A Variable Power Surface Error Function backstepping based Dynamic Surface Control of Non-Lower Triangular Nonlinear Systems

TL;DR

This paper introduces a novel control method combining Variable Power Surface Error Function, backstepping, and dynamic surface control to improve tracking accuracy in complex nonlinear systems, ensuring stability and small steady-state errors.

Contribution

It proposes a new control design for non-lower triangular nonlinear systems using VPSEF and backstepping, with stability analysis and simulation validation.

Findings

Ensures semi-global stability of the closed-loop system.

Achieves arbitrarily small steady-state tracking error.

Validated effectiveness through two simulation cases.

Abstract

A control design for error reduction in the tracking control for a class of non-lower triangular nonlinear systems is presented by combining techniques of Variable Power Surface Error Function (VPSEF), backstepping, and dynamic surface control. At each step of design, a surface error is obtained, and based on its magnitude, the VPSEF technique decides the surface error to be used. Thus, the backstepping-based virtual and actual control law is designed to stabilize the corresponding subsystem. To address the issue of circular structure, a first-order low-pass filter is used to handle the virtual control signal at each intermediate stage of the recursive design. The stability analysis of the closed-loop system demonstrates that all signals indicate semi-global uniform ultimate boundedness. Moreover, by using the switching strategy of the control input using the VPSEF technique suitably, it is possible to ensure that the steady-state tracking error converges to a neighborhood of zero with an arbitrarily very small size. The effectiveness of the proposed concept has been verified using two different simulated demonstrations.