Awesome
Unscented Kalman Filtering on (Parallelizable) Manifolds
About
UKF-M, for Unscented Kalman Filtering on (parallelizable) Manifolds, is a novel methodology for implementing unscented Kalman filter both on manifold and Lie groups. Beyond filtering performances, the main interests of the approach are its versatility, as the method applies to numerous state estimation problems, and its simplicity of implementation for practitioners not being necessarily familiar with manifolds and Lie groups.
This repo contains two independent Python and Matlab implementations - we recommend Python - for quickly implementing and testing the approach. If you use this project for your research, please please cite:
@inproceedings{brossard2020Code,
author={Martin Brossard and Axel Barrau and Silvère Bonnabel},
title={{A Code for Unscented Kalman Filtering on Manifolds (UKF-M)}},
booktitle={2020 International Conference on Robotics and Automation (ICRA)},
year={2020},
organization={IEEE}
}
Documentation
The documentation is available at https://caor-mines-paristech.github.io/ukfm/.
The paper A Code for Unscented Kalman Filtering on Manifolds (UKF-M) related to this code is available at this url.
Download
The repo contains tutorials, documentation and that can be downloaded from https://github.com/CAOR-MINES-ParisTech/ukfm.
Getting Started
- Download the latest source code from GitHub (see Installation in the documentation).
- Follow the 2D robot localization for an introduction to the methodology.
Examples
Below is a list of examples from which the unscented Kalman filter on parallelizable manifolds has been implemented.
-
2D robot localization (for introduction on simulated data and on real data).
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3D Attitude estimation with an Inertial Measurement Unit (IMU) equipped with gyros, accelerometers and magnetometers.
-
3D inertial navigation on flat Earth with observations of known landmarks.
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2D Simultaneous Localization And Mapping (SLAM).
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IMU-GNSS sensor-fusion for a vehicle on the KITTI dataset.
-
Spherical pendulum example, where the state lives on the 2-sphere manifold.
Support
Please, use the GitHub issue tracker for questions, bug reports, feature requests/additions, etc.
Acknowledgments
The library was written by Martin Brossard^, Axel Barrau^ and Silvère Bonnabel^.
^MINES ParisTech, PSL Research University, Centre for Robotics, 60 Boulevard Saint-Michel, 75006 Paris, France.