Point spread functions for the Solar Optical Telescope onboard Hinode

TL;DR

This paper characterizes the point spread functions of the Solar Optical Telescope onboard Hinode using Mercury transits and eclipses, revealing near-diffraction-limited performance with minor stray-light effects.

Contribution

It provides a detailed method to determine PSFs for SOT/Hinode using observational data and theoretical modeling, including the impact of stray-light and anisotropy.

Findings

SOT operates close to the diffraction limit with ~0.8 Strehl ratio.

Stray-light contributions are minimal and well-modeled by Voigt functions.

The PSF broadening is about 1% compared to diffraction-limited PSF.

Abstract

The combined PSF of the BFI and the SOT onboard the Hinode spacecraft is investigated. Observations of the Mercury transit from November 2006 and the solar eclipse(s) from 2007 are used to determine the PSFs of SOT for the blue, green, and red continuum channels of the BFI. For each channel large grids of theoretical point spread functions are calculated by convolution of the ideal diffraction-limited PSF and Voigt profiles. These PSFs are applied to artificial images of an eclipse and a Mercury transit. The comparison of the resulting artificial intensity profiles across the terminator and the corresponding observed profiles yields a quality measure for each case. The optimum PSF for each observed image is indicated by the best fit. The observed images of the Mercury transit and the eclipses exhibit a clear proportional relation between the residual intensity and the overall light level in the telescope. In addition there is a anisotropic stray-light contribution. ... BFI/SOT operate close to the diffraction limit and have only a rather small stray-light contribution. The FWHM of the PSF is broadened by only ~1% with respect to the diffraction-limited case, while the overall Strehl ratio is ~ 0.8. In view of the large variations -- best seen in the residual intensities of eclipse images -- and the dependence on the overall light level and position in the FOV, a range of PSFs should be considered instead of a single PSF per wavelength. The individual PSFs of that range allow then the determination of error margins for the quantity under investigation. Nevertheless the stray-light contributions are here found to be best matched with Voigt functions with the parameters sigma = 0."008 and gamma = 0."004, 0."005, and 0."006 for the blue, green, and red continuum channels, respectively.