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Main Authors: Vogt, Moritz D. Pinheiro-Torres, Huwald, Markus, Ben-Larbi, M. Khalil, Stoll, Enrico
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.03034
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author Vogt, Moritz D. Pinheiro-Torres
Huwald, Markus
Ben-Larbi, M. Khalil
Stoll, Enrico
author_facet Vogt, Moritz D. Pinheiro-Torres
Huwald, Markus
Ben-Larbi, M. Khalil
Stoll, Enrico
contents The estimation of relative motion between spacecraft increasingly relies on feature-matching computer vision, which feeds data into a recursive filtering algorithm. Kalman filters, although efficient in noise compensation, demand extensive tuning of system and noise models. This paper introduces FlexKalmanNet, a novel modular framework that bridges this gap by integrating a deep fully connected neural network with Kalman filter-based motion estimation algorithms. FlexKalmanNet's core innovation is its ability to learn any Kalman filter parameter directly from measurement data, coupled with the flexibility to utilize various Kalman filter variants. This is achieved through a notable design decision to outsource the sequential computation from the neural network to the Kalman filter variant, enabling a purely feedforward neural network architecture. This architecture, proficient at handling complex, nonlinear features without the dependency on recurrent network modules, captures global data patterns more effectively. Empirical evaluation using data from NASA's Astrobee simulation environment focuses on learning unknown parameters of an Extended Kalman filter for spacecraft pose and twist estimation. The results demonstrate FlexKalmanNet's rapid training convergence, high accuracy, and superior performance against manually tuned Extended Kalman filters.
format Preprint
id arxiv_https___arxiv_org_abs_2405_03034
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle FlexKalmanNet: A Modular AI-Enhanced Kalman Filter Framework Applied to Spacecraft Motion Estimation
Vogt, Moritz D. Pinheiro-Torres
Huwald, Markus
Ben-Larbi, M. Khalil
Stoll, Enrico
Robotics
Earth and Planetary Astrophysics
The estimation of relative motion between spacecraft increasingly relies on feature-matching computer vision, which feeds data into a recursive filtering algorithm. Kalman filters, although efficient in noise compensation, demand extensive tuning of system and noise models. This paper introduces FlexKalmanNet, a novel modular framework that bridges this gap by integrating a deep fully connected neural network with Kalman filter-based motion estimation algorithms. FlexKalmanNet's core innovation is its ability to learn any Kalman filter parameter directly from measurement data, coupled with the flexibility to utilize various Kalman filter variants. This is achieved through a notable design decision to outsource the sequential computation from the neural network to the Kalman filter variant, enabling a purely feedforward neural network architecture. This architecture, proficient at handling complex, nonlinear features without the dependency on recurrent network modules, captures global data patterns more effectively. Empirical evaluation using data from NASA's Astrobee simulation environment focuses on learning unknown parameters of an Extended Kalman filter for spacecraft pose and twist estimation. The results demonstrate FlexKalmanNet's rapid training convergence, high accuracy, and superior performance against manually tuned Extended Kalman filters.
title FlexKalmanNet: A Modular AI-Enhanced Kalman Filter Framework Applied to Spacecraft Motion Estimation
topic Robotics
Earth and Planetary Astrophysics
url https://arxiv.org/abs/2405.03034