luna: an algorithm for generating dynamic planet-moon transits

It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of...

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Published in	Monthly notices of the Royal Astronomical Society Vol. 416; no. 1; pp. 689 - 709
Main Author	Kipping, David M.
Format	Journal Article
Language	English
Published	Oxford, UK Blackwell Publishing Ltd 01.09.2011 Wiley-Blackwell Oxford University Press
Subjects	Astronomy Earth, ocean, space eclipses Exact sciences and technology Extrasolar planets methods: analytical Moons planetary systems Planetology planets and satellites: general techniques: photometric methods: analytical planetary systems eclipses planets and satellites: general techniques: photometric Extrasolar planets Light curves Planetary system Habitable space Algorithms Asymmetry Neptune planet Limb darkening Dynamics Analytical method Timing Photometry
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ISSN	0035-8711 1365-8711 1365-2966 1365-2966
DOI	10.1111/j.1365-2966.2011.19086.x

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Abstract	It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of transit light curves of a planet plus a single moon including not only the transit timing effects, but also the light-curve signal of the moon itself. We introduce our new algorithm, luna, which produces transit light curves for both bodies, analytically accounting for shadow overlaps, stellar limb darkening and planet-moon dynamical motion. By building the dynamics into the core of luna, the routine automatically accounts for transit-timing/duration variations and ingress/egress asymmetries for not only the planet, but also the moon. We then generate some artificial data for two feasibly detectable hypothetical systems of interest: (i) prograde and (ii) retrograde Earth-like moons around a habitable-zone Neptune for an M dwarf system. We fit the hypothetical systems using luna and demonstrate the feasibility of detecting these cases with Kepler photometry.
AbstractList	It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above similar to 0.2M[oplus]. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of transit light curves of a planet plus a single moon including not only the transit timing effects, but also the light-curve signal of the moon itself. We introduce our new algorithm, luna, which produces transit light curves for both bodies, analytically accounting for shadow overlaps, stellar limb darkening and planet-moon dynamical motion. By building the dynamics into the core of luna, the routine automatically accounts for transit-timing/duration variations and ingress/egress asymmetries for not only the planet, but also the moon. We then generate some artificial data for two feasibly detectable hypothetical systems of interest: (i) prograde and (ii) retrograde Earth-like moons around a habitable-zone Neptune for an M dwarf system. We fit the hypothetical systems using luna and demonstrate the feasibility of detecting these cases with Kepler photometry. ABSTRACT It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above 0.2M. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of transit light curves of a planet plus a single moon including not only the transit timing effects, but also the light-curve signal of the moon itself. We introduce our new algorithm, luna, which produces transit light curves for both bodies, analytically accounting for shadow overlaps, stellar limb darkening and planet-moon dynamical motion. By building the dynamics into the core of luna, the routine automatically accounts for transit-timing/duration variations and ingress/egress asymmetries for not only the planet, but also the moon. We then generate some artificial data for two feasibly detectable hypothetical systems of interest: (i) prograde and (ii) retrograde Earth-like moons around a habitable-zone Neptune for an M dwarf system. We fit the hypothetical systems using luna and demonstrate the feasibility of detecting these cases with Kepler photometry. [PUBLICATION ABSTRACT] ABSTRACT It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of transit light curves of a planet plus a single moon including not only the transit timing effects, but also the light‐curve signal of the moon itself. We introduce our new algorithm, luna, which produces transit light curves for both bodies, analytically accounting for shadow overlaps, stellar limb darkening and planet–moon dynamical motion. By building the dynamics into the core of luna, the routine automatically accounts for transit‐timing/duration variations and ingress/egress asymmetries for not only the planet, but also the moon. We then generate some artificial data for two feasibly detectable hypothetical systems of interest: (i) prograde and (ii) retrograde Earth‐like moons around a habitable‐zone Neptune for an M dwarf system. We fit the hypothetical systems using luna and demonstrate the feasibility of detecting these cases with Kepler photometry. It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing effects have been formerly identified as a potent tool to this end, exploiting the dynamics of the system. In this work, we explore the simulation of transit light curves of a planet plus a single moon including not only the transit timing effects, but also the light-curve signal of the moon itself. We introduce our new algorithm, luna, which produces transit light curves for both bodies, analytically accounting for shadow overlaps, stellar limb darkening and planet-moon dynamical motion. By building the dynamics into the core of luna, the routine automatically accounts for transit-timing/duration variations and ingress/egress asymmetries for not only the planet, but also the moon. We then generate some artificial data for two feasibly detectable hypothetical systems of interest: (i) prograde and (ii) retrograde Earth-like moons around a habitable-zone Neptune for an M dwarf system. We fit the hypothetical systems using luna and demonstrate the feasibility of detecting these cases with Kepler photometry.
Author	Kipping, David M.
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Snippet	It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing effects... ABSTRACT It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above ∼0.2 M⊕. Transit timing... ABSTRACT It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above 0.2M. Transit timing... It has been previously shown that moons of extrasolar planets may be detectable with the Kepler Mission, for moon masses above similar to 0.2M[oplus]. Transit...
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SubjectTerms	Astronomy Earth, ocean, space eclipses Exact sciences and technology Extrasolar planets methods: analytical Moons planetary systems Planetology planets and satellites: general techniques: photometric
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Title	luna: an algorithm for generating dynamic planet-moon transits
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