Identifying Exoplanets with Deep Learning: A Five-planet Resonant Chain around Kepler-80 and an Eighth Planet around Kepler-90

Shallue, Christopher J.; Vanderburg, Andrew

doi:10.3847/1538-3881/aa9e09

Cited by 359 publications

(335 citation statements)

References 118 publications

(175 reference statements)

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“…So far, independent Kepler searches have focused on only a subset of light-curves (e.g., Kunimoto et al 2018;Shallue & Vanderburg 2018) or a more limited range of orbital periods than examined by the Kepler team (e.g., Wang et al 2015;Caceres et al 2019). In this paper, we present an independent systematic search of the entirety of Kepler data (∼ 200, 000 stars) for planets, using the same three-transit minimum detection criteria as the Kepler team.…”

Section: Paper Outlinementioning

confidence: 99%

“…S/N can often be underestimated, such as through the assumption of a box-shaped transit or the distortion of the transit shape from the detrending algorithm, causing a planet TC to be erroneously rejected. For these reasons, recent searches have begun to relax the noise floor, such as Shallue & Vanderburg (2018) in which a BLS algorithm was used to search as low as S/N = 5, and Kunimoto et al (2018), in which members of our team searched down to S/N = 6.…”

Section: Choice Of S/n Thresholdmentioning

confidence: 99%

“…Even following the release of Kepler catalogues based on all four years of Kepler data (Coughlin et al 2016; Thompson et al 2018), independent authors have shown that there are still scientifically interesting candidates to be found. Shallue & Vanderburg (2018) represents the first application of machine learning to searching Kepler data for exoplanets, finding two new planets among a subset of Q1−Q17 KOIs including an eighth planet in a planetary system. Kunimoto et al (2018) also searched a subset of KOIs, finding four new candidates including a Neptune-sized candidate in the Habitable Zone.…”

Section: Introductionmentioning

confidence: 99%

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Searching the Entirety of Kepler Data. I. 17 New Planet Candidates Including One Habitable Zone World

Kunimoto

Matthews

Ngo

2020

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We present the results of an independent search of all ∼200,000 stars observed over the four year Kepler mission (Q1−Q17) for multiplanet systems, using a three-transit minimum detection criteria to search orbital periods up to hundreds of days. We incorporate both automated and manual triage, and provide estimates of the completeness and reliability of our vetting pipeline. Our search returned 17 planet candidates (PCs) in addition to thousands of known Kepler Objects of Interest (KOIs), with a 98.8% recovery rate of already confirmed planets. We highlight the discovery of one candidate, KIC-7340288 b, that is both rocky (radius ≤ 1.6R ) and in the Habitable Zone (insolation between 0.25 and 2.2 times the Earth's insolation). Another candidate is an addition to the already known KOI-4509 system. We also present adaptive optics imaging follow-up for six of our new PCs, two of which reveal a line-of-sight stellar companion within 4 .

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Section: Paper Outlinementioning

confidence: 99%

Section: Choice Of S/n Thresholdmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Searching the Entirety of Kepler Data. I. 17 New Planet Candidates Including One Habitable Zone World

Kunimoto

Matthews

Ngo

2020

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“…The discovery of extensive multi-planet systems around other stars (Lovis et al 2011;Gillon et al 2017;Shallue & Vanderburg 2018) shows that the Solar System is not unique. Therefore, we may expect exoplanets to also have their own satellites, like the Solar-System planets; Mercury and Venus being exceptions (Namouni 2010;Ogihara & Ida 2012;Barr 2016).…”

Section: Introductionmentioning

confidence: 99%

Fourier series for eclipses on exoplanet binaries

Visser

Mol

2020

A&A

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Context. A double planet system or planet binary undergoes eclipses that modify the reflective light curve. In the time domain, the eclipse events are fast and weak. This would make their signal difficult to find and recognize in the phase light curve, even for small inclinations when eclipses happen frequently. However, due to the quasiperiodic nature of the phenomenon, the Fourier transform of the direct reflection signal consists of a double sum of sharp peaks. These peaks can be resolved for large close binaries and sufficiently long observation times with a star coronagraph. Aims. Eclipses modulate the phase curve, having an orbital period 2π/ω, with a contribution from the relative motion in the binary plane of a period 2π/Ω. This leads to a spectral structure with basis frequencies ω and Ω. We aim to characterize these spectra. Methods. We studied the regime of short eclipses that occur when the planet radii are small compared to the planet separation. We derived formulas for the peak amplitudes applicable to homogeneous (Lambertian) planet binaries in circular orbit with small inclination. Results. The effects of an eclipse and of double reflection appear as first-and second-order contributions (in planet radius over separation) in the reflection signal respectively. Small peaks appear as observable side bands in the spectrum. Identical structures around mΩ are characteristic of short-duration eclipses. Deceasing side bands could indicate double reflection between companions.Conclusions. Fourier analysis of the light curve of non-transiting planets can be used to find planets and their moons. Difficulties in interpreting the structures arise for small planet separation and when there are several moons in mean-motion resonance.

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“…Recent applications in astronomy utilizing ML and AI include: the discovery of extrasolar planets (Pearson, Palafox, & Griffith, 2018;Shallue & Vanderburg, 2018) and gravitationally lensed systems (Jacobs, Glazebrook, Collett, More, & McCarthy, 2017;Lanusse et al, 2018;Pourrahmani, Nayyeri, & Cooray, 2018); discovery and classification of transient objects (Connor & van Leeuwen, 2018;Farah et al, 2018;Mahabal et al, 2019); forecasting solar activity (Florios et al, 2018;Inceoglu et al, 2018;Nishizuka et al, 2017); assignment of photometric redshifts within large-scale galaxy surveys (Bilicki et al, 2018;Ruiz, Corral, Mountrichas, & Georgantopoulos, 2018;Speagle & Eisenstein, 2017); and the classification of gravitational wave signals and instrumental noise (George & Huerta, 2018a, 2018bPowell et al, 2017).…”

mentioning

confidence: 99%

Surveying the reach and maturity of machine learning and artificial intelligence in astronomy

Fluke

Jacobs

2019

WIREs Data Min & Knowl

113

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Machine learning (automated processes that learn by example in order to classify, predict, discover, or generate new data) and artificial intelligence (methods by which a computer makes decisions or discoveries that would usually require human intelligence) are now firmly established in astronomy. Every week, new applications of machine learning and artificial intelligence are added to a growing corpus of work. Random forests, support vector machines, and neural networks are now having a genuine impact for applications as diverse as discovering extrasolar planets, transient objects, quasars, and gravitationally lensed systems, forecasting solar activity, and distinguishing between signals and instrumental effects in gravitational wave astronomy. This review surveys contemporary, published literature on machine learning and artificial intelligence in astronomy and astrophysics. Applications span seven main categories of activity: classification, regression, clustering, forecasting, generation, discovery, and the development of new scientific insights. These categories form the basis of a hierarchy of maturity, as the use of machine learning and artificial intelligence emerges, progresses, or becomes established. This article is categorized under: Application Areas > Science and Technology Fundamental Concepts of Data and Knowledge > Motivation and Emergence of Data Mining Technologies > Machine Learning

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Identifying Exoplanets with Deep Learning: A Five-planet Resonant Chain around Kepler-80 and an Eighth Planet around Kepler-90

Cited by 359 publications

References 118 publications

Searching the Entirety of Kepler Data. I. 17 New Planet Candidates Including One Habitable Zone World

Searching the Entirety of Kepler Data. I. 17 New Planet Candidates Including One Habitable Zone World

Fourier series for eclipses on exoplanet binaries

Surveying the reach and maturity of machine learning and artificial intelligence in astronomy

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