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Proceedings Paper

Concurrent computation of Zernike coefficients used in a phase diversity algorithm for optical aberration correction
Author(s): Richard A. Carreras; Gregory L. Tarr; Sergio R. Restaino; Gary C. Loos; Meledath Damodaran
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Paper Abstract

This paper describes a method to compute the optical transfer function, in terms of Zernike polynomials, one coefficient at a time using a neural network and gradiant decent. Neural networks, which are a class of self-tutored non-linear transfer functions, are shown to be appropriate for this problem as a closed form solution does not exist. A neural network provides an approximation to the optical transfer function computed from examples using gradient descent methods. Orthogonality of the Zernike polynomials allow image wavefront aberrations to be described as an ortho-normal set of coefficients. Atmospheric and system distortion of astronomical observations can introduce an unknown phase error with the observed image. This phase distortion can be described by a set of coefficients of the Zernike polynomials. This orthogonality is shown to contribute to the simplicity of the neural network method of computation. Two paradigms are used to determine the coefficient description of the wave front error to provide to a compensation system. The first uses a phase diverse image as input to a feedforward backpropagation network for generation of a single coefficient. The second method requires the transfer function to be computed in the Fourier domain. Architecture requirements are investigated and reported together with saliency determination of each input the the network to optimize computation and system requirements.

Paper Details

Date Published: 30 December 1994
PDF: 8 pages
Proc. SPIE 2315, Image and Signal Processing for Remote Sensing, (30 December 1994); doi: 10.1117/12.196735
Show Author Affiliations
Richard A. Carreras, Air Force Phillips Lab. (United States)
Gregory L. Tarr, Air Force Phillips Lab. (United States)
Sergio R. Restaino, Air Force Phillips Lab. (United States)
Gary C. Loos, Air Force Phillips Lab. (United States)
Meledath Damodaran, Univ. of Houston/Victoria (United States)


Published in SPIE Proceedings Vol. 2315:
Image and Signal Processing for Remote Sensing
Jacky Desachy, Editor(s)

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