Enhanced Contour Tracking: a Time-Varying Internal Model Principle-Based Approach

TL;DR

This paper introduces a novel control method based on the time-varying internal model principle to significantly improve multi-axis contour tracking accuracy and robustness in motion control systems.

Contribution

It proposes a new TV-IMCC approach that decouples multi-axis contouring into two-axis problems and handles time-varying dynamics, with proven stability and enhanced performance.

Findings

Enhanced contour tracking accuracy demonstrated in simulations and experiments.

The method effectively reduces axial and contour errors.

No strict master axis precision required, suitable for macro-micro systems.

Abstract

Contour tracking plays a crucial role in multi-axis motion control systems, and it requires both multi-axial contouring as well as standard servo performance in each axis. Among the existing contouring control methods, the cross coupled control (CCC) lacks of an asymptotical tracking performance for general contours, and the task coordinate frame (TCF) control usually leads to system nonlinearity, and by design is not well-suited for multi-axis contour tracking. Here we propose a novel time-varying internal model principle-based contouring control (TV-IMCC) methodology to enhance contour tracking performance with both axial and contour error reduction. The proposed TV-IMCC is twofold, including an extended position domain framework with master-slave structures for contour regulation, and a time-varying internal model principle-based controller for each axial tracking precision improvement. Specifically, a novel signal conversion algorithm is proposed with the extended position domain framework, hence the original n-axis contouring problem can be decoupled into (n-1) two-axis master-slave tracking problems in the position domain, and the class of contour candidates can be extended as well. With this, the time-varying internal model principle-based control method is proposed to deal with the time-varying dynamics in the axial systems resulted from the transformation between the time and position domains. Furthermore, the stability analysis is provided for the closed-loop system of the TV-IMCC. Various simulation and experimental results validate the TV-IMCC with enhanced contour tracking performance compared with the existing methods. Moreover, there is no strict requirement on the precision of the master axis, therefore a potential application of the TV-IMCC is multi-axis macro-micro motion systems.