Phase Errors in Diffraction-Limited Imaging: Contrast Limits for Sparse Aperture Masking
Abstract
Bispectrum phase, closure phase and their generalisation to kernel-phase are all independent of pupil-plane phase errors to first-order. This property, when used with Sparse Aperture Masking (SAM) behind adaptive optics, has been used recently in high-contrast observations at or inside the formal diffraction limit of large telescopes. Finding the limitations to these techniques requires an understanding of spatial and temporal third-order phase effects, as well as effects such as time-variable dispersion when coupled with the non-zero bandwidths in real observations. In this paper, formulae describing many of these errors are developed, so that a comparison can be made to fundamental noise processes of photon- and background-noise. I show that the current generation of aperture-masking observations of young solar-type stars, taken carefully in excellent observing conditions, are consistent with being limited by temporal phase noise and photon noise. This has relevance for plans to combine pupil-remapping with spatial filtering. Finally, I describe calibration strategies for kernel-phase, including the optimised calibrator weighting as used for LkCa 15, and the restricted kernel-phase POISE technique that avoids explicit dependence on calibrators.
Cite
@article{arxiv.1301.6205,
title = {Phase Errors in Diffraction-Limited Imaging: Contrast Limits for Sparse Aperture Masking},
author = {Michael J. Ireland},
journal= {arXiv preprint arXiv:1301.6205},
year = {2013}
}
Comments
11 pages, 5 figures, resubmitted to MNRAS after responding to referee's comments