Self-calibration in two dimensional aperture mask optical interferometry: a new method for wavefront sensing (2503.10820v1)

Abstract: We present a new methodology in optical aperture masking interferometry involving Fourier analysis of the complex visibilities (real and imaginary, or amplitude and phase), derived from the interferometric images. The analysis includes use of a non-redundant aperture mask, and self-calibration of the hole-based complex voltage gains to correct for non-uniform illumination and phase fluctuations across the mask. The technique is demonstrated using the Synchrotron Radiation Interferometry (SRI) facility at the ALBA synchrotron light source. Application of the technique results in a joint derivation of the Gaussian shape of the electron beam, and of the hole-based voltage gain amplitude and phase distribution over the mask area. The gain phases are linearly related to the photon path-lengths through the optical system for the ray to each hole, and hence represent an accurate wavefront sensor (WFS) determining the path-length distortions across the wavefront. Wavefront sensing is a vital technology in fields ranging from adaptive optics to metrology to optometry. We calculate that the rms precision of this WFS method is better than 1~nm per frame in the current experiment. We compare the technique to the standard Shack-Hartman WFS. We also show that a structure-agnostic imaging and deconvolution process can be used with the visibility data to determine the beam shape without assuming a Gaussian model, and hence the technique is generalizable to more complex source morphologies.