George J. M. Aitken scite author profile

Accurate prediction of the short-term future behavior of atmospherically distorted wave fronts would permit the elimination of delays inherent in current adaptive-optics systems. It is shown by using astronomical image data that atmospherically induced wave-front distortions as represented by time series of wave-front tips and tilts measured in the visible and piston values measured in the infrared are predictable to a degree that would be useful in an adaptive-optics system. Adaptive linear predictors as well as predictors based on the back-propagation neural network are employed in this study.

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Using the Fast Orthogonal Search with First Term Reselection to Find Subharmonic Terms in Spectral Analysis

McGaughey

Korenberg

Adeney

et al. 2003

Annals of Biomedical Engineering

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The fast orthogonal search (FOS) algorithm has been shown to accurately model various types of time series by implicitly creating a specialized orthogonal basis set to fit the desired time series. When the data contain periodic components, FOS can find frequencies with a resolution greater than the discrete Fourier transform (DFT) algorithm. Frequencies with less than one period in the record length, called subharmonic frequencies, and frequencies between the bins of a DFT, can be resolved. This paper considers the resolution of subharmonic frequencies using the FOS algorithm. A new criterion for determining the number of non-noise terms in the model is introduced. This new criterion does not assume the first model term fitted is a dc component as did the previous stopping criterion. An iterative FOS algorithm called FOS first-term reselection (FOS-FTR), is introduced. FOS-FTR reduces the mean-square error of the sinusoidal model and selects the subharmonic frequencies more accurately than does the unmodified FOS algorithm.

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Phase-gradient stellar image reconstruction

Aitken

Johnson

Houtman

1986

Optics Communications

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Diffraction-limited imaging from the ground - Measurement of stellar spatial spectra

Aitken

1989

PASP

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Algorithms and computational developments in recent years have yielded suitable techniques for overcoming the resolution limits imposed on conventional astronomical observations by atmospheric turbulence. The Knox-Thompson, triple-correlation, and phase-gradient algorithms are capable of reconstructing the diffraction-limited, complex spatial spectrum of an object from a sequence of short-exposure images. The basic principles of these techniques are reviewed with emphasis on photon-limited operation at visible wavelengths. Practical considerations, magnitude limits, and examples of recent applications are presented.

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George J. M. Aitken

Triple-correlation subplane reconstruction of photon-address stellar images

Prediction of atmospherically induced wave-front degradations

Using the Fast Orthogonal Search with First Term Reselection to Find Subharmonic Terms in Spectral Analysis

Phase-gradient stellar image reconstruction

Diffraction-limited imaging from the ground - Measurement of stellar spatial spectra

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