Correcting for the effects of pupil discontinuities with the ACAD method

TL;DR

This paper introduces the ACAD method to correct pupil discontinuities in coronagraphic instruments using two deformable mirrors, enhancing contrast and throughput for complex telescope geometries.

Contribution

The paper presents the ACAD technique, leveraging dual deformable mirrors to correct complex pupil geometries, improving contrast and throughput in coronagraphic systems.

Findings

High contrast levels achieved with various DM setups on WFIRST pupil

Performance comparable to previously designed coronagraphs for WFIRST

DM configuration significantly impacts contrast and throughput

Abstract

The current generation of ground-based coronagraphic instruments uses deformable mirrors to correct for phase errors and to improve contrast levels at small angular separations. Improving these techniques, several space and ground based instruments are currently developed using two deformable mirrors to correct for both phase and amplitude errors. However, as wavefront control techniques improve, more complex telescope pupil geometries will soon be a limiting factor for these next generation coronagraphic instru- ments. The technique presented in this proceeding, the Active Correction of Aperture Discontinuities method, is taking advantage of the fact that most future coronagraphic instruments will include two deformable mirrors, and is proposing to find the shapes and actuator movements to correct for the effect introduced by these complex pupil geometries. We here present the results of the parametric analysis realized on the WFIRST pupil for which we obtained high contrast levels with several deformable mirror setups (size, separation between them), coronagraphs (Vortex charge 2, vortex charge 4, APLC) and spectral bandwidths. However, because contrast levels and separation are not the only metrics to maximize the scientific return of an instrument, we also included in this study the influence of these deformable mirror shapes on the throughput of the instrument and sensitivity to pointing jitters. Finally, we present results obtained on another potential space based telescope segmented aperture. The main result of this proceeding is that we now obtain comparable performance than the coronagraphs previously designed for WFIRST. First result from the parametric analysis strongly suggest that the 2 deformable mirror set up (size and distance between them) has a important impact on the performance in contrast and throughput of the final instrument.