Regular Papers

International Journal of Control, Automation and Systems 2018; 16(6): 2790-2800

Published online November 21, 2018

https://doi.org/10.1007/s12555-017-0234-8

© The International Journal of Control, Automation, and Systems

Design and Stability Analysis of a Fractional Order State Feedback Controller for Trajectory Tracking of a Differential Drive Robot

Omar Waleed Abdulwahhab* and Nizar Hadi Abbas

University of Baghdad

Abstract

n this paper, a new structure of a Fractional Order State Feedback Controller (FOSFC) is designed to solve the problem of trajectory tracking of a Differential Drive Robot (DDR), which is a nonlinear Multi-Input Multi-Output (MIMO) system. One of the main features of this paper is that it considers both the kinematic and dynamic models of the robot. For comparison purposes, a conventional Integer Order State Feedback Controller (IOSFC) is designed for the same system. The parameters of both controllers are tuned (using the fmincon Matlab function) to minimize the Integral of Time multiplied by Squared Error (ITSE) performance index when the DDR tracks a circular reference trajectory. The FOSFC gives a better value for this performance index than that of the IOSFC, which means that the FOSFC enhances the performance of the system with respect to this performance index. While the stability of the closed loop system is verified using Lyapunovs direct method for the IOSFC, a new approach is presented in this paper to analyze the stability of the closed loop system for the designed FOSFC. Simulation results demonstrate that the FOSFC outperforms the IOSFC for two other performance indices, namely, the Integral of Absolute Error (IAE) and the Integral of Squared Error (ISE)."

Keywords Differential drive robot, fractional order state feedback controller, integral of time multiplied by squared error, Lyapunovs direct method, Lyapunovs indirect method, trajectory tracking.

Article

Regular Papers

International Journal of Control, Automation and Systems 2018; 16(6): 2790-2800

Published online December 1, 2018 https://doi.org/10.1007/s12555-017-0234-8

Copyright © The International Journal of Control, Automation, and Systems.

Design and Stability Analysis of a Fractional Order State Feedback Controller for Trajectory Tracking of a Differential Drive Robot

Omar Waleed Abdulwahhab* and Nizar Hadi Abbas

University of Baghdad

Abstract

n this paper, a new structure of a Fractional Order State Feedback Controller (FOSFC) is designed to solve the problem of trajectory tracking of a Differential Drive Robot (DDR), which is a nonlinear Multi-Input Multi-Output (MIMO) system. One of the main features of this paper is that it considers both the kinematic and dynamic models of the robot. For comparison purposes, a conventional Integer Order State Feedback Controller (IOSFC) is designed for the same system. The parameters of both controllers are tuned (using the fmincon Matlab function) to minimize the Integral of Time multiplied by Squared Error (ITSE) performance index when the DDR tracks a circular reference trajectory. The FOSFC gives a better value for this performance index than that of the IOSFC, which means that the FOSFC enhances the performance of the system with respect to this performance index. While the stability of the closed loop system is verified using Lyapunovs direct method for the IOSFC, a new approach is presented in this paper to analyze the stability of the closed loop system for the designed FOSFC. Simulation results demonstrate that the FOSFC outperforms the IOSFC for two other performance indices, namely, the Integral of Absolute Error (IAE) and the Integral of Squared Error (ISE)."

Keywords: Differential drive robot, fractional order state feedback controller, integral of time multiplied by squared error, Lyapunovs direct method, Lyapunovs indirect method, trajectory tracking.

IJCAS
September 2024

Vol. 22, No. 9, pp. 2673~2953

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