On-board spacecraft relative pose estimation with high-order extended Kalman filter
On-board spacecraft relative pose estimation with high-order extended Kalman filter
This paper analyzes the real-time relative pose estimation and attitude prediction of a tumbling target spacecraft through a high-order numerical extended Kalman filter based on differential algebra. Indeed, in the differential algebra framework, the Taylor expansion of the phase flow is automatically available once the spacecraft dynamics is integrated and thus the need to write and integrate high-order variational equations is completely avoided making the presented solution easier to implement. To validate the technique, the ESA’s e.deorbit mission, involving the Envisat satellite, is used as reference test case. The developed algorithms are implemented on a BeagleBone Black platform, as representative of the limited computational capability available on onboard
processors. The performance is assessed by varying the measurement acquisition frequency and processor clock frequency, and considering various levels of uncertainties.
A comparison among the different orders of the filter is carried out.
Cavenago, Francesco
7555ca1e-a11f-4b43-9a3c-7d90116d4be2
Lizia, Pierluigi
8a0d7c21-8869-498e-95c8-41a8c8a6dd1a
Massari, Mauro
6b6f72d2-7e3a-4394-87c3-9fb0e51b75ec
Wittig, Alexander
3a140128-b118-4b8c-9856-a0d4f390b201
Cavenago, Francesco
7555ca1e-a11f-4b43-9a3c-7d90116d4be2
Lizia, Pierluigi
8a0d7c21-8869-498e-95c8-41a8c8a6dd1a
Massari, Mauro
6b6f72d2-7e3a-4394-87c3-9fb0e51b75ec
Wittig, Alexander
3a140128-b118-4b8c-9856-a0d4f390b201
Cavenago, Francesco, Lizia, Pierluigi, Massari, Mauro and Wittig, Alexander
(2018)
On-board spacecraft relative pose estimation with high-order extended Kalman filter.
Acta Astronautica.
(doi:10.1016/j.actaastro.2018.11.020).
Abstract
This paper analyzes the real-time relative pose estimation and attitude prediction of a tumbling target spacecraft through a high-order numerical extended Kalman filter based on differential algebra. Indeed, in the differential algebra framework, the Taylor expansion of the phase flow is automatically available once the spacecraft dynamics is integrated and thus the need to write and integrate high-order variational equations is completely avoided making the presented solution easier to implement. To validate the technique, the ESA’s e.deorbit mission, involving the Envisat satellite, is used as reference test case. The developed algorithms are implemented on a BeagleBone Black platform, as representative of the limited computational capability available on onboard
processors. The performance is assessed by varying the measurement acquisition frequency and processor clock frequency, and considering various levels of uncertainties.
A comparison among the different orders of the filter is carried out.
Text
Onboard_spacecraft_relative_pose_estimation_with_high_order_extended
- Accepted Manuscript
More information
Accepted/In Press date: 15 November 2018
e-pub ahead of print date: 20 November 2018
Identifiers
Local EPrints ID: 426433
URI: http://eprints.soton.ac.uk/id/eprint/426433
ISSN: 0094-5765
PURE UUID: b62b5818-0eda-4b05-9a6c-d83da598ae91
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Date deposited: 27 Nov 2018 17:30
Last modified: 16 Mar 2024 07:19
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Contributors
Author:
Francesco Cavenago
Author:
Pierluigi Lizia
Author:
Mauro Massari
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