Revised Point-Spread Functions for the Atmospheric Imaging Assembly onboard the Solar Dynamics Observatory

TL;DR

This paper presents revised point-spread functions for the AIA instrument on SDO, improving image correction by accurately modeling diffraction and scattering effects, leading to better solar feature analysis.

Contribution

The paper introduces new PSFs that more accurately account for diffraction and scattering, enhancing image correction for solar observations.

Findings

Approximately 24-33% of light is diffracted depending on the channel.

Diffuse scattered light accounts for 10-35% of the total light.

The revised PSFs outperform previous models in correcting images.

Abstract

We present revised point-spread functions (PSFs) for the Atmospheric Imaging Assembly (AIA) onboard the Solar Dynamics Observatory (SDO). These PSFs provide a robust estimate of the light diffracted by the meshes holding the entrance and focal plane filters and the light that is diffusely scattered over medium- to long-distance by the micro-roughness of the mirrors. We first calibrate the diffracted light using flare images. Our modeling of the diffracted light provides reliable determinations of the mesh parameters and finds that about 24 to 33% of the collected light is diffracted, depending on the AIA channel. Then, we fit for the diffuse scattered light using partially lunar occulted images. We find that the diffuse scattered light can be modeled as a superposition of two power law functions that scatter light over the entire length of the detector. The amount of diffuse scattered light ranges from 10 to 35 %, depending on the AIA channel. In total, AIA diffracts and scatters about 40 to 60 % of the collected light over medium to long distances. When correcting for this, bright image regions increase in intensity by about 30 %, dark image regions decrease in intensity by up to 90 %, and the associated differential emission measure analysis of solar features are affected accordingly. Finally, we compare the image reconstructions using our new PSFs to those using the AIA team PSFs and the PSFs of Poduval et al. (2013). We find that our PSFs outperform the others; our PSFs correct well for the flare diffraction pattern and predict accurately the long-distance scattered light in lunar occultations.