Wavelength calibration for OSIRIS/GTC* tunable filters

TL;DR

This paper presents a precise wavelength calibration method for OSIRIS tunable filters on GTC, achieving better than 1 Å accuracy across the full field of view by modeling wavelength variation with position.

Contribution

It introduces an empirical calibration model for OSIRIS TF that improves wavelength accuracy over the entire field of view, surpassing previous manual calibration methods.

Findings

Calibration accuracy better than 1 Å across the full FOV

Wavelength variation modeled as λ(R)=λ(0)/√(1+(R/f₂)²)

Calibration protocol ensures long-term stability and precision

Abstract

OSIRIS (Optical System for Imaging and low Resolution Integrated Spectroscopy) is the first light instrument of the Gran Telescopio Canarias (GTC). It provides a flexible and competitive tunable filter (TF). Since it is based on a Fabry-Perot interferometer working in collimated beam, the TF transmission wavelength depends on the position of the target with respect to the optical axis. This effect is non-negligible and must be accounted for in the data reduction. Our paper establishes a wavelength calibration for OSIRIS TF with the accuracy required for spectrophotometric measurements using the full field of view (FOV) of the instrument. The variation of the transmission wavelength $\lambda(R)$ across the FOV is well described by $\lambda(R)=\lambda(0)/\sqrt{1+(R/f_2)^2}$, where $\lambda(0)$ is the central wavelength, $R$ represents the physical distance from the optical axis, and $f_2=185.70\pm0.17\,$mm is the effective focal length of the camera lens. This new empirical calibration yields an accuracy better than 1\,\AA\ across the entire OSIRIS FOV ($\sim$8\arcmin$\times$8\arcmin), provided that the position of the optical axis is known within 45 $\mu$m ($\equiv$ 1.5 binned pixels). We suggest a calibration protocol to grant such precision over long periods, upon re-alignment of OSIRIS optics, and in different wavelength ranges. This calibration differs from the calibration in OSIRIS manual which, nonetheless, provides an accuracy $\lesssim1$\AA\, for $R\lesssim 2\arcmin$.