Learning responsibility allocations for multi-agent interactions: A differentiable optimization approach with control barrier functions
Abstract
From autonomous driving to package delivery, ensuring safe yet efficient multi-agent interaction is challenging as the interaction dynamics are influenced by hard-to-model factors such as social norms and contextual cues. Understanding these influences can aid in the design and evaluation of socially-aware autonomous agents whose behaviors are aligned with human values. In this work, we seek to codify factors governing safe multi-agent interactions via the lens of responsibility, i.e., an agent's willingness to deviate from their desired control to accommodate safe interaction with others. Specifically, we propose a data-driven modeling approach based on control barrier functions and differentiable optimization that efficiently learns agents' responsibility allocation from data. We demonstrate on synthetic and real-world datasets that we can obtain an interpretable and quantitative understanding of how much agents adjust their behavior to ensure the safety of others given their current environment.
Cite
@article{arxiv.2410.07409,
title = {Learning responsibility allocations for multi-agent interactions: A differentiable optimization approach with control barrier functions},
author = {Isaac Remy and David Fridovich-Keil and Karen Leung},
journal= {arXiv preprint arXiv:2410.07409},
year = {2026}
}
Comments
8 pages, 7 figures