Motion control design for unmanned ground vehicle in dynamic environment using intelligent controller

To protect the personnel of the intervention units operating in high-risk areas, it is necessary to introduce (autonomous/semi-autonomous) robotic intervention systems. Previous studies have shown that robotic intervention systems should be as versatile as possible. Here, we focused on the idea of a robotic system composed of two vectors: a carrier vector and an operational vector. The proposed system particularly relates to the carrier vector. A simple analytical model was developed to enable the entire robotic assembly to be autonomous. To validate the analytical-numerical model regarding the kinematics and dynamics of the carrier vector, two of the following applications are presented: intervention for extinguishing a fire and performing measurements for monitoring gamma radiation in a public enclosure. The results show that the chosen carrier vector solution, i.e., the ground vehicle with six-wheel drive, satisfies the requirements related to the mobility of the robotic intervention system. In addition, the conclusions present the elements of the kinematics and dynamics of the robot.

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“…The implemented controllers integrate the systems, and the data flow was commercial off-the-shelf (COTS) accessible [ 43 , 44 ].…”

Section: Configuration Of the Intervention Robotmentioning

confidence: 99%

A Dynamic Motion Analysis of a Six-Wheel Ground Vehicle for Emergency Intervention Actions

Grigore

Gorgoteanu

Molder

et al. 2021

Sensors

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“…In the last thirty years, the use of mobile robots has gained great attention because of their broad potential in practical applications oriented toward the solution of important engineering problems [31][32][33][34][35][36]. For this purpose, several control approaches were developed for obtaining the stabilization and the trajectory tracking control of mobile robots [37][38][39][40][41][42][43]. In particular, in the field of robotics, the advantage of using wheeled mobile robots instead of legged mobile robots is widely accepted.…”

Section: Formulation Of the Problem Of Interest For This Studymentioning

confidence: 99%

Forward and Inverse Dynamics of a Unicycle-Like Mobile Robot

Pappalardo

Guida

2019

Machines

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In this research work, a new method for solving forward and inverse dynamic problems of mechanical systems having an underactuated structure and subjected to holonomic and/or nonholonomic constraints is developed. The method devised in this paper is based on the combination of the Udwadia-Kalaba Equations with the Underactuation Equivalence Principle. First, an analytical method based on the Udwadia-Kalaba Equations is employed in the paper for handling dynamic and control problems of nonlinear nonholonomic mechanical systems in the same computational framework. Subsequently, the Underactuation Equivalence Principle is used for extending the capabilities of the Udwadia-Kalaba Equations from fully actuated mechanical systems to underactuated mechanical systems. The Underactuation Equivalence Principle represents an efficient method recently developed in the field of classical mechanics. The Underactuation Equivalence Principle is used in this paper for mathematically formalizing the underactuation property of a mechanical system considering a particular set of nonholonomic algebraic constraints defined at the acceleration level. On the other hand, in this study, the Udwadia-Kalaba Equations are analytically reformulated in a mathematical form suitable for treating inverse dynamic problems. By doing so, the Udwadia-Kalaba Equations are employed in conjunction with the Underactuation Equivalence Principle for developing a nonlinear control method based on an inverse dynamic approach. As shown in detail in this investigation, the proposed method can be used for analytically solving in an explicit manner the forward and inverse dynamic problems of several nonholonomic mechanical systems. In particular, the tracking control of the unicycle-like mobile robot is considered in this investigation as a benchmark example. Numerical experiments on the dynamic model of the unicycle-like mobile robot confirm the effectiveness of the nonlinear dynamic and control approaches developed in this work.

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“…Patle, et al [102] have presented the firefly algorithm based path planning and obstacle avoidance for wheeled mobile robot in uncertain environment. Almayyahi, et al [103] have presented two fuzzy inference systems, one for obstacle avoidance and other for target reaching of the unmanned ground vehicle in the dynamic environment. Elbanhawi and Simic, [104] have made a critical review on motion planning of robot.…”

Section: Ant Colony Optimization Algorithm and Other Nondeterministicmentioning

confidence: 99%

Different Nature-Inspired Techniques Applied for Motion Planning of Wheeled Robot: A Critical Review

Kashyap

Pandey

2018

IJARA

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Motion planning is one of the most important parts when we design any wheeled or walking robots. The meaning of motion planning is to plan a path from start point to goal point between obstacles in any working environment. Many techniques have applied by researchers from last two-three decades for wheeled robot motion planning. This article presents a critical review on motion planning of wheeled robot by using different nature-inspired techniques like evolutionary algorithm and swarm-based optimization algorithm.

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Motion control design for unmanned ground vehicle in dynamic environment using intelligent controller

Cited by 22 publications

References 15 publications

A Dynamic Motion Analysis of a Six-Wheel Ground Vehicle for Emergency Intervention Actions

A Dynamic Motion Analysis of a Six-Wheel Ground Vehicle for Emergency Intervention Actions

Forward and Inverse Dynamics of a Unicycle-Like Mobile Robot

Different Nature-Inspired Techniques Applied for Motion Planning of Wheeled Robot: A Critical Review

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