Laboratory characterisation bench for high precision astrometry

Fabrice Pancher (1); Sebastien Soler (1); Fabien Malbet (1); Manon; Lizzana (1; 2; 3); Pierre Kern (1); Thierry Lepine (4); Alain Leger (5) ((1); Universit\'e Grenoble Alpes; CNRS; IPAG; Grenoble; France; (2) Centre; National d'\'Etudes Spatiales; Toulouse; France; (3) Pyxalis; Moirans,; France; (4) Universit\'e Jean Monnet - Saint-Etienne; IOGS; CNRS; Laboratoire; Hubert Curien; Saint-Etienne; France; (5) Universit\'e Paris-Saclay; CNRS,; CNES; IAS; Gif-sur-Yvette; France)

arXiv:2410.21911·astro-ph.IM·October 30, 2024

Laboratory characterisation bench for high precision astrometry

Fabrice Pancher (1), Sebastien Soler (1), Fabien Malbet (1), Manon, Lizzana (1, 2, 3), Pierre Kern (1), Thierry Lepine (4), Alain Leger (5) ((1), Universit\'e Grenoble Alpes, CNRS, IPAG, Grenoble, France, (2) Centre, National d'\'Etudes Spatiales, Toulouse, France, (3) Pyxalis

PDF

Open Access

TL;DR

This paper presents a specialized optical bench designed to calibrate high-resolution detectors for space telescopes, aiming to improve the precision of astrometric measurements critical for detecting Earth-like exoplanets.

Contribution

It introduces a novel characterization setup capable of assessing detector parameters and correcting field distortions with unprecedented precision for high-precision astrometry.

Findings

01

Successful characterization of a 46-megapixel sensor

02

Precise intra and extra pixel quantum yield mapping

03

Effective correction of optical distortions

Abstract

High precision differential astrometry assesses the positions, distances, and motions of celestial objects in relation to the stars. The focal plane of such space telescope must be calibrated with a precision down to the level of 1e-5 pixel in order to be able to detect Earth-like planets in the close vicinity of the Sun. The presented characterization bench is designed to improve the technology readiness level for the following key points: calibration of new detectors with a high number of pixels and correcting the field distortion using stars in the field of view. The first aim of the project concentrates on the characterization of a 46 megapixels sensor from PYXALIS, to assess its typical parameters using an integrating sphere. The next objective intends to map the intra and extra pixel quantum yield of the detector with a precision of 1e-5 pixels and investigate the evolution of the…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.

Taxonomy

TopicsAstronomical Observations and Instrumentation · Calibration and Measurement Techniques · Astronomy and Astrophysical Research