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Multiband Transit Follow-up Observations of Five Hot Jupiters with Critical Noise Treatments: Improved Physical Properties

Suman Saha, Aritra Chakrabarty, Sujan Sengupta

2021The Astronomical Journal20 citationsDOIOpen Access PDF

Abstract

Abstract The most challenging limitation in transit photometry arises from the noises in the photometric signal. In particular, the ground-based telescopes are heavily affected by the noise due to perturbation in the Earth’s atmosphere. Use of telescopes with large apertures can improve the photometric signal-to-noise ratio to a great extent. However, detecting a transit signal out of a noisy light curve of the host star and precisely estimating the transit parameters call for various noise reduction techniques. Here, we present multiband transit photometric follow-up observations of five hot Jupiters e.g., HAT-P-30 b, HAT-P-54 b, WASP-43 b, TrES-3 b, and XO-2 N b, using the 2 m Himalayan Chandra Telescope at the Indian Astronomical Observatory, Hanle, and the 1.3 m J. C. Bhattacharya Telescope at the Vainu Bappu Observatory, Kavalur. Our critical noise treatment approach includes techniques such as wavelet denoising and Gaussian process regression, which effectively reduce both time-correlated and time-uncorrelated noise components from our transit light curves. In addition to these techniques, use of our state-of-the-art model algorithms have allowed us to estimate the physical properties of the target exoplanets with a better accuracy and precision compared to the previous studies.

Topics & Concepts

ExoplanetLight curveHot JupiterPhysicsTransit (satellite)Photometry (optics)ObservatoryNoise (video)AstronomyAstrophysicsPlanetStarsComputer scienceLawPolitical sciencePublic transportArtificial intelligenceImage (mathematics)Stellar, planetary, and galactic studiesAstronomical Observations and InstrumentationAdaptive optics and wavefront sensing