Discrete-Time Fractional-Order PID Controller: Definition, Tuning, Digital Realization and Experimental Results

TL;DR

This paper introduces a discrete-time fractional-order PID controller that applies nonlocal operators directly in digital form, addressing discretization errors and enhancing control performance in complex systems.

Contribution

It proposes a novel discrete-time FOPID controller with tunable parameters and discusses its properties, offering an alternative to traditional discretization methods.

Findings

The proposed controller effectively handles complex control problems.

Two tuning methods are developed for the new controller.

Experimental results demonstrate high performance in practical applications.

Abstract

In some of the complicated control problems we have to use the controllers that apply nonlocal operators to the error signal to generate the control. Currently, the most famous controller with nonlocal operators is the fractional-order PID (FOPID). Commonly, after tuning the parameters of FOPID controller, its transfer function is discretized (for realization purposes) using the so-called generating function. This discretization is the origin of some errors and unexpected results in feedback systems. It may even happen that the controller obtained by discretizing a FOPID controller works worse than a directly-tuned discrete-time classical PID controller. Moreover, FOPID controllers cannot directly be applied to the processes modeled by, e.g., the ARMA or ARMAX model. The aim of this paper is to propose a discrete-time version of the FOPID controller and discuss on its properties and applications. Similar to the FOPID controller, the proposed structure applies nonlocal operators (with adjustable memory length) to the error signal. Two methods for tuning the parameters of the proposed controller are developed and it is shown that the proposed controller has the capacity of solving complicated control problems with a high performance.