The Fellowship of the Dyson Ring: ACT&Friends' Results and Methods for GTOC 11

Dyson spheres are hypothetical megastructures encircling stars in order to harvest most of their energy output. During the 11th edition of the GTOC challenge, participants were tasked with a complex trajectory planning related to the construction of a precursor Dyson structure, a heliocentric ring m...

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Veröffentlicht in:	arXiv.org 2022-05
Hauptverfasser:	Märtens, Marcus, Izzo, Dario, Blazquez, Emmanuel, Moritz von Looz, Gómez, Pablo, Mergy, Anne, Acciarini, Giacomo, Chit Hong Yam, Javier Hernando Ayuso, Shimane, Yuri
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Schlagworte:	Combinatorial analysis Computer Science - Artificial Intelligence Computer Science - Learning Energy harvesting Evolutionary algorithms Machine learning Optimization Optimization techniques Physics - Earth and Planetary Astrophysics Physics - Instrumentation and Methods for Astrophysics Scheduling Trajectory planning
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creator	Märtens, Marcus Izzo, Dario Blazquez, Emmanuel Moritz von Looz Gómez, Pablo Mergy, Anne Acciarini, Giacomo Chit Hong Yam Javier Hernando Ayuso Shimane, Yuri
description	Dyson spheres are hypothetical megastructures encircling stars in order to harvest most of their energy output. During the 11th edition of the GTOC challenge, participants were tasked with a complex trajectory planning related to the construction of a precursor Dyson structure, a heliocentric ring made of twelve stations. To this purpose, we developed several new approaches that synthesize techniques from machine learning, combinatorial optimization, planning and scheduling, and evolutionary optimization effectively integrated into a fully automated pipeline. These include a machine learned transfer time estimator, improving the established Edelbaum approximation and thus better informing a Lazy Race Tree Search to identify and collect asteroids with high arrival mass for the stations; a series of optimally-phased low-thrust transfers to all stations computed by indirect optimization techniques, exploiting the synodic periodicity of the system; and a modified Hungarian scheduling algorithm, which utilizes evolutionary techniques to arrange a mass-balanced arrival schedule out of all transfer possibilities. We describe the steps of our pipeline in detail with a special focus on how our approaches mutually benefit from each other. Lastly, we outline and analyze the final solution of our team, ACT&Friends, which ranked second at the GTOC 11 challenge.
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subjects	Combinatorial analysis Computer Science - Artificial Intelligence Computer Science - Learning Energy harvesting Evolutionary algorithms Machine learning Optimization Optimization techniques Physics - Earth and Planetary Astrophysics Physics - Instrumentation and Methods for Astrophysics Scheduling Trajectory planning
title	The Fellowship of the Dyson Ring: ACT&Friends' Results and Methods for GTOC 11
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