Your search keyword '"internal model control"' showing total 4 results

1. Fractional-order IMC controller for high-order system using reduced-order modelling via Big-Bang, Big-Crunch optimisation.

Author

Saxena, Sahaj and Biradar, Shivanagouda

Subjects

*REDUCED-order models, *MATHEMATICAL optimization, *INTERNAL auditing, *PID controllers, *TRACKING control systems, *INTEGRATORS, *NEWSVENDOR model

Abstract

Striking developments have taken place in feedback control theory after the evolution of the fractional-order (FO) control concept. However, for large-scale (high-order) systems, these well-established FO techniques become rigorous and lead to an infeasible solution. To overcome this issue, this paper proposes a three-fold control policy. The first step finds the optimal reduced-order (low-order) model using Big-Bang, Big-Crunch (BB–BC) optimisation algorithm. Based on the obtained reduced model, the control structure is formulated in the internal model control (IMC) framework. The controller acquires a PID form followed by an additional term and FO integrator. Unlike the FO-PID controller which demands five tuning parameters, the proposed controller requires only two tuning parameters whose evaluation is done on the basis of user specified gain crossover frequency and phase margin. To substantiate the design approach, a detailed simulation study has been carried out, in which the problems of tracking control, disturbance rejection, and time-delay compensation are illustrated. [ABSTRACT FROM AUTHOR]

Published

2022

2. Two-degree-of-freedom internal model position control and fuzzy fractional force control of nonlinear parallel robot.

Author

Wen, Shuhuan, Zhang, Di, Zhang, Baowei, Lam, Hak Keung, Wang, Hongbin, and Zhao, Yongsheng

Subjects

*PARALLEL robots, *CONTROL theory (Engineering), *INTERNAL auditing

Abstract

The paper proposes a novel method for the nonlinear redundantly actuated parallel robot based on force/position hybrid control structure. In order to solve the limitation of making a compromise for internal model controller, a two-DOF fractional order internal model control algorithm combining the internal model control principle and the fractional order theory is proposed for the position branch of the parallel robot redundantly actuated. This algorithm can realise the adjustment of the dynamic performance and anti-interference of 6PUS-UPU respectively. Aiming at the big force control error fractional order internal model, fuzzy control theory and the fractional order internal model controller are integrated into a new controller-fuzzy fractional order internal model(FFOIM) force control algorithm. Then Admas/Matlab simulation results demonstrate that the proposed algorithm can further reduce the driving force error of the system, and also retain the strong anti-interference of fractional order internal model controller. [ABSTRACT FROM AUTHOR]

Published

2019

3. Optimal control of non-minimum phase integrating processes with time delay using disturbance observer-based control scheme.

Author

Zhang, Wei, Wang, Yagang, Yin, Zhong, Wang, Yongxiong, and Zhang, Weidong

Subjects

*OPTIMAL control theory, *TIME delay systems, *COMPUTER simulation, *PID controllers, *CLOSED loop systems

Abstract

A systematical design method of optimal control for non-minimum phase integrating processes with time delay using disturbance observer-based (DOB) control scheme is presented. All stabilising controllers and the filter of DOBs for integrating plants are developed. Then the optimal set-point tracking controller and the optimal filter of DOB are systematically derived by minimising the H2 norm performance specifications. The proposed design method has three main advantages. First, the design procedure is systematical and simple. Specified weight functions are chosen for step inputs and inputs similar to steps. The designed set-point tracking controller and the filter of DOB are given in analytical forms. Second, the designed set-point tracking controller and the filter of the DOB are optimal. They are derived from minimising the performance indexes of set-point tracking and input load disturbance rejection (ILDR). Finally, the set-point tracking performance specification and ILDR specification can be quantitatively achieved by conveniently tuning the adjustable parameters. Numerical simulations are given to illustrate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

4. A robust and high-performance queue management controller for large round trip time networks.

Author

Khoshnevisan, Ladan and Salmasi, Farzad R.

Subjects

*QUEUEING networks, *TCP/IP, *DATA packeting, *PROCESS control systems, *TIME delay systems, *PROTOCOL analyzers

Abstract

Congestion management for transmission control protocol is of utmost importance to prevent packet loss within a network. This necessitates strategies for active queue management. The most applied active queue management strategies have their inherent disadvantages which lead to suboptimal performance and even instability in the case of large round trip time and/or external disturbance. This paper presents an internal model control robust queue management scheme with two degrees of freedom in order to restrict the undesired effects of large and small round trip time and parameter variations in the queue management. Conventional approaches such as proportional integral and random early detection procedures lead to unstable behaviour due to large delay. Moreover, internal model control-Smith scheme suffers from large oscillations due to the large round trip time. On the other hand, other schemes such as internal model control-proportional integral and derivative show excessive sluggish performance for small round trip time values. To overcome these shortcomings, we introduce a system entailing two individual controllers for queue management and disturbance rejection, simultaneously. Simulation results based on Matlab/Simulink and also Network Simulator 2 (NS2) demonstrate the effectiveness of the procedure and verify the analytical approach. [ABSTRACT FROM AUTHOR]

Published

2016