Spatial Formation Control with Volume Information: Application to Quadcopter UAV's

E. D. Ferreira-Vazquez; E. G. Hernandez-Martinez; J. J. Flores-Godoy; G. Fernandez-Anaya

doi:10.1016/j.ifacol.2016.10.181

Spatial Formation Control with Volume Information: Application to Quadcopter UAV's

E. D. Ferreira-Vazquez, E. G. Hernandez-Martinez, J. J. Flores-Godoy, G. Fernandez-Anaya

Universidad Iberoamericana

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

2 Scopus citations

Abstract

This paper extends the distance-based formation control for the case of holonomic robots moving in 3D space. The approach is addressed for agents modeled as double-integrators with any undirected communication graphs. The control strategy uses a combined distance-based attractive-repulsive potentials to ensure convergence to the formation pattern avoiding possible inter-robot collisions. In order to avoid unwanted formation patterns that verify the distance constraints, each robot control law includes a volume condition which provides information about the unique desired position of each robot in the formation pattern. The proposed algorithm is tested by numerical simulations and extended to the case of quadcopters UAV's by an input-output linearization showing good behavior.

Original language	English
Pages (from-to)	302-307
Number of pages	6
Journal	IFAC-PapersOnLine
Volume	49
Issue number	18
DOIs	https://doi.org/10.1016/j.ifacol.2016.10.181
State	Published - 2016

Keywords

Artificial Potential Function
Collision Avoidance
Formation control
Mobile robots
Quadcopter UAV

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10.1016/j.ifacol.2016.10.181

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title = "Spatial Formation Control with Volume Information: Application to Quadcopter UAV's",

abstract = "This paper extends the distance-based formation control for the case of holonomic robots moving in 3D space. The approach is addressed for agents modeled as double-integrators with any undirected communication graphs. The control strategy uses a combined distance-based attractive-repulsive potentials to ensure convergence to the formation pattern avoiding possible inter-robot collisions. In order to avoid unwanted formation patterns that verify the distance constraints, each robot control law includes a volume condition which provides information about the unique desired position of each robot in the formation pattern. The proposed algorithm is tested by numerical simulations and extended to the case of quadcopters UAV's by an input-output linearization showing good behavior.",

keywords = "Artificial Potential Function, Collision Avoidance, Formation control, Mobile robots, Quadcopter UAV",

author = "Ferreira-Vazquez, {E. D.} and Hernandez-Martinez, {E. G.} and Flores-Godoy, {J. J.} and G. Fernandez-Anaya",

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T1 - Spatial Formation Control with Volume Information

T2 - Application to Quadcopter UAV's

AU - Ferreira-Vazquez, E. D.

AU - Hernandez-Martinez, E. G.

AU - Flores-Godoy, J. J.

AU - Fernandez-Anaya, G.

PY - 2016

Y1 - 2016

N2 - This paper extends the distance-based formation control for the case of holonomic robots moving in 3D space. The approach is addressed for agents modeled as double-integrators with any undirected communication graphs. The control strategy uses a combined distance-based attractive-repulsive potentials to ensure convergence to the formation pattern avoiding possible inter-robot collisions. In order to avoid unwanted formation patterns that verify the distance constraints, each robot control law includes a volume condition which provides information about the unique desired position of each robot in the formation pattern. The proposed algorithm is tested by numerical simulations and extended to the case of quadcopters UAV's by an input-output linearization showing good behavior.

AB - This paper extends the distance-based formation control for the case of holonomic robots moving in 3D space. The approach is addressed for agents modeled as double-integrators with any undirected communication graphs. The control strategy uses a combined distance-based attractive-repulsive potentials to ensure convergence to the formation pattern avoiding possible inter-robot collisions. In order to avoid unwanted formation patterns that verify the distance constraints, each robot control law includes a volume condition which provides information about the unique desired position of each robot in the formation pattern. The proposed algorithm is tested by numerical simulations and extended to the case of quadcopters UAV's by an input-output linearization showing good behavior.

KW - Artificial Potential Function

KW - Collision Avoidance

KW - Formation control

KW - Mobile robots

KW - Quadcopter UAV

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ER -

Spatial Formation Control with Volume Information: Application to Quadcopter UAV's

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