Non-Collision Conditions in Multi-Agent Virtual Leader-Based Formation Control

Hernández‐Martínez, Eduardo Gamaliel; Bricaire, Eduardo Aranda

doi:10.5772/50722

Cited by 11 publications

(6 citation statements)

References 32 publications

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“…Representation of the robot leader and the robot follower as material points If some robot from the swarm is assigned as the leader, the stability of the swarm is at serious risk: in the case of a leader failure, the whole swarm becomes inoperable. To solve such a problem, we can identify a virtual leader and support a distance related to it [18]. The position of the virtual leader can be simply marked in the center of the swarm.…”

Section: Leader-follower Approachmentioning

confidence: 99%

Method of Coordination of Motion of Swarm Robotic Systems

Kyzyrkanov,

Atanov,

Aljawarneh

et al. 2023

sjaitu

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Maintaining a specific geometric pattern is essential in various applications where groups of autonomous robots must follow a given path. Proper organization of the geometric pattern can lead to several benefits such as cost reduction, increased system reliability, and efficiency while providing a reconfigurable and flexible structure of the system. Military missions and traffic systems are examples where maintaining certain geometric patterns are widely used. However, little is known about how to develop an effective algorithm that guarantees collision avoidance and obstacle avoidance while maintaining the geometric pattern. This paper presents an algorithm for movement with a certain geometric structure of a group of autonomous mobile robots that maintains the required geometric pattern and ensures the avoidance of collisions and obstacles. The proposed algorithm is behavior-based and utilizes a set of rules that allow the robots to navigate around obstacles and avoid collisions. The algorithm's performance is demonstrated through simulations in a variety of scenarios with different numbers of robots and geometric patterns. The algorithm proposed in this paper provides an effective solution for controlling a group of autonomous mobile robots to maintain a certain geometric pattern. The proposed algorithm has the potential to be utilized in numerous applications where multiple robots must work together to achieve a common goal while maintaining a specific formation. The use of behavior-based approach and obstacle avoidance rules ensures that the robots avoid collisions and obstacles while maintaining the required pattern

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Section: Leader-follower Approachmentioning

confidence: 99%

Method of Coordination of Motion of Swarm Robotic Systems

Kyzyrkanov,

Atanov,

Aljawarneh

et al. 2023

sjaitu

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“…Theorem 2. Consider the system (12) and the control law (22) along with definitions (13), (20) and (21). Suppose at the time instant t 0 there exists an agent, say R r , which is in risk of collision with…”

Section: Collision Avoidancementioning

confidence: 99%

“…[8][9][10][11] In a first approach, collisions can be predicted, but not avoided, from initial conditions. 12,13 This can be useful if such initial conditions can be selected properly. Another, and the most known approach, consists in the use of Repulsive Potential Functions (RPFs) in combination with Attractive Potential Functions.…”

Section: Introductionmentioning

confidence: 99%

A General Solution to the Formation Control Problem Without Collisions for First-Order Multi-Agent Systems

Flores-Resendiz¹,

Aranda-Bricaire

2019

Robotica

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SUMMARYIn this paper, a general solution to the formation control problem without collisions for first-order multi-agent systems is proposed. The case of an arbitrary number of mobile agents on a plane with saturated input velocity is analysed. Besides, conditions on the communication graph among agents are relaxed to the only requirement of containing a directed spanning tree. This general approach is an extended result from the simpler case of combinations of cyclic pursuit communication graphs. The proposed solution to this problem is designed in two steps. First, the asymptotic convergence in the absence of collisions is ensured. After this, the non-collision problem is faced by analysing the most general possible geometrical scenario which can lead to collision among agents. Discontinuous vector fields with unstable counterclockwise focus behaviour are applied by every agent in order to repel each other. Numerical simulations illustrate the performance of the proposed scheme.

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“…The main contribution is an original formal proof about the convergence of robots to multiple equilibria where the robots are placed in the desired formation. The collision avoidance is not included in the analysis following the practical assumptions of [8,25,26] where reactive routines appear momentarily if the robots detect a shock danger or if the initial postures of robots generated free-collision trajectories, which occur frequently in the nature behaviors.…”

Section: Introductionmentioning

confidence: 99%

Decentralized Discrete-Time Formation Control for Multirobot Systems

Hernández‐Martínez

Flores-Godoy

Fernández‐Anaya

2013

Discrete Dynamics in Nature and Society

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Inspired from the collective behavior of biological entities for the group motion coordination, this paper analyzes the formation control of mobile robots in discrete time where each robot can sense only the position of certain team members and the group behavior is achieved through the local interactions of robots. The main contribution is an original formal proof about the global convergence to the formation pattern represented by an arbitrary Formation Graph using attractive potential functions. The analysis is addressed for the case of omnidirectional robots with numerical simulations.

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Non-Collision Conditions in Multi-Agent Virtual Leader-Based Formation Control

Cited by 11 publications

References 32 publications

Method of Coordination of Motion of Swarm Robotic Systems

Method of Coordination of Motion of Swarm Robotic Systems

A General Solution to the Formation Control Problem Without Collisions for First-Order Multi-Agent Systems

Decentralized Discrete-Time Formation Control for Multirobot Systems

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