Necessary and Sufficient Conditions for PID Design of MIMO Nonlinear Systems

TL;DR

This paper develops explicit, closed-form conditions for designing PID controllers that guarantee stability and tracking in uncertain nonlinear MIMO systems, providing both sufficient and necessary gain regions.

Contribution

It introduces a rigorous, explicit PID gain design framework for nonlinear uncertain MIMO systems with Jacobian bounds, including necessary and sufficient conditions.

Findings

Explicit gain regions depend only on Jacobian bounds and input gain

Sufficient and necessary regions coincide under certain structural assumptions

Closed-form regions enable practical PID tuning for complex systems

Abstract

As is well known, classical PID control is ubiquitous in industrial processes, yet a rigorous and explicit design theory for nonlinear uncertain MIMO second-order systems remains underdeveloped. In this paper we consider a class of such systems with both uncertain dynamics and an unknown but strictly positive input gain, where the nonlinear uncertainty is characterized by bounds on the Jacobian with respect to the state variables. We explicitly construct a three-dimensional region for the PID gains that is sufficient to guarantee global stability and asymptotic tracking of constant references for all nonlinearities satisfying these Jacobian bounds. We then derive a corresponding necessary region, thereby revealing the inherent conservatism required to cope with worst-case uncertainties. Moreover, under additional structural assumptions on the nonlinearities, these sufficient and necessary regions coincide, yielding a precise necessary-and-sufficient characterization of all globally stabilizing PID gains. All these regions are given in closed form and depend only on the prescribed Jacobian bounds and the known lower bound of the input gain, in contrast to many qualitative tuning methods in the literature.