Black-Box vs. Gray-Box: A Case Study on Learning Table Tennis Ball Trajectory Prediction with Spin and Impacts

Jan Achterhold; Philip Tobuschat; Hao Ma; Dieter Büchler; Michael Muehlebach; Joerg Stueckler

2023 L4DC L4DC 2023

Black-Box vs. Gray-Box: A Case Study on Learning Table Tennis Ball Trajectory Prediction with Spin and Impacts

Abstract

In this paper, we present a method for table tennis ball trajectory filtering and prediction. Our gray-box approach builds on a physical model. At the same time, we use data to learn parameters of the dynamics model, of an extended Kalman filter, and of a neural model that infers the ball’s initial condition. We demonstrate superior prediction performance of our approach over two black-box approaches, which are not supplied with physical prior knowledge. We demonstrate that initializing the spin from parameters of the ball launcher using a neural network drastically improves long-time prediction performance over estimating the spin purely from measured ball positions. An accurate prediction of the ball trajectory is crucial for successful returns. We therefore evaluate the return performance with a pneumatic artificial muscular robot and achieve a return rate of 29/30 (97.7%).

🌉 Interdisciplinary Bridge — Artificial Intelligence and Deep Learning and Machine Learning

🧭 Keyword Pioneer — spin prediction

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Jan Achterhold , Philip Tobuschat , Hao Ma , Dieter Büchler , Michael Muehlebach , Joerg Stueckler

Topics

Artificial Intelligence > Core AI > Trajectory Prediction Machine Learning > Optimization & Theory > Optimization Deep Learning > Architectures > Neural Networks

Keywords

trajectory prediction extended kalman filter neural network physical model spin prediction

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