The active space debris removal mission RemoveDebris. Part 2: In orbit operations

Aglietti, Guglielmo S.; Taylor, B.C.; Fellowes, Simon; Salmon, Thierry; Retat, Ingo; Hall, Alexander; Chabot, Thomas; Pisseloup, Aurélien; Cox, C. M.; Zarkesh, A.; Mafficini, A.; Vinkoff, N.; Bashford, K.; Bernal, Cesar; Chaumette, François; Pollini, A.; Steyn, Willem J.

doi:10.1016/j.actaastro.2019.09.001

Cited by 133 publications

(40 citation statements)

References 9 publications

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“…Experimental space debris removal missions include the European Commission-funded RemoveDebris mission, the world's first Active Debris Removal (ADR) mission, demonstrating cost-effective technologies that can be used to observe, capture, and discard space debris, including net and harpoon capture. This experimental mission was successful and is discussed in Forshaw et al (2020) and Aglietti et al (2020).…”

Section: Introductionmentioning

confidence: 94%

Electromagnetic-launch-based method for cost-efficient space debris removal

Hou

Yang

et al. 2020

Open Astronomy

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The increase in space debris orbiting Earth is a critical problem for future space missions. Space debris removal has thus become an area of interest, and significant research progress is being made in this field. However, the exorbitant cost of space debris removal missions is a major concern for commercial space companies. We therefore propose the debris removal using electromagnetic launcher (DREL) system, a ground-based electromagnetic launch system (railgun), for space debris removal missions. The DREL system has three components: a ground-based electromagnetic launcher (GEML), suborbital vehicle (SOV), and mass of micrometer-scale dust (MSD) particles. The average cost of removing a piece of low-earth orbit space debris using DREL was found to be approximately USD 160,000. The DREL method is thus shown to be economical; the total cost to remove more than 2,000 pieces of debris in a cluster was only approximately USD 400 million, compared to the millions of dollars required to remove just one or two pieces of debris using a conventional space debris removal mission. By using DREL, the cost of entering space is negligible, thereby enabling countries to remove their space debris in an affordable manner.

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Section: Introductionmentioning

confidence: 94%

Electromagnetic-launch-based method for cost-efficient space debris removal

Hou

Yang

et al. 2020

Open Astronomy

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“…(4) Iterate the steps (2) and 3until ∆J = J (k+1) − J (k) < ε, J is the distortion function of K-means, written as…”

Section: Gmm-based Apf Designmentioning

confidence: 99%

“…In order to improve the utilization value of space and save on costs to the aerospace industry, research and development for on-orbit service are ever-increasing. For example, the Cubesat Proximity Operations Demonstration (CPOD) implemented an on-orbit demonstration of rendezvous, proximity operations and docking of two 3U Cubesats [1]; MEV-1 completed the proximity operation to IS-901 satellite, and inserted the docking mechanism into the throat of IS-901 engine nozzle to realize rendezvous and docking; the RemoveDebris mission has successfully demonstrated on-orbit net and harpoon capture and the whole sequence of operations like vision-based navigation for the purpose of Active Debris Removal (ADR) [2]; also the e.Deorbit project has planned to testing technology to clear out space debris [3].…”

Section: Introductionmentioning

confidence: 99%

Safe Proximity Operation to Rotating Non-Cooperative Spacecraft with Complex Shape Using Gaussian Mixture Model-Based Fixed-Time Control

et al. 2020

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This paper studies the safety control problem for rotating spacecraft proximity maneuver in presence of complex shaped obstacles. First, considering the attitude change of the target spacecraft, a dynamic model of close-range relative motion in a body-fixed coordinate system is derived using a novel approach. Then, the Gaussian mixture model (GMM) is utilized to reconstruct the complex shape of the spacecraft, and a novel GMM-based artificial potential function (APF) is proposed to represent the collision avoidance requirement. By combining GMM-based APF with fixed-time stability methodology, a fixed-time control (FTC) is designed for close-range proximity operation to a rotating spacecraft having a complex shape. The presented GMM-FTC scheme can guarantee the convergence of relative state errors, and ensure that no collision occurs. Finally, simulation results are provided to illustrate the feasibility of the proposed control approach.

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“…This paper examines the design of the mission from initial concepts through to manufacture, AIT, testing and up to launch. The mission operations from launch to the various inorbit demonstrations are described in the companion article [1]. Apart from a general consideration of the mission design, only elements of testing that differ from a conventional mission will be examined.…”

Section: Introductionmentioning

confidence: 99%

The active space debris removal mission RemoveDebris. Part 1: From concept to launch

et al. 2020

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This is the first of two companion papers that describe the development of the RemoveDEBRIS; mission. This first article focusses on the mission design and hardware development up to the delivery of the spacecraft to the launch authority. The Secord article describes the in-orbit operations. The European Commission funded RemoveDebris mission has been the world's first Active Debris Removal (ADR) missions to demonstrate, in orbit, some cost effective key technologies, including net and harpoon capture; and elements of the whole sequence of operations, like the vision-based navigation, ultimately planning to terminate the mission with the deployment of the dragsail to de-orbit the craft. The mission has utilized two 2U CubeSats as artificial debris targets released from the main 100 kg satellite, to demonstrate the various technologies. This paper examines the design of the mission from initial concepts through to Manufacture, Assembly Integration and Testing of the payloads, up to launch, and apart from a general consideration of the mission, will focus on the elements of design and testing that differ from a conventional mission.

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The active space debris removal mission RemoveDebris. Part 2: In orbit operations

Cited by 133 publications

References 9 publications

Electromagnetic-launch-based method for cost-efficient space debris removal

Electromagnetic-launch-based method for cost-efficient space debris removal

Safe Proximity Operation to Rotating Non-Cooperative Spacecraft with Complex Shape Using Gaussian Mixture Model-Based Fixed-Time Control

The active space debris removal mission RemoveDebris. Part 1: From concept to launch

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