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Proprioceptive State Estimation for Quadruped Robots using Invariant Kalman Filtering and Scale-Variant Robust Cost Functions | IEEE Conference Publication | IEEE Xplore
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Proprioceptive State Estimation for Quadruped Robots using Invariant Kalman Filtering and Scale-Variant Robust Cost Functions

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Hilton Marques Souza Santana; João Carlos Virgolino Soares; Ylenia Nisticò; Marco Antonio Meggiolaro; Claudio Semini
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Abstract:

Accurate state estimation is crucial for legged robot locomotion, as it provides the necessary information to allow control and navigation. However, it is also challengin...Show More

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Abstract:

Accurate state estimation is crucial for legged robot locomotion, as it provides the necessary information to allow control and navigation. However, it is also challenging, especially in scenarios with uneven and slippery terrain. This paper presents a new Invariant Extended Kalman filter for legged robot state estimation using only proprioceptive sensors. We formulate the methodology by combining recent advances in state estimation theory with the use of robust cost functions in the measurement update. We tested our methodology on quadruped robots through experiments and public datasets, showing that we can obtain a pose drift up to 40% lower in trajectories covering a distance of over 450 m, in comparison with a state-of-the-art Invariant Extended Kalman filter.
Published in: 2024 IEEE-RAS 23rd International Conference on Humanoid Robots (Humanoids)
Date of Conference: 22-24 November 2024
Date Added to IEEE Xplore: 03 December 2024
ISBN Information:

ISSN Information:

DOI: 10.1109/Humanoids58906.2024.10769911
Conference Location: Nancy, France

Description

The video briefly describes the Invariant Extended Kalman Filter (IEKF) formulation, including the prediction and measurement models.It also includes a Monte Carlo simulation of the prediction step, which highlights the IEKF's main feature.In addition, the methodology for dealing with contact slippage using robust cost functions is described. Finally, it shows an experiment with the robot AlienGo walking on challenging terrain.
Review our Supplemental Items documentation for more information.
Contents

I. Introduction

Quadruped robots are becoming increasingly capable, with recent advancements enabling them to perform complex tasks in unstructured environments. State estimation is a crucial step for these robots to achieve autonomy. Quadruped robots require accurate pose and velocity estimation to feed the controllers, ensure stability, and perform navigation. However, accurate state estimation is challenging due to sensor noise and external disturbances.

Description

The video briefly describes the Invariant Extended Kalman Filter (IEKF) formulation, including the prediction and measurement models.It also includes a Monte Carlo simulation of the prediction step, which highlights the IEKF's main feature.In addition, the methodology for dealing with contact slippage using robust cost functions is described. Finally, it shows an experiment with the robot AlienGo walking on challenging terrain.
Review our Supplemental Items documentation for more information.
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