Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions

Sankalp Gilda; Yuan-Sen Ting; Kanoa Withington; Matt Wilson; S Prunet; William Mahoney; S Fabbro; Stark Draper; Andy Sheinis

Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions

Sankalp Gilda, Yuan-Sen Ting, Kanoa Withington, Matt Wilson, S Prunet, William Mahoney, S Fabbro, Stark Draper, Andy Sheinis

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Intelligent scheduling of the sequence of scientific exposures taken at ground-based astronomical observatories is massively challenging. Observing time is over-subscribed and atmospheric conditions are constantly changing. We propose to guide observatory scheduling using machine learning. Leveraging a 15-year archive of exposures, environmental, and operating conditions logged by the Canada-France-Hawaii Telescope, we construct a probabilistic data-driven model that accurately predicts image quality. We demonstrate that, by optimizing the opening and closing of twelve vents placed on the dome of the telescope, we can reduce dome-induced turbulence and improve telescope image quality by (0.05-0.2 arc-seconds). This translates to a reduction in exposure time (and hence cost) of âˆ¼10âˆ’15%. Our study is the first step toward data-based optimization of the multi-million dollar operations of current and next-generation telescopes.

Original language	English
Title of host publication	Advances in Neural Information Processing Systems
Editors	H. Larochelle, M. Ranzato, R. Hadsell, M.F. Balcan & H. Lin
Place of Publication	United States
Publisher	Neural Information Processing Systems Foundation
ISBN (Print)	9781713829546
Publication status	Published - 2020
Event	34th Conference on Neural Information Processing Systems, NeurIPS 2020 - Vancouver, Canada, Virtual Duration: 1 Jan 2020 → … https://proceedings.neurips.cc/paper/2020

Conference

Conference	34th Conference on Neural Information Processing Systems, NeurIPS 2020
Period	1/01/20 → …
Other	December 6-12 2020
Internet address	https://proceedings.neurips.cc/paper/2020

Cite this

@inproceedings{94e86cfb7ce7465a81f1e6244d9efd3f,

title = "Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions",

abstract = "Intelligent scheduling of the sequence of scientific exposures taken at ground-based astronomical observatories is massively challenging. Observing time is over-subscribed and atmospheric conditions are constantly changing. We propose to guide observatory scheduling using machine learning. Leveraging a 15-year archive of exposures, environmental, and operating conditions logged by the Canada-France-Hawaii Telescope, we construct a probabilistic data-driven model that accurately predicts image quality. We demonstrate that, by optimizing the opening and closing of twelve vents placed on the dome of the telescope, we can reduce dome-induced turbulence and improve telescope image quality by (0.05-0.2 arc-seconds). This translates to a reduction in exposure time (and hence cost) of {\^a}ˆ¼10{\^a}ˆ{\textquoteright}15%. Our study is the first step toward data-based optimization of the multi-million dollar operations of current and next-generation telescopes.",

author = "Sankalp Gilda and Yuan-Sen Ting and Kanoa Withington and Matt Wilson and S Prunet and William Mahoney and S Fabbro and Stark Draper and Andy Sheinis",

year = "2020",

language = "English",

isbn = "9781713829546",

editor = "{H. Larochelle, M. Ranzato, R. Hadsell, M.F. Balcan & H. Lin}",

booktitle = "Advances in Neural Information Processing Systems",

publisher = "Neural Information Processing Systems Foundation",

note = "34th Conference on Neural Information Processing Systems, NeurIPS 2020 ; Conference date: 01-01-2020",

url = "https://proceedings.neurips.cc/paper/2020",

}

Gilda, S, Ting, Y-S, Withington, K, Wilson, M, Prunet, S, Mahoney, W, Fabbro, S, Draper, S & Sheinis, A 2020, Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions. in HLMRRHMFBHL (ed.), Advances in Neural Information Processing Systems. Neural Information Processing Systems Foundation, United States, 34th Conference on Neural Information Processing Systems, NeurIPS 2020, 1/01/20.

Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions. / Gilda, Sankalp; Ting, Yuan-Sen; Withington, Kanoa et al.
Advances in Neural Information Processing Systems. ed. / H. Larochelle, M. Ranzato, R. Hadsell, M.F. Balcan & H. Lin. United States: Neural Information Processing Systems Foundation, 2020.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions

AU - Gilda, Sankalp

AU - Ting, Yuan-Sen

AU - Withington, Kanoa

AU - Wilson, Matt

AU - Prunet, S

AU - Mahoney, William

AU - Fabbro, S

AU - Draper, Stark

AU - Sheinis, Andy

PY - 2020

Y1 - 2020

N2 - Intelligent scheduling of the sequence of scientific exposures taken at ground-based astronomical observatories is massively challenging. Observing time is over-subscribed and atmospheric conditions are constantly changing. We propose to guide observatory scheduling using machine learning. Leveraging a 15-year archive of exposures, environmental, and operating conditions logged by the Canada-France-Hawaii Telescope, we construct a probabilistic data-driven model that accurately predicts image quality. We demonstrate that, by optimizing the opening and closing of twelve vents placed on the dome of the telescope, we can reduce dome-induced turbulence and improve telescope image quality by (0.05-0.2 arc-seconds). This translates to a reduction in exposure time (and hence cost) of âˆ¼10âˆ’15%. Our study is the first step toward data-based optimization of the multi-million dollar operations of current and next-generation telescopes.

AB - Intelligent scheduling of the sequence of scientific exposures taken at ground-based astronomical observatories is massively challenging. Observing time is over-subscribed and atmospheric conditions are constantly changing. We propose to guide observatory scheduling using machine learning. Leveraging a 15-year archive of exposures, environmental, and operating conditions logged by the Canada-France-Hawaii Telescope, we construct a probabilistic data-driven model that accurately predicts image quality. We demonstrate that, by optimizing the opening and closing of twelve vents placed on the dome of the telescope, we can reduce dome-induced turbulence and improve telescope image quality by (0.05-0.2 arc-seconds). This translates to a reduction in exposure time (and hence cost) of âˆ¼10âˆ’15%. Our study is the first step toward data-based optimization of the multi-million dollar operations of current and next-generation telescopes.

M3 - Conference contribution

SN - 9781713829546

BT - Advances in Neural Information Processing Systems

A2 - null, H. Larochelle, M. Ranzato, R. Hadsell, M.F. Balcan & H. Lin

PB - Neural Information Processing Systems Foundation

CY - United States

T2 - 34th Conference on Neural Information Processing Systems, NeurIPS 2020

Y2 - 1 January 2020

ER -

Astronomical Image Quality Prediction based on Environmental and Telescope Operating Conditions

Abstract

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