Tracking the Kinematically Optimal Trajectories by Mobile Manipulators

Galicki, M.

doi:10.1007/s10846-018-0868-7

Cited by 7 publications

(14 citation statements)

References 55 publications

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“…As can be seen in Table 6, some refs. [43,45,48,50,52,55] have used only one Lyapunov-like positive definite function in their stability analysis because of the structure and assumptions they have made. For example, control methods designed in [43,45,48] have not contained any adaptive mechanisms or estimators.…”

Section: Evaluation Of Finite-time Control Designsmentioning

confidence: 99%

“…Utilizing an output feedback design, a finite-time non-linear control scheme [49] was proposed for a non-holonomic WMR. Guaranteeing the finite-time stabilization, a torque-based robust controller [50] and a second-order sliding-mode control [51] were developed for a mobile manipulator and a WMR, respectively. A kinematic/dynamic controller equipped with an adaptive neural network control method [52] was designed for finite-time trajectory tracking of WMRs with uncertainties.…”

Section: Introductionmentioning

confidence: 99%

“…• Motivated by refs. [43,45,46,47,48,50,52] which have developed finite-time stability and refs. [36,[53][54][55][56] which have provided semi-global practical finite-time stability, the finite-time convergence of inner closed-loop system is ensured by employing a non-singular sliding surface, and two Lyapunov-like positive definite functions.…”

Section: Introductionmentioning

confidence: 99%

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A finite‐time adaptive Taylor series tracking control of electrically‐driven wheeled mobile robots

Fateh

Ahmadi

2022

IET Control Theory & Appl

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This research seeks to address a new integrated kinematic/dynamic adaptive Taylor series‐based control design for the robust tracking of electrically‐driven differential drive wheeled mobile robots (WMRs). This control design includes two loops, namely the outer loop (a kinematic control law) and the inner loop (a dynamic controller). Being capable of compensating for far initial conditions from a desired trajectory, a new kinematic control law is designed to make the posture tracking error converge to zero asymptotically as well as to generate a desired trajectory for a dynamic controller. The key role of the dynamic controller is to compensate for lumped uncertainties. To do this, the proposed chattering‐free dynamic controller guarantees that the defined sliding surface which is a function of tracking error and its time derivative will be converged to zero within a finite time. The exact stability analysis of inner closed‐loop system is developed via two Lyapunov‐like positive definite functions to ensure not only the boundedness of all signals but also the finite‐time convergence of sliding surface to zero. The proposed control algorithm is validated by means of various simulations, including comparisons with well‐designed kinematic and integrated kinematic/dynamic control literature.

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Section: Evaluation Of Finite-time Control Designsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A finite‐time adaptive Taylor series tracking control of electrically‐driven wheeled mobile robots

Fateh

Ahmadi

2022

IET Control Theory & Appl

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“…In [17] a model predictive control algorithm has been applied to tracking control a free-floating space robot. Desirable performance qualities characterize the finite-time tracking algorithm for mobile manipulators, based on the terminal sliding mode manifold technique, described in [4]. As is well known, both the predictive control as well as the sliding mode control exhibit some robustness against model uncertainty and external disturbance.…”

Section: Introductionmentioning

confidence: 99%

Normal form approach in the motion planning of space robots: a case study

Tchoń

Zadarnowska

2021

Nonlinear Dyn

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We examine applicability of normal forms of non-holonomic robotic systems to the problem of motion planning. A case study is analyzed of a planar, free-floating space robot consisting of a mobile base equipped with an on-board manipulator. It is assumed that during the robot’s motion its conserved angular momentum is zero. The motion planning problem is first solved at velocity level, and then torques at the joints are found as a solution of an inverse dynamics problem. A novelty of this paper lies in using the chained normal form of the robot’s dynamics and corresponding feedback transformations for motion planning at the velocity level. Two basic cases are studied, depending on the position of mounting point of the on-board manipulator. Comprehensive computational results are presented, and compared with the results provided by the Endogenous Configuration Space Approach. Advantages and limitations of applying normal forms for robot motion planning are discussed.

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“…Systems generally made up of two or more mobile manipulator robots that fulfill a common objective are called collaborative robots [10] which allows for multi-tasking operations [11], allowing standard controllers to cooperate with each other, to perform complex tasks that cannot be performed by a single robot [12], The control schemes of the collaborative robots are mainly based on: i) centralized architecture in which the central computer generates the control actions to achieve the secondary projections [13]; ii) decentralized architecture, in which all components of the robotic system consist of the proprietary processing unit which develops both kinematic and dynamic control [13].…”

Section: Introductionmentioning

confidence: 99%

Collaborative Control of Mobile Manipulator Robots Through the Hardware-in-the-Loop Technique

Santo

Tandalla

Andaluz

2021

Proceedings of Sixth International Congress on Information and Communication Technology

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This article aims at designing and implementing the "Hardware in the Loop" (HIL) technique, to evaluate the collaborative control algorithm of two mobile manipulator robots to carry out tasks of movement and manipulation of objects in an industrial environment. The developed control structure is made up of a centralized control algorithm, developed in Matlab mathematical software, which is linked to the HIL system, which contains both the kinematic model and the dynamic model of each robotic system programmed on the Raspberry Pi. To analyze the optimal functioning of the proposed control algorithm, an immersive virtual reality scenario is designed and implemented using the UNITY3D graphic engine, which facilitates interaction with the user.

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Tracking the Kinematically Optimal Trajectories by Mobile Manipulators

Cited by 7 publications

References 55 publications

A finite‐time adaptive Taylor series tracking control of electrically‐driven wheeled mobile robots

A finite‐time adaptive Taylor series tracking control of electrically‐driven wheeled mobile robots

Normal form approach in the motion planning of space robots: a case study

Collaborative Control of Mobile Manipulator Robots Through the Hardware-in-the-Loop Technique

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