Energy-based Potential Games for Joint Motion Forecasting and Control
Abstract
This work uses game theory as a mathematical framework to address interaction modeling in multi-agent motion forecasting and control. Despite its interpretability, applying game theory to real-world robotics, like automated driving, faces challenges such as unknown game parameters. To tackle these, we establish a connection between differential games, optimal control, and energy-based models, demonstrating how existing approaches can be unified under our proposed Energy-based Potential Game formulation. Building upon this, we introduce a new end-to-end learning application that combines neural networks for game-parameter inference with a differentiable game-theoretic optimization layer, acting as an inductive bias. The analysis provides empirical evidence that the game-theoretic layer adds interpretability and improves the predictive performance of various neural network backbones using two simulations and two real-world driving datasets.
Cite
@article{arxiv.2312.01811,
title = {Energy-based Potential Games for Joint Motion Forecasting and Control},
author = {Christopher Diehl and Tobias Klosek and Martin Krüger and Nils Murzyn and Timo Osterburg and Torsten Bertram},
journal= {arXiv preprint arXiv:2312.01811},
year = {2023}
}
Comments
Conference on Robot Learning, CoRL 2023