Adaptive optics for high-contrast imaging: pyramid sensor versus spatially filtered Shack—Hartmann sensor

Vérinaud, Christophe; Louarn, Miska Le; Korkiakoski, Visa; Carbillet, Marcel

doi:10.1111/j.1745-3933.2005.08638.x

Cited by 78 publications

(38 citation statements)

References 19 publications

(23 reference statements)

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“…The Pyramid WFS, however, offers the flexibility to adjust the modulation amplitude and hence the sensitivity of the sensor to the observing conditions. In the extreme case of no modulation at all, the Pyramid WFS very much behaves like an interferometer and measures the phase directly rather than its slope (Verinaud et al 2005).…”

Section: Wavefront Sensingmentioning

confidence: 99%

Adaptive Optics for Astronomy

Davies

Kasper

2012

Annu. Rev. Astron. Astrophys.

291

180

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Adaptive Optics is a prime example of how progress in observational astronomy can be driven by technological developments. At many observatories it is now considered to be part of a standard instrumentation suite, enabling ground-based telescopes to reach the diffraction limit and thus providing spatial resolution superior to that achievable from space with current or planned satellites. In this review we consider adaptive optics from the astrophysical perspective. We show that adaptive optics has led to important advances in our understanding of a multitude of astrophysical processes, and describe how the requirements from science applications are now driving the development of the next generation of novel adaptive optics techniques.

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Section: Wavefront Sensingmentioning

confidence: 99%

Adaptive Optics for Astronomy

Davies

Kasper

2012

Annu. Rev. Astron. Astrophys.

291

180

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“…It therefore ignores the increase in the noise propagator for high-order S-H systems due to reconstructing the wavefront. The Zernike phase contrast sensor, the pyramid wave-front sensor (unmodulated) and the four-bin interferometer all act as interferometers and have a nearly flat spectral response to noise, however, the Shack-Hartmann wave-front sensor has a photon noise propagation power spectral density proportional to d -2 f -2 sinc -2 (df), with d being the sub-aperture size [Verinaud 2005]. A reduction of 1.5 in the RMS error of the Shack-Hartmann sensor was observed in certain cases using a weighted center of gravity algorithm [Nicolle 2004].…”

Section: Trade Study Summarymentioning

confidence: 99%

“…It has been demonstrated to be very robust and does not suffer from chromatic effects. With new techniques applied to these wave-front sensors, such as spatial filtering to prevent aliasing [Poyneer 2004] and matched filtering or weighted center of mass algorithms [Nicolle 2004] to reduce photon noise on the centroiding (provided read noise is negligible), ShackHartmann wave-front sensors have been shown to compare favorably to pyramid sensors [Verinaud 2005]. However, the wavefront reconstruction process means that the ShackHartmann sensor always measures low-order modes less effectively than the other sensors described here.…”

Section: Introductionmentioning

confidence: 99%

Planet Formation Instrument for the Thirty Meter Telescope

Macintosh¹,

Troy²,

Graham³

et al. 2006

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“…They can in principle be used in slope mode to bootstrap to a high Strehl ratio regime and then operate in a direct phase sensing mode, which has a much lower wavefront reconstruction error for low photon fluxes. The pyramid wave-front sensor has been compared in both regimes to the spatially filtered Shack-Hartmann wavefront sensor 4 . The pyramid wave-front sensor in the direct phase mode acts similarly in many ways to a white-light interferometer, but even though its operation in this mode is interferometric in nature, it acts fundamentally different from familiar interferometers such as the Mach-Zehnder interferometer.…”

Section: Introductionmentioning

confidence: 99%

Two-sided pyramid wavefront sensor in the direct phase mode

Phillion

Baker

2006

SPIE Proceedings

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The two-sided pyramid wavefront sensor has been extensively simulated in the direct phase mode using a wave optics code. The two-sided pyramid divides the focal plane so that each half of the core only interferes with the speckles in its half of the focal plane. A relayed image of the pupil plane is formed at the CCD camera for each half. Antipodal speckle pairs are separated so that a pure phase variation causes amplitude variations in the two images. The phase is reconstructed from the difference of the two amplitudes by transforming cosine waves into sine waves using the Hilbert transform. There are also other corrections which have to be applied in Fourier space. The two-sided pyramid wavefront sensor performs extremely well: After two or three iterations, the phase error varies purely in y. The two-sided pyramid pair enables the phase to be completely reconstructed. Its performance has been modeled closed loop with atmospheric turbulence and wind. Both photon noise and read noise were included. The three-sided and four-sided pyramid wavefront sensors have also been studied in direct phase mode. Neither performs nearly as well as does the two-sided pyramid wavefront sensor.

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Adaptive optics for high-contrast imaging: pyramid sensor versus spatially filtered Shack—Hartmann sensor

Cited by 78 publications

References 19 publications

Adaptive Optics for Astronomy

Adaptive Optics for Astronomy

Planet Formation Instrument for the Thirty Meter Telescope

Two-sided pyramid wavefront sensor in the direct phase mode

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