RFID-Based Mobile Robot Trajectory Tracking and Point Stabilization Through On-line Neighboring Optimal Control

Miah, Suruz; Gueaieb, Wail

doi:10.1007/s10846-014-0048-3

Cited by 21 publications

(25 citation statements)

References 54 publications

(72 reference statements)

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“…The main differences between the current work and our previously relevant published articles (see [25], [26], [22], [23], [24]) are the following. In [25], [26], both time-varying and time-invariant feedback laws are established but they are tailored towards solving the tracking problems of semilinear dynamic systems only, which are not applicable for nonlinear affine systems (differential drive mobile robots, for example) as in the current work.…”

Section: Introductionmentioning

confidence: 81%

“…1. Following [23], let u L and u R , respectively, be the robot's left and right wheel angular velocities. The robot's position is the midpoint of the wheelbase of length l connecting the two lateral wheels along their axis.…”

Section: Mobile Robot Model and Problem Statementmentioning

confidence: 99%

“…The controller parameters (similar to the feedback gain parameters in our current work) are iteratively determined by adopting several tuning methodologies proposed by the authors in [18], [19], [20], [21]. Recently, linear time-varying feedback laws in cooperation with optimal control theory are extensively used by Miah and Gueaieb, see [22], [23], [24] for solving both trajectory tracking and regulation problems of wheeled mobile robots in a unified manner. Here we extend these ideas for the case when the feedback operator is linear in state and is time-invariant, which provides a partial solution to the tracking and stabilization problems of nonholonomic mobile robots as pointed out by the Brockett's conditions in [2].…”

Section: Introductionmentioning

confidence: 99%

“…In [25], [26], both time-varying and time-invariant feedback laws are established but they are tailored towards solving the tracking problems of semilinear dynamic systems only, which are not applicable for nonlinear affine systems (differential drive mobile robots, for example) as in the current work. This issue is then overcome in our recent work [22], [23], [24] by developing measurement feedback laws, where the feedback operator is time-varying as opposed to the proposed feedback operator which is timeinvariant.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Linear time-invariant feedback operator for mobile robot trajectory tracking

Miah

Gueaieb

Farkas

et al. 2015

2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings

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Abstract-In this paper we propose a linear time-invariant (LTI) state feedback operator for nonholonomic mobile robots to track a pre-defined trajectory on a 2D planar region. Designing an on-line smooth state feedback control law is still among the major challenges for solving the trajectory tracking problem of nonholonomic systems including differential drive mobile robots. To address this problem, numerous nonlinear feedback control laws have been proposed to date. Most of these feedback control laws yield online solutions to the trajectory tracking problem with satisfactory tracking errors asymptotically. In most cases, they suffer from an overwhelming degree of computational complexity even to track a 2D trajectory using a simple unicyclelike nonholonomic system. The proposed control law offers an advantage of being smooth and LTI state-feedback in addition to its capability to address problems of partially observed systems. The shortcoming of the proposed control law is that the LTI feedback operator is computed off-line before the robot applies its control signal into the left and right wheels through their actuators. The theoretical results are supported by computer simulations followed by experiments with an e-puck mobile robot.

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Section: Introductionmentioning

confidence: 81%

Section: Mobile Robot Model and Problem Statementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Linear time-invariant feedback operator for mobile robot trajectory tracking

Miah

Gueaieb

Farkas

et al. 2015

2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings

Self Cite

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show abstract

“…Adaptive sliding mode control has been used to deal with the model uncertainty in wheeled mobile robots [7]. A radio frequency identification-based control method has also been proposed for a mobile robot [8], [9]. Moreover, wheeled mobile robots often encounter obstacles when working in complex environment [10].…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Control for Tracking and Obstacle Avoidance of a Wheeled Mobile Robot With Nonholonomic Constraint

Yang

Fan

Shi

et al. 2015

IEEE Trans. Contr. Syst. Technol.

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Abstract-This paper presents a novel control scheme for some problems on tracking and obstacle avoidance of a wheeled mobile robot with nonholonomic constraint. An extended state observer is introduced to estimate unknown disturbances and velocity information of the wheeled mobile robot. A nonlinear controller is designed to achieve tracking target and obstacle avoidance in complex environments. Note that tracking errors converge to a residual set outside the obstacle detection region. Moreover, the obstacle avoidance is also guaranteed inside the obstacle detection region. Simulation results are given to verify the effectiveness and robustness of the proposed design scheme.

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Optimal robot‐environment interaction using inverse differential Riccati equation

Nohooji

Howard

Cui

2019

Asian Journal of Control

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An optimal robot-environment interaction is designed by transforming an environment model into an optimal control problem. In the optimal control, the inverse differential Riccati equation is introduced as a fixed-end-point closed-loop optimal control over a specific time interval. Then, the environment model, including interaction force is formulated in a state equation, and the optimal trajectory is determined by minimizing a cost function. Position control is proposed, and the stability of the closed-loop system is investigated using the Lyapunov direct method. Finally, theoretical developments are verified through numerical simulation.

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RFID-Based Mobile Robot Trajectory Tracking and Point Stabilization Through On-line Neighboring Optimal Control

Cited by 21 publications

References 54 publications

Linear time-invariant feedback operator for mobile robot trajectory tracking

Linear time-invariant feedback operator for mobile robot trajectory tracking

Nonlinear Control for Tracking and Obstacle Avoidance of a Wheeled Mobile Robot With Nonholonomic Constraint

Optimal robot‐environment interaction using inverse differential Riccati equation

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