Mission ORCA: Orbit Refinement for Collision Avoidance

With new launches every year, and the use of 'mega-constellations' becoming commonplace, there is an increasing number of active satellites and other resident space objects (RSOs) in low Earth orbit. However, a collision between objects could be disastrous, having wide-ranging impacts on t...

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Main Authors: Barles, Anaïs, Bilkhu, Satnam, Boulnois, Anthony, Cuesta Arijaa, Francisco Javier, Duarri Albacete, Guillem, Easdown, William, Estalella Silvela, Alvaro, Gallego Fernández, Ramiro, Kent, Ben, Martínez Mariscal, Javier, Martinez Mata, Alfonso, Pradeep, Shilpa, Sinclair, Giovanni, Stephens-Simonazzi, Benedict, Yan, Wenhan, Felicetti, Leonard
Format: Conference Object
Language:English
Published: iafastro 2020
Subjects:
Constellation Design
CubeSat Design
Space Situational Awareness
Resident Space Objects Tracking
Space Debris Surveillance
Orca
Online Access:https://dspace.lib.cranfield.ac.uk/handle/1826/15958
https://iafastro.directory/iac/paper/id/61448/abstract-pdf/IAC-20,E2,3-GTS.4,12,x61448.brief.pdf?2020-07-07.17:00:02
id ftcranfield:oai:dspace.lib.cranfield.ac.uk:1826/15958
record_format openpolar
spelling ftcranfield:oai:dspace.lib.cranfield.ac.uk:1826/15958 2023-05-15T17:54:03+02:00 Mission ORCA: Orbit Refinement for Collision Avoidance Barles, Anaïs Bilkhu, Satnam Boulnois, Anthony Cuesta Arijaa, Francisco Javier Duarri Albacete, Guillem Easdown, William Estalella Silvela, Alvaro Gallego Fernández, Ramiro Kent, Ben Martínez Mariscal, Javier Martinez Mata, Alfonso Pradeep, Shilpa Sinclair, Giovanni Stephens-Simonazzi, Benedict Yan, Wenhan Felicetti, Leonard 2020-10-14 https://dspace.lib.cranfield.ac.uk/handle/1826/15958 https://iafastro.directory/iac/paper/id/61448/abstract-pdf/IAC-20,E2,3-GTS.4,12,x61448.brief.pdf?2020-07-07.17:00:02 en eng iafastro Barles A, Bilkhu S, Boulnois A, et al., (2020) Mission ORCA: Orbit Refinement for Collision Avoidance. In: 71st International Astronautical Congress - the Cyberspace Edition, 12-14 October 2020, Online https://dspace.lib.cranfield.ac.uk/handle/1826/15958 https://iafastro.directory/iac/paper/id/61448/abstract-pdf/IAC-20,E2,3-GTS.4,12,x61448.brief.pdf?2020-07-07.17:00:02 Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/ CC-BY Constellation Design CubeSat Design Space Situational Awareness Resident Space Objects Tracking Space Debris Surveillance Conference paper 2020 ftcranfield 2022-01-09T06:51:06Z With new launches every year, and the use of 'mega-constellations' becoming commonplace, there is an increasing number of active satellites and other resident space objects (RSOs) in low Earth orbit. However, a collision between objects could be disastrous, having wide-ranging impacts on the collision orbit and all the satellites users within it. Collision forecasting currently has large degrees of uncertainty, causing satellite operators to often ignore collision warnings. It is therefore critical that a system becomes operational to track RSOs and determine the likelihood of collisions with greater accuracy than is currently available. The proposed solution uses a constellation of 28 spacecraft (plus in-orbit spares) in Sun Synchronous Orbits. CubeSats will be used to reduce the cost and the time required for the constellation to become operational. Each satellite uses an optical payload to track target RSOs, with the satellite's position precisely determined. Multiple pictures of the RSO are taken, and the spacecraft attitude used to calculate the target's position relative to the spacecraft. The target's orbit is then determined from the movement of the target through the field of view over time. The system outputs orbit state vectors of the tracked object, allowing precise orbit characterisation and collision forecasting to be delivered. The constellation's design allows high temporal resolution, so reliable information can be supplied to end-users. The paper shows the results of the system design of a demonstration mission meant to verify the feasibility of the concept, performed by a team of students of Cranfield University. The exercise addresses all the aspects of the preliminary design, including the definition of the mission and system requirements, the selection of the overall mission architecture, operations, and mission phases. A cap on the overall cost allows for the realisation of the platform within a university budget. The outline of the design includes not only the selection and sizing of all the subsystems and payload but also suggests a new strategy for deploying the constellation if the demonstration mission is successful. The utilisation of high TRL and COTS components, as well as mass, power, and link budgets, demonstrate the feasibility of the overall mission concept Conference Object Orca Cranfield University: Collection of E-Research - CERES
institution Open Polar
collection Cranfield University: Collection of E-Research - CERES
op_collection_id ftcranfield
language English
topic Constellation Design
CubeSat Design
Space Situational Awareness
Resident Space Objects Tracking
Space Debris Surveillance
spellingShingle Constellation Design
CubeSat Design
Space Situational Awareness
Resident Space Objects Tracking
Space Debris Surveillance
Barles, Anaïs
Bilkhu, Satnam
Boulnois, Anthony
Cuesta Arijaa, Francisco Javier
Duarri Albacete, Guillem
Easdown, William
Estalella Silvela, Alvaro
Gallego Fernández, Ramiro
Kent, Ben
Martínez Mariscal, Javier
Martinez Mata, Alfonso
Pradeep, Shilpa
Sinclair, Giovanni
Stephens-Simonazzi, Benedict
Yan, Wenhan
Felicetti, Leonard
Mission ORCA: Orbit Refinement for Collision Avoidance
topic_facet Constellation Design
CubeSat Design
Space Situational Awareness
Resident Space Objects Tracking
Space Debris Surveillance
description With new launches every year, and the use of 'mega-constellations' becoming commonplace, there is an increasing number of active satellites and other resident space objects (RSOs) in low Earth orbit. However, a collision between objects could be disastrous, having wide-ranging impacts on the collision orbit and all the satellites users within it. Collision forecasting currently has large degrees of uncertainty, causing satellite operators to often ignore collision warnings. It is therefore critical that a system becomes operational to track RSOs and determine the likelihood of collisions with greater accuracy than is currently available. The proposed solution uses a constellation of 28 spacecraft (plus in-orbit spares) in Sun Synchronous Orbits. CubeSats will be used to reduce the cost and the time required for the constellation to become operational. Each satellite uses an optical payload to track target RSOs, with the satellite's position precisely determined. Multiple pictures of the RSO are taken, and the spacecraft attitude used to calculate the target's position relative to the spacecraft. The target's orbit is then determined from the movement of the target through the field of view over time. The system outputs orbit state vectors of the tracked object, allowing precise orbit characterisation and collision forecasting to be delivered. The constellation's design allows high temporal resolution, so reliable information can be supplied to end-users. The paper shows the results of the system design of a demonstration mission meant to verify the feasibility of the concept, performed by a team of students of Cranfield University. The exercise addresses all the aspects of the preliminary design, including the definition of the mission and system requirements, the selection of the overall mission architecture, operations, and mission phases. A cap on the overall cost allows for the realisation of the platform within a university budget. The outline of the design includes not only the selection and sizing of all the subsystems and payload but also suggests a new strategy for deploying the constellation if the demonstration mission is successful. The utilisation of high TRL and COTS components, as well as mass, power, and link budgets, demonstrate the feasibility of the overall mission concept
format Conference Object
author Barles, Anaïs
Bilkhu, Satnam
Boulnois, Anthony
Cuesta Arijaa, Francisco Javier
Duarri Albacete, Guillem
Easdown, William
Estalella Silvela, Alvaro
Gallego Fernández, Ramiro
Kent, Ben
Martínez Mariscal, Javier
Martinez Mata, Alfonso
Pradeep, Shilpa
Sinclair, Giovanni
Stephens-Simonazzi, Benedict
Yan, Wenhan
Felicetti, Leonard
author_facet Barles, Anaïs
Bilkhu, Satnam
Boulnois, Anthony
Cuesta Arijaa, Francisco Javier
Duarri Albacete, Guillem
Easdown, William
Estalella Silvela, Alvaro
Gallego Fernández, Ramiro
Kent, Ben
Martínez Mariscal, Javier
Martinez Mata, Alfonso
Pradeep, Shilpa
Sinclair, Giovanni
Stephens-Simonazzi, Benedict
Yan, Wenhan
Felicetti, Leonard
author_sort Barles, Anaïs
title Mission ORCA: Orbit Refinement for Collision Avoidance
title_short Mission ORCA: Orbit Refinement for Collision Avoidance
title_full Mission ORCA: Orbit Refinement for Collision Avoidance
title_fullStr Mission ORCA: Orbit Refinement for Collision Avoidance
title_full_unstemmed Mission ORCA: Orbit Refinement for Collision Avoidance
title_sort mission orca: orbit refinement for collision avoidance
publisher iafastro
publishDate 2020
url https://dspace.lib.cranfield.ac.uk/handle/1826/15958
https://iafastro.directory/iac/paper/id/61448/abstract-pdf/IAC-20,E2,3-GTS.4,12,x61448.brief.pdf?2020-07-07.17:00:02
genre Orca
genre_facet Orca
op_relation Barles A, Bilkhu S, Boulnois A, et al., (2020) Mission ORCA: Orbit Refinement for Collision Avoidance. In: 71st International Astronautical Congress - the Cyberspace Edition, 12-14 October 2020, Online
https://dspace.lib.cranfield.ac.uk/handle/1826/15958
https://iafastro.directory/iac/paper/id/61448/abstract-pdf/IAC-20,E2,3-GTS.4,12,x61448.brief.pdf?2020-07-07.17:00:02
op_rights Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/
op_rightsnorm CC-BY
_version_ 1766161769556869120

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