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Main Authors: Ayling, Alex, Fikes, Austin, Mizrahi, Oren S., Wu, Ailec, Riazati, Raha, Brunet, Jesse, Abiri, Behrooz, Bohn, Florian, Gal-Katziri, Matan, Hashemi, Mohammed Reza M., Padmanabhan, Sharmila, Russell, Damon, Hajimiri, Ali
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.15267
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author Ayling, Alex
Fikes, Austin
Mizrahi, Oren S.
Wu, Ailec
Riazati, Raha
Brunet, Jesse
Abiri, Behrooz
Bohn, Florian
Gal-Katziri, Matan
Hashemi, Mohammed Reza M.
Padmanabhan, Sharmila
Russell, Damon
Hajimiri, Ali
author_facet Ayling, Alex
Fikes, Austin
Mizrahi, Oren S.
Wu, Ailec
Riazati, Raha
Brunet, Jesse
Abiri, Behrooz
Bohn, Florian
Gal-Katziri, Matan
Hashemi, Mohammed Reza M.
Padmanabhan, Sharmila
Russell, Damon
Hajimiri, Ali
contents Space solar power (SSP), envisioned for decades as a solution for continuous, stable, and dynamically dispatchable clean energy, has seen tremendous interest and a number of experimental demonstrations in the last few years. A practical implementation has been elusive to date, owing to the high launch costs associated with heavy, rigid photovoltaic (PV) and wireless power transfer (WPT) arrays. Lightweight and flexible solutions for WPT have been demonstrated terrestrially but, to date, have not been deployed and tested in space. In this paper, we present an experimental space demonstration of a lightweight, flexible WPT array powered by custom radio frequency integrated circuits (RFICs). The transmit arrays, receive arrays, and the rest of the system were operated and tested for eight months in Low Earth Orbit (LEO). Results from these experiments, including pointing of the array's beam to Earth and its detection by a ground station, are presented and discussed in detail. Observations and results from this mission uncover existing strengths and weaknesses that inform future steps toward realizing SSP.
format Preprint
id arxiv_https___arxiv_org_abs_2401_15267
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Wireless Power Transfer in Space using Flexible, Lightweight, Coherent Arrays
Ayling, Alex
Fikes, Austin
Mizrahi, Oren S.
Wu, Ailec
Riazati, Raha
Brunet, Jesse
Abiri, Behrooz
Bohn, Florian
Gal-Katziri, Matan
Hashemi, Mohammed Reza M.
Padmanabhan, Sharmila
Russell, Damon
Hajimiri, Ali
Applied Physics
Space solar power (SSP), envisioned for decades as a solution for continuous, stable, and dynamically dispatchable clean energy, has seen tremendous interest and a number of experimental demonstrations in the last few years. A practical implementation has been elusive to date, owing to the high launch costs associated with heavy, rigid photovoltaic (PV) and wireless power transfer (WPT) arrays. Lightweight and flexible solutions for WPT have been demonstrated terrestrially but, to date, have not been deployed and tested in space. In this paper, we present an experimental space demonstration of a lightweight, flexible WPT array powered by custom radio frequency integrated circuits (RFICs). The transmit arrays, receive arrays, and the rest of the system were operated and tested for eight months in Low Earth Orbit (LEO). Results from these experiments, including pointing of the array's beam to Earth and its detection by a ground station, are presented and discussed in detail. Observations and results from this mission uncover existing strengths and weaknesses that inform future steps toward realizing SSP.
title Wireless Power Transfer in Space using Flexible, Lightweight, Coherent Arrays
topic Applied Physics
url https://arxiv.org/abs/2401.15267