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Auteurs principaux: Payne, J. Joe, Zhu, James, Kong, Nathan J., Johnson, Aaron M.
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2410.19958
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author Payne, J. Joe
Zhu, James
Kong, Nathan J.
Johnson, Aaron M.
author_facet Payne, J. Joe
Zhu, James
Kong, Nathan J.
Johnson, Aaron M.
contents In this paper we present Hybrid iterative Linear Quadratic Estimation (HiLQE), an optimization based offline state estimation algorithm for hybrid dynamical systems. We utilize the saltation matrix, a first order approximation of the variational update through an event driven hybrid transition, to calculate gradient information through hybrid events in the backward pass of an iterative linear quadratic optimization over state estimates. This enables accurate computation of the value function approximation at each timestep. Additionally, the forward pass in the iterative algorithm is augmented with hybrid dynamics in the rollout. A reference extension method is used to account for varying impact times when comparing states for the feedback gain in noise calculation. The proposed method is demonstrated on an ASLIP hopper system with position measurements. In comparison to the Salted Kalman Filter (SKF), the algorithm presented here achieves a maximum of 63.55% reduction in estimation error magnitude over all state dimensions near impact events.
format Preprint
id arxiv_https___arxiv_org_abs_2410_19958
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hybrid Iterative Linear Quadratic Estimation: Optimal Estimation for Hybrid Systems
Payne, J. Joe
Zhu, James
Kong, Nathan J.
Johnson, Aaron M.
Robotics
In this paper we present Hybrid iterative Linear Quadratic Estimation (HiLQE), an optimization based offline state estimation algorithm for hybrid dynamical systems. We utilize the saltation matrix, a first order approximation of the variational update through an event driven hybrid transition, to calculate gradient information through hybrid events in the backward pass of an iterative linear quadratic optimization over state estimates. This enables accurate computation of the value function approximation at each timestep. Additionally, the forward pass in the iterative algorithm is augmented with hybrid dynamics in the rollout. A reference extension method is used to account for varying impact times when comparing states for the feedback gain in noise calculation. The proposed method is demonstrated on an ASLIP hopper system with position measurements. In comparison to the Salted Kalman Filter (SKF), the algorithm presented here achieves a maximum of 63.55% reduction in estimation error magnitude over all state dimensions near impact events.
title Hybrid Iterative Linear Quadratic Estimation: Optimal Estimation for Hybrid Systems
topic Robotics
url https://arxiv.org/abs/2410.19958