Quadruped robots are currently a widespread platform for robotics research, thanks to powerful Reinforcement Learning controllers and the availability of cheap and robust commercial platforms. However, to broaden the adoption of the technology in the real world, we require robust navigation stacks relying only on low-cost sensors such as depth cameras. This paper presents a first step towards a robust localization, mapping, and navigation system for low-cost quadruped robots. In pursuit of this objective, we combine contact-aided kinematic, visual-inertial odometry, and depth-stabilized vision, enhancing the system’s stability and accuracy. Our results in simulation and two different real-world quadruped platforms show that our system can generate an accurate 2D map of the environment, robustly localize itself, and navigate autonomously. Furthermore, we present in-depth ablation studies of the system’s key components and their impact on localization accuracy. Videos, code, and additional experiments can be found on the project website.
Robust Localization, Mapping, and Navigation for Quadruped Robots / D. Aditya, J. Huang, N. Bohlinger, P. Kicki, K. Walas, J. Peters, M. Luperto, D. Tateo (EUROPEAN CONFERENCE ON MOBILE ROBOTS CONFERENCE PROCEEDINGS). - In: 2025 European Conference on Mobile Robots (ECMR)[s.l] : IEEE, 2025 Sep. - ISBN 979-8-3315-2705-1. - pp. 1-8 (( convegno European Conference on Mobile Robots (ECMR) tenutosi a Pavoda nel 2025 [10.1109/ecmr65884.2025.11163249].
Robust Localization, Mapping, and Navigation for Quadruped Robots
M. LupertoCo-ultimo
;
2025
Abstract
Quadruped robots are currently a widespread platform for robotics research, thanks to powerful Reinforcement Learning controllers and the availability of cheap and robust commercial platforms. However, to broaden the adoption of the technology in the real world, we require robust navigation stacks relying only on low-cost sensors such as depth cameras. This paper presents a first step towards a robust localization, mapping, and navigation system for low-cost quadruped robots. In pursuit of this objective, we combine contact-aided kinematic, visual-inertial odometry, and depth-stabilized vision, enhancing the system’s stability and accuracy. Our results in simulation and two different real-world quadruped platforms show that our system can generate an accurate 2D map of the environment, robustly localize itself, and navigate autonomously. Furthermore, we present in-depth ablation studies of the system’s key components and their impact on localization accuracy. Videos, code, and additional experiments can be found on the project website.
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