Non-common path aberration compensation and a dark hole loop with a pyramid adaptive optics system: Application to SAXO+

TL;DR

This study evaluates methods to improve high-contrast imaging by compensating for non-common path aberrations and implementing a dark hole loop with a pyramid adaptive optics system, demonstrating significant residual starlight reduction.

Contribution

It introduces and assesses NCPA compensation and dark hole loop techniques, including optical gain calibration, for the SAXO+ system, enhancing high-contrast imaging performance.

Findings

NCPA compensation reduces residual starlight by a factor of 20 for bright stars.

Dark hole loop reduces residual starlight by a factor of 200.

Optical gain calibration improves dark hole performance in single pyramid AO but not in SAXO+.

Abstract

In ground-based high-contrast instruments, non-common path aberrations (NCPAs) limit detection performance, as they are unseen by the adaptive optics (AO) wavefront sensor but impact the astrophysical image, creating quasi-static speckles. SAXO+, the upgrade of the SAXO (SPHERE AO system) includes a second loop of AO downstream of the SAXO loop that is equipped with a near-infrared pyramid wavefront sensor whose nonlinearities, usually described with modal optical gains, might be challenging for removing quasi-static speckles. We investigated two methods of quasi-static speckle removal : NCPA compensation and a dark hole loop, behind a pyramid AO system, measuring the interest of compensating for the pyramid optical gains. We performed end-to-end numerical simulations under various astrophysical conditions. We offset the pyramid wavefront sensor operating point to apply both the speckle suppression methods, with or without optical gain calibration. We evaluated the performance by measuring the residual starlight in the coronagraph image. A by-product of our study is an on-sky calibration method of measuring the pyramid optical gains. NCPA compensation reduces the residual starlight in the coronagraph image by a factor of 20 for seeing between 0.7" and 1" for a bright star and a factor of 2 at 0.7" for a faint star. Optical gains compensation enhances the performance at poor seeing and small pyramid modulation radius with a bright star, but shows a useless or even negative impact due to estimation inaccuracies at faint targets. On the other hand, the dark hole loop reduces the residual starlight by a factor of 200. The optical gain calibration enhances the dark hole performance behind a single pyramid AO system but is useless behind the SAXO+ system. Our parametric study gives baseline values for the efficient control of the dark hole loop for the SAXO+ system.