ingeniería, Campus Hidalgo (UPIIH)

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

This work addresses collision avoidance in the formation control of a group of mobile robots with first-order dynamics perturbed by lateral and longitudinal slipping parameters. A Generalized Proportional–Integral Observer (GPIO) is designed to estimate these perturbations. Then, an Active Disturbance Rejection Control (ADRC) is proposed to solve the well-known formation control avoiding collisions among the agents. The control strategy only depends on the agents’ position measurements. On the other hand, Continuous Repulsive Vector Fields (C-RVFs) are developed to avoid collisions among the agents. For this purpose, a parameter depending on the inter-robot distance is developed to scale the RVFs properly. By proposing C-RVFs, the chattering is eliminated when using Discontinuous RVFs (D-RVFs). Numerical simulations and real-time experiments illustrate the agents’ performance when they are at risk of collision.

Original language	English
Article number	104433
Journal	Robotics and Autonomous Systems
Volume	165
DOIs	https://doi.org/10.1016/j.robot.2023.104433
State	Published - Jul 2023

Keywords

Collision avoidance
First-order agents
Formation control
Multi-agent system
Observer

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10.1016/j.robot.2023.104433

Cite this

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title = "Smooth collision avoidance for the formation control of first order multi-agent systems",

abstract = "This work addresses collision avoidance in the formation control of a group of mobile robots with first-order dynamics perturbed by lateral and longitudinal slipping parameters. A Generalized Proportional–Integral Observer (GPIO) is designed to estimate these perturbations. Then, an Active Disturbance Rejection Control (ADRC) is proposed to solve the well-known formation control avoiding collisions among the agents. The control strategy only depends on the agents{\textquoteright} position measurements. On the other hand, Continuous Repulsive Vector Fields (C-RVFs) are developed to avoid collisions among the agents. For this purpose, a parameter depending on the inter-robot distance is developed to scale the RVFs properly. By proposing C-RVFs, the chattering is eliminated when using Discontinuous RVFs (D-RVFs). Numerical simulations and real-time experiments illustrate the agents{\textquoteright} performance when they are at risk of collision.",

keywords = "Collision avoidance, First-order agents, Formation control, Multi-agent system, Observer",

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AU - González-Sierra, Jaime

AU - Hernandez-Martinez, E. G.

AU - Ramírez-Neria, Mario

AU - Fernandez-Anaya, Guillermo

PY - 2023/7

Y1 - 2023/7

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AB - This work addresses collision avoidance in the formation control of a group of mobile robots with first-order dynamics perturbed by lateral and longitudinal slipping parameters. A Generalized Proportional–Integral Observer (GPIO) is designed to estimate these perturbations. Then, an Active Disturbance Rejection Control (ADRC) is proposed to solve the well-known formation control avoiding collisions among the agents. The control strategy only depends on the agents’ position measurements. On the other hand, Continuous Repulsive Vector Fields (C-RVFs) are developed to avoid collisions among the agents. For this purpose, a parameter depending on the inter-robot distance is developed to scale the RVFs properly. By proposing C-RVFs, the chattering is eliminated when using Discontinuous RVFs (D-RVFs). Numerical simulations and real-time experiments illustrate the agents’ performance when they are at risk of collision.

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KW - First-order agents

KW - Formation control

KW - Multi-agent system

KW - Observer

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Smooth collision avoidance for the formation control of first order multi-agent systems

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Keywords

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