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Learning Responsibility Allocations for Safe Human-Robot Interaction with Applications to Autonomous Driving
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Learning Responsibility Allocations for Safe Human-Robot Interaction with Applications to Autonomous Driving
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Drivers have a responsibility to exercise reasonable care to avoid collision with other road users. This assumed responsibility allows interacting agents to maintain safety without explicit coordination. Thus to enable safe autonomous vehicle (AV) interactions, AVs must understand what their responsibilities are to maintain safety and how they affect the safety of nearby agents. In this work we seek to understand how responsibility is shared in multi-agent settings where an autonomous agent is interacting with human counterparts. We introduce Responsibility-Aware Control Barrier Functions (RA-CBFs) and present a method to learn responsibility allocations from data. By combining safety-critical control and learning-based techniques, RA-CBFs allow us to account for scene-dependent responsibility allocations and synthesize safe and efficient driving behaviors without making worst-case assumptions that typically result in overly-conservative behaviors. We test our framework using real-world driving data and demonstrate its efficacy as a tool for both safe control and forensic analysis of unsafe driving.
Forward citations
Cited by 2 Pith papers
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Control Barrier Function only Formation Tracking in Multi-Agent Systems
A single CBF-like constraint in quadratic optimization enables formation tracking for heterogeneous multi-agent systems using only relative neighbor information.
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Control Barrier Function only Formation Tracking in Multi-Agent Systems
A single-CBF quadratic-program controller for formation tracking in heterogeneous nonlinear multi-agent systems that requires no separate nominal controller or parameter tuning.
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