Magalie Nicolle scite author profile

The detection of extrasolar planets implies an extremely high-contrast, long-exposure imaging capability at near infrared and probably visible wavelengths. We present here the core of any Planet Finder instrument, that is, the extreme adaptive optics (XAO) subsystem. The level of AO correction directly impacts the exposure time required for planet detection. In addition, the capacity of the AO system to calibrate all the instrument static defects ultimately limits detectivity. Hence, the extreme AO system has to adjust for the perturbations induced by the atmospheric turbulence, as well as for the internal aberrations of the instrument itself. We propose a feasibility study for an extreme AO system in the frame of the SPHERE (Spectro-Polarimetry High-contrast Exoplanet Research) instrument, which is currently under design and should equip one of the four VLT 8-m telescopes in 2010.

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Comparison of centroid computation algorithms in a Shack-Hartmann sensor

Thomas

et al. 2006

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Analytical theory is combined with extensive numerical simulations to compare different flavours of centroiding algorithms: thresholding, weighted centroid, correlation, quad cell (QC). For each method, optimal parameters are defined in function of photon flux, readout noise and turbulence level. We find that at very low flux the noise of QC and weighted centroid leads the best result, but the latter method can provide linear and optimal response if the weight follows spot displacements. Both methods can work with average flux as low as 10 photons per subaperture under a readout noise of three electrons. At high‐flux levels, the dominant errors come from non‐linearity of response, from spot truncations and distortions and from detector pixel sampling. It is shown that at high flux, centre of gravity approaches and correlation methods are equivalent (and provide better results than QC estimator) as soon as their parameters are optimized. Finally, examples of applications are given to illustrate the results obtained in the paper.

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Improvement of Shack–Hartmann wave-front sensor measurement for extreme adaptive optics

et al. 2004

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The development of high-performance adaptive optics systems requires the optimization of wave-front sensors (WFSs) working in the high-order correction regime. We propose a new method to improve the wave-front slope estimation of a Shack-Hartmann WFS in such a regime. Based on a detailed analysis of the different errors in the slope estimation with a classical centroid and with the new method, the gain in terms of wave-front-sensing accuracy in both the detector and the photon noise regimes is stressed. This improvement is proposed without major system disruption.

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Optimization of a Shack-Hartmann-based wavefront sensor for XAO systems

Fusco

Nicolle

Rousset

et al. 2004

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Shack-Hartmann wavefront sensing with extended sources

Michau

Conan

Fusco

et al. 2006

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Magalie Nicolle

High-order adaptive optics requirements for direct detection of extrasolar planets: Application to the SPHERE instrument

Comparison of centroid computation algorithms in a Shack-Hartmann sensor

Improvement of Shack–Hartmann wave-front sensor measurement for extreme adaptive optics

Optimization of a Shack-Hartmann-based wavefront sensor for XAO systems

Shack-Hartmann wavefront sensing with extended sources

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