VOCALoco: Viability-Optimized Cost-aware Adaptive Locomotion
Abstract
Recent advancements in legged robot locomotion have facilitated traversal over increasingly complex terrains. Despite this progress, many existing approaches rely on end-to-end deep reinforcement learning (DRL), which poses limitations in terms of safety and interpretability, especially when generalizing to novel terrains. To overcome these challenges, we introduce VOCALoco, a modular skill-selection framework that dynamically adapts locomotion strategies based on perceptual input. Given a set of pre-trained locomotion policies, VOCALoco evaluates their viability and energy-consumption by predicting both the safety of execution and the anticipated cost of transport over a fixed planning horizon. This joint assessment enables the selection of policies that are both safe and energy-efficient, given the observed local terrain. We evaluate our approach on staircase locomotion tasks, demonstrating its performance in both simulated and real-world scenarios using a quadrupedal robot. Empirical results show that VOCALoco achieves improved robustness and safety during stair ascent and descent compared to a conventional end-to-end DRL policy
Cite
@article{arxiv.2510.23997,
title = {VOCALoco: Viability-Optimized Cost-aware Adaptive Locomotion},
author = {Stanley Wu and Mohamad H. Danesh and Simon Li and Hanna Yurchyk and Amin Abyaneh and Anas El Houssaini and David Meger and Hsiu-Chin Lin},
journal= {arXiv preprint arXiv:2510.23997},
year = {2025}
}
Comments
Accepted in IEEE Robotics and Automation Letters (RAL), 2025. 8 pages, 9 figures