Litcius/Paper detail

Data-Driven Feedforward Learning With Force Ripple Compensation for Wafer Stages: A Variable-Gain Robust Approach

Fazhi Song, Yang Liu, Wen Jin, Jiubin Tan, Wei He

2020IEEE Transactions on Neural Networks and Learning Systems49 citationsDOI

Abstract

To meet the increasing demand for denser integrated circuits, feedforward control plays an important role in the achievement of high servo performance of wafer stages. The preexisting feedforward control methods, however, are subject to either inflexibility to reference variations or poor robustness. In this article, these deficiencies are removed by a novel variable-gain iterative feedforward tuning (VGIFFT) method. The proposed VGIFFT method attains: 1) no involvement of any parametric model through data-driven estimation; 2) high performance regardless of reference variations through feedforward parameterization; and 3) especially high robustness against stochastic disturbance as well as against model uncertainty through a variable learning gain. What is more, the tradeoff in which preexisting methods are subject to between fast convergence and high robustness is broken through by VGIFFT. Experimental results validate the proposed method and confirm its effectiveness and enhanced performance.

Topics & Concepts

Feed forwardRobustness (evolution)Control theory (sociology)Computer scienceParametric statisticsRippleControl engineeringEngineeringControl (management)MathematicsArtificial intelligenceStatisticsVoltageGeneChemistryBiochemistryElectrical engineeringIterative Learning Control SystemsPiezoelectric Actuators and ControlAdvanced Measurement and Metrology Techniques