Atmospheric turbulence profiling using multiple laser star wavefront sensors

Cortes, Angela; Neichel, Benoît; Guesalaga, Andrés; Osborn, James; Rigaut, François; Guzmán, Dani

doi:10.1111/j.1365-2966.2012.22076.x

Cited by 47 publications

(60 citation statements)

References 19 publications

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“…3, right), but they also change in shape, especially for larger outer scales. These differences in shape are caused by the finite nature of the telescope pupil and the WFS fratricide effects (Cortés et al 2012). These characteristics are nicely captured via simulation.…”

Section: Gems's Response Functionsmentioning

confidence: 76%

“…The atmospheric turbulence profile is recovered from the correlation of wavefront slopes of two stars (A and B) with a known angular separation. The common turbulence patch between two WFSs for a single layer (left) decreases as a function of the layer altitude; the slant range to the sodium layer (zenith angle); and the angular separation between the artificial stars (see Cortés et al 2012). This causes the correlation peak to shift along the WFS baseline (bottom right).…”

Section: A P Ro F I L I N G M E T H O D F O R L 0 ( H)mentioning

confidence: 99%

“…As GeMS is a closed-loop system, the next step is to construct the pseudo-open-loop slopes (POLSs) from on-sky data using the actuator voltages, the interaction matrix and the residual slopes (see Cortés et al 2012 andGuesalaga et al 2014 for a detailed explanation). After subtracting tip and tilt, these slopes are used to construct the auto-correlation of slopes using the normalization of overlapping subapertures described in Butterley et al (2006) and Wang, Schöck & Chanan (2008).…”

Section: Estimating the Integrated Lmentioning

confidence: 99%

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Online estimation of the wavefront outer scale profile from adaptive optics telemetry

Guesalaga

Neichel

Correia

et al. 2016

Mon. Not. R. Astron. Soc.

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Section: Gems's Response Functionsmentioning

confidence: 76%

Section: A P Ro F I L I N G M E T H O D F O R L 0 ( H)mentioning

confidence: 99%

Section: Estimating the Integrated Lmentioning

confidence: 99%

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Online estimation of the wavefront outer scale profile from adaptive optics telemetry

Guesalaga

Neichel

Correia

et al. 2016

Mon. Not. R. Astron. Soc.

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“…We can estimate the atmospheric optical turbulence profile using the AO telemetry from the WFSs using the slope detection and ranging (SLODAR) method with either natural guide stars (Wilson 2002) or the laser guide stars (LGS; Cortés et al 2012). SLODAR works by correlating the wavefront slopes from two or more WFSs, and a turbulent layer will appear in the covariance function as a peak with an offset from the centre proportional to the altitude of the turbulent layer and a magnitude proportional to the strength of the layer.…”

Section: Ao To M O G R a Pa H Ymentioning

confidence: 99%

“…However, as no AO system is perfect, the residual phase aberration can result in a complicated spatially and temporally varying point spread function (PSF; for example Cagigal & Canales 2000;Currie et al 2000;Osborn, Myers & Love 2009;Baena Gallé & Gladysz 2011). Even in medium-to high-order correction regimes, quasi-static speckles due to non-common path errors and uncorrected aberrations can add complexity to the PSF (Fitzgerald & Graham 2006;Soummer et al 2007;Osborn 2012). These variations in the PSF make separating the light from different objects difficult.…”

Section: Introductionmentioning

confidence: 99%

Scintillation correction for astronomical photometry on large and extremely large telescopes with tomographic atmospheric reconstruction

Osborn

2014

Monthly Notices of the Royal Astronomical Society

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We describe a new concept to correct for scintillation noise on high-precision photometry in large and extremely large telescopes using telemetry data from adaptive optics (AO) systems. Most wide-field AO systems designed for the current era of very large telescopes and the next generation of extremely large telescopes require several guide stars to probe the turbulent atmosphere in the volume above the telescope. These data can be used to tomographically reconstruct the atmospheric turbulence profile and phase aberrations of the wavefront in order to assist wide-field AO correction. If the wavefront aberrations and altitude of the atmospheric turbulent layers are known from this tomographic model, then the effect of the scintillation can be calculated numerically and used to normalize the photometric light curve. We show through detailed Monte Carlo simulation that for an 8 m telescope with a 16 × 16 AO system we can reduce the scintillation noise by an order of magnitude.

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Towards analytical model optimization in atmospheric tomography

Helin

Kindermann²,

Saxenhuber³

2016

Math Methods in App Sciences

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Modern ground‐based telescopes rely on a technology called adaptive optics in order to compensate for the loss of angular resolution caused by atmospheric turbulence. Next‐generation adaptive optics systems designed for a wide field of view require a stable and high‐resolution reconstruction of the turbulent atmosphere. By introducing a novel Bayesian method, we address the problem via reconstructing the atmospheric turbulence strength profile and the turbulent layers simultaneously, where we only use wavefront measurements of incoming light from guide stars. Most importantly, we demonstrate how this method can be used for model optimization as well. We propose two different algorithms for solving the maximum a posteriori estimate: the first approach is based on alternating minimization and has the advantage of integrability into existing atmospheric tomography methods. In the second approach, we formulate a convex non‐differentiable optimization problem, which is solved by an iterative thresholding method. This approach clearly illustrates the underlying sparsity‐enforcing mechanism for the strength profile. By introducing a tuning/regularization parameter, an automated model reduction of the layer structure of the atmosphere is achieved. Using numerical simulations, we demonstrate the performance of our method in practice. Copyright © 2016 John Wiley & Sons, Ltd.

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Atmospheric turbulence profiling using multiple laser star wavefront sensors

Cited by 47 publications

References 19 publications

Online estimation of the wavefront outer scale profile from adaptive optics telemetry

Online estimation of the wavefront outer scale profile from adaptive optics telemetry

Scintillation correction for astronomical photometry on large and extremely large telescopes with tomographic atmospheric reconstruction

Towards analytical model optimization in atmospheric tomography

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