# Fine cophasing of segmented aperture telescopes with ZELDA, a Zernike   wavefront sensor in the diffraction-limited regime

**Authors:** Pierre Janin-Potiron, Mamadou N'Diaye, Patrice Martinez, Arthur Vigan,, Kjetil Dohlen, Marcel Carbillet

arXiv: 1704.05501 · 2017-04-20

## TL;DR

This paper demonstrates that ZELDA, a Zernike wavefront sensor, can effectively perform fine cophasing of segmented telescopes in the diffraction-limited regime, achieving nanometric accuracy through a novel analysis scheme.

## Contribution

The authors adapt and enhance ZELDA for diffraction-limited segment phasing, introducing a new analysis method for accurate piston, tip, and tilt measurement and correction.

## Key findings

- Achieves near-zero residual errors in closed-loop correction
- Effective with bright natural guide stars
- Low sensitivity to sensor misalignment

## Abstract

Segmented aperture telescopes require an alignment procedure with successive steps from coarse alignment to monitoring process in order to provide very high optical quality images for stringent science operations such as exoplanet imaging. The final step, referred to as fine phasing, calls for a high sensitivity wavefront sensing and control system in a diffraction-limited regime to achieve segment alignment with nanometric accuracy. In this context, Zernike wavefront sensors represent promising options for such a calibration. A concept called the Zernike unit for segment phasing (ZEUS) was previously developed for ground-based applications to operate under seeing-limited images. Such a concept is, however, not suitable for fine cophasing with diffraction-limited images. We revisit ZELDA, a Zernike sensor that was developed for the measurement of residual aberrations in exoplanet direct imagers, to measure segment piston, tip, and tilt in the diffraction-limited regime. We introduce a novel analysis scheme of the sensor signal that relies on piston, tip, and tilt estimators for each segment, and provide probabilistic insights to predict the success of a closed-loop correction as a function of the initial wavefront error. The sensor unambiguously and simultaneously retrieves segment piston and tip-tilt misalignment. Our scheme allows for correction of these errors in closed-loop operation down to nearly zero residuals in a few iterations. This sensor also shows low sensitivity to misalignment of its parts and high ability for operation with a relatively bright natural guide star. Our cophasing sensor relies on existing mask technologies that make the concept already available for segmented apertures in future space missions.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1704.05501/full.md

## References

47 references — full list in the complete paper: https://tomesphere.com/paper/1704.05501/full.md

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Source: https://tomesphere.com/paper/1704.05501