A framework for the stabilization of general nonholonomic systems with an application to the plate-ball mechanism

Oriolo, Giuseppe; Vendittelli, Marilena

doi:10.1109/tro.2004.839231

Cited by 69 publications

(55 citation statements)

References 42 publications

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“…[31]). Another possible generalization takes advantage of devising from our algorithm a globally regular input, one can then address the motion planning of dynamical extensions of the nonholonomic control systems considered in the present paper.…”

Section: : End Formentioning

confidence: 99%

A global steering method for nonholonomic systems

Chitour

Jean

Long

2013

Journal of Differential Equations

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In this paper, we present an iterative steering algorithm for nonholonomic systems (also called driftless control-affine systems) and we prove its global convergence under the sole assumption that the Lie Algebraic Rank Condition (LARC) holds true everywhere. That algorithm is an extension of the one introduced in Jean et al. (2005) [21] for regular systems. The first novelty here consists in the explicit algebraic construction, starting from the original control system, of a lifted control system which is regular. The second contribution of the paper is an exact motion planning method for nilpotent systems, which makes use of sinusoidal control laws and which is a generalization of the algorithm described in Murray and Sastry (1993) [29] for chainedform systems.

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Section: : End Formentioning

confidence: 99%

A global steering method for nonholonomic systems

Chitour

Jean

Long

2013

Journal of Differential Equations

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“…This corresponds in a robot displacement of about 2 cm with respect to the target position. However it is our plan to improve performances and increase robustness by setting the proposed two-step controller in an iterative framework as proposed in [13], [22] for nonholonomic robots. The robot motion under the action of the proposed control law, from the starting position to the target one, is reported in Fig.…”

Section: Resultsmentioning

confidence: 99%

Image-Based Visual Servoing for Nonholonomic Mobile Robots Using Epipolar Geometry

2007

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Abstract-We present an image-based visual servoing strategy for nonholonomic mobile robot equipped with a central catadioptric camera. This kind of vision sensor combines lens and mirrors to enlarge the field of view. The proposed approach, which exploits the epipolar geometry defined by the current and the desired camera views, does not need any knowledge of the 3-D scene geometry. The control scheme is divided in two steps. In the first one, the epipoles are used used together with an approximate input-output linearizing feedback to align the robot with the goal. Feature points are then used in the second translation step to reach the desired configuration. Global asymptotic convergence is proven. Simulation and experimental results show the effectiveness of the proposed control scheme.

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“…A detailed extension of some of the planning and control techniques reviewed in this article to the case of car-like kinematics is given in De Luca et al (1998). A framework for the stabilization of non-flat nonholonomic robots was presented by Oriolo and Vendittelli (2005). Recent work aimed at designing practical universal controllers was carried out by Morin and Samson (2009).…”

Section: Recommended Readingmentioning

confidence: 99%

Wheeled Robots

Oriolo¹

2014

Encyclopedia of Systems and Control

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The use of mobile robots in service applications is steadily increasing. Most of these systems achieve locomotion using wheels. As a consequence, they are subject to differential constraints that are nonholonomic, i.e., non-integrable. This article reviews the kinematic models of wheeled robots arising from these constraints and discusses their fundamental properties and limitations from a control viewpoint. An overview of the main approaches for trajectory planning and feedback motion control is provided.

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A framework for the stabilization of general nonholonomic systems with an application to the plate-ball mechanism

Cited by 69 publications

References 42 publications

A global steering method for nonholonomic systems

A global steering method for nonholonomic systems

Image-Based Visual Servoing for Nonholonomic Mobile Robots Using Epipolar Geometry

Wheeled Robots

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