@article{d7c1e9562f39418ba45b4b482989821c,
title = "Position-Dependent Motion Feedforward via Gaussian Processes: Applied to Snap and Force Ripple in Semiconductor Equipment",
abstract = "The requirements for high accuracy and throughput in next-generation data-intensive motion systems lead to situations where position-dependent feedforward is essential. This article aims to develop a framework for interpretable and task-flexible position-dependent feedforward through systematic learning with automated experimental design. A data-driven and interpretable framework is developed by employing Gaussian process (GP) regression, enabling accurate modeling of feedforward parameters as a continuous function of position. The data is efficiently collected and illustrated through an iterative learning control (ILC) algorithm. Moreover, a framework for experimental design in the sense of automatically determining the training positions is presented by exploiting the uncertainty estimates of the GP and the specified first-principles knowledge. Two relevant case studies show the importance and significant performance improvement of the approach for position-dependent snap feedforward for a simplified 1-D wafer stage simulation and experimental application to position-dependent motor force constant compensation in an industrial wirebonder.",
keywords = "Actuators, Dynamics, Feedforward systems, Force, Gaussian processes (GPs), Systematics, Task analysis, Wires, iterative learning control (ILC), mutual information",
author = "M.M. Poot and {van Haren}, Max and Dragan Kostic and Portegies, {Jacobus W.} and Oomen, {Tom A.E.}",
year = "2024",
doi = "10.1109/TCST.2024.3385632",
language = "English",
volume = "XX",
journal = "IEEE Transactions on Control Systems Technology",
issn = "1063-6536",
publisher = "Institute of Electrical and Electronics Engineers",
number = "X",
}