SafeMind: A Risk-Aware Differentiable Control Framework for Adaptive and Safe Quadruped Locomotion
Zukun Zhang, Kai Shu, Mingqiao Mo
TLDR
SafeMind is a risk-aware differentiable control framework that enhances quadruped safety and efficiency by unifying probabilistic CBFs with adaptive risk calibration.
Key contributions
- Introduces SafeMind, a differentiable stochastic safety-control framework for quadruped robots.
- Integrates probabilistic Control Barrier Functions with semantic context and meta-adaptive risk calibration.
- Models uncertainty via a variance-aware barrier constraint in a differentiable quadratic program.
- Achieves 3-10x fewer safety violations and 10-15% less energy use compared to SOTA methods.
Why it matters
This paper addresses a critical gap in robotic control by providing formal safety guarantees for agile quadruped locomotion under real-world uncertainties. SafeMind's novel integration of probabilistic safety and adaptive risk calibration significantly improves robot reliability and efficiency, crucial for deploying autonomous robots in complex, unpredictable environments.
Original Abstract
Learning-based quadruped controllers achieve impressive agility but typically lack formal safety guarantees under model uncertainty, perception noise, and unstructured contact conditions. We introduce SafeMind, a differentiable stochastic safety-control framework that unifies probabilistic Control Barrier Functions with semantic context understanding and meta-adaptive risk calibration. SafeMind explicitly models epistemic and aleatoric uncertainty through a variance-aware barrier constraint embedded in a differentiable quadratic program, thereby preserving gradient flow for end-to-end training. A semantics-to-constraint encoder modulates safety margins using perceptual or language cues, while a meta-adaptive learner continuously adjusts risk sensitivity across environments. We provide theoretical conditions for probabilistic forward invariance, feasibility, and stability under stochastic dynamics. SafeMind is deployed on Unitree A1 and ANYmal C at 200~Hz and validated across 12 terrain types, dynamic obstacles, morphology perturbations, and semantically defined tasks. Experiments show that SafeMind reduces safety violations by 3--10x and energy consumption by 10--15% relative to state-of-the-art CBF, MPC, and hybrid RL baselines, while maintaining real-time control performance.
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