Proprioceptive-only State Estimation for Legged Robots with Set-Coverage Measurements of Learned Dynamics
This addresses the challenge of reliable state estimation for legged robots in perceptually degraded conditions, representing an incremental improvement over existing methods.
The paper tackled the problem of inconsistent and potentially divergent state estimation in legged robots under limited training data by proposing a proprioceptive-only framework that uses set-coverage measurements instead of Gaussian noise assumptions, showing that it remains consistent and drift-free in simulations and real-world datasets compared to baselines.
Proprioceptive-only state estimation is attractive for legged robots since it is computationally cheaper and is unaffected by perceptually degraded conditions. The history of joint-level measurements contains rich information that can be used to infer the dynamics of the system and subsequently produce navigational measurements. Recent approaches produce these estimates with learned measurement models and fuse with IMU data, under a Gaussian noise assumption. However, this assumption can easily break down with limited training data and render the estimates inconsistent and potentially divergent. In this work, we propose a proprioceptive-only state estimation framework for legged robots that characterizes the measurement noise using set-coverage statements that do not assume any distribution. We develop a practical and computationally inexpensive method to use these set-coverage measurements with a Gaussian filter in a systematic way. We validate the approach in both simulation and two real-world quadrupedal datasets. Comparison with the Gaussian baselines shows that our proposed method remains consistent and is not prone to drift under real noise scenarios.