Prospects for using drones to test formation-flying CubeSat concepts, and other astronomical applications
John D. Monnier (University of Michigan), Prachet Jain (University of Michigan), Mayra Gutierrez (University of Michigan), Chi Han (University of Michigan), Sara Hezi (University of Michigan), Shashank Kalluri (University of Michigan), Hirsh Kabaria (University of Michigan), Brennan Kompas (University of Michigan), Vaishnavi Harikumar (University of Michigan), Julian Skifstad (University of Michigan), Janani Peri (University of Michigan), Emmanuel Hernandez (University of Michigan), Ramya Bhaskarapanthula (University of Michigan), James Cutler (University of Michigan)
arXiv:2408.03911v1 Announce Type: new
Abstract: Drones provide a versatile platform for remote sensing and atmospheric studies. However, strict payload mass limits and intense vibrations have proven obstacles to adoption for astronomy. We present a concept for system-level testing of a long-baseline CubeSat space interferometer using drones, taking advantage of their cm-level xyz station-keeping, 6-dof freedom of movement, large operational environment, access to guide stars for end-to-end testing of optical train and control algorithms, and comparable mass and power requirements. We have purchased two different drone platforms (Aurelia X6 Pro, Freefly Alta X) and present characterization studies of vibrations, flight stability, gps positioning precision, and more. We also describe our progress in sub-system development, including inter-drone laser metrology, realtime gimbal control, and LED beacon tracking. Lastly, we explore whether custom-built drone-borne telescopes could be used for interferometry of bright objects over km-level baselines using vibration-isolation platforms and a small fast delay for fringe-tracking.arXiv:2408.03911v1 Announce Type: new
Abstract: Drones provide a versatile platform for remote sensing and atmospheric studies. However, strict payload mass limits and intense vibrations have proven obstacles to adoption for astronomy. We present a concept for system-level testing of a long-baseline CubeSat space interferometer using drones, taking advantage of their cm-level xyz station-keeping, 6-dof freedom of movement, large operational environment, access to guide stars for end-to-end testing of optical train and control algorithms, and comparable mass and power requirements. We have purchased two different drone platforms (Aurelia X6 Pro, Freefly Alta X) and present characterization studies of vibrations, flight stability, gps positioning precision, and more. We also describe our progress in sub-system development, including inter-drone laser metrology, realtime gimbal control, and LED beacon tracking. Lastly, we explore whether custom-built drone-borne telescopes could be used for interferometry of bright objects over km-level baselines using vibration-isolation platforms and a small fast delay for fringe-tracking.