The correlator has an input signal which is multiplied by some filter in the Fourier domain. An example filter is the matched filter which uses the cross correlation of the two signals.
The cross correlation or correlation plane, of a 2D signal with is
This can be re-expressed in Fourier space as
where the capital letters denote the Fourier transform of what the lower case letter denotes. So the correlation can then be calculated by inverse Fourier transforming the result.
Implementationedit
According to Fresnel Diffraction theory a convex lens of focal length will produce the exact Fourier transform at a distance behind the lens of an object placed distance in front of the lens. So that complex amplitudes are multiplied, the light source must be coherent and is typically from a laser. The input signal and filter are commonly written onto a spatial light modulator (SLM).
A typical arrangement is the 4f correlator. The input signal is written to an SLM which is illuminated with a laser. This is Fourier transformed with a lens and this is then modulated with a second SLM containing the filter. The resultant is again Fourier transformed with a second lens and the correlation result is captured on a camera.
Filter designedit
Many filters have been designed to be used with an optical correlator. Some have been proposed to address hardware limitations, others were developed to optimize a merit function or to be invariant under a certain transformation.
Matched filteredit
The matched filter maximizes the signal-to-noise ratio and is simply obtained by using as a filter the Fourier transform of the reference signal .
Phase-only filteredit
The phase-only filter[2] is easier to implement due to limitation of many SLMs and has been shown to be more discriminant than the matched filter.
Referencesedit
^A. VanderLugt, Signal detection by complex spatial filtering, IEEE Transactions on Information Theory, vol. 10, 1964, pp. 139–145.
^J. L. Horner and P. D. Gianino, Phase-only matched filtering, Appl. Opt. 23, 1984, 812–816
April 11, 2024
optical, correlator, this, article, multiple, issues, please, help, improve, discuss, these, issues, talk, page, learn, when, remove, these, template, messages, this, article, needs, additional, citations, verification, please, help, improve, this, article, ad. This article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Optical correlator news newspapers books scholar JSTOR February 2007 Learn how and when to remove this template message This article may be too technical for most readers to understand Please help improve it to make it understandable to non experts without removing the technical details May 2020 Learn how and when to remove this template message Learn how and when to remove this template message Optical correlation redirects here Not to be confused with Image correlation An optical correlator is an optical computer for comparing two signals by utilising the Fourier transforming properties of a lens 1 It is commonly used in optics for target tracking and identification Contents 1 Introduction 2 Implementation 3 Filter design 3 1 Matched filter 3 2 Phase only filter 4 ReferencesIntroduction editThe correlator has an input signal which is multiplied by some filter in the Fourier domain An example filter is the matched filter which uses the cross correlation of the two signals The cross correlation or correlation plane c x y displaystyle c x y nbsp of a 2D signal i x y displaystyle i x y nbsp with h x y displaystyle h x y nbsp is c x y i x y h x y displaystyle c x y i x y otimes h x y nbsp This can be re expressed in Fourier space as C 3 h I 3 h H 3 h displaystyle C xi eta I xi eta H xi eta nbsp where the capital letters denote the Fourier transform of what the lower case letter denotes So the correlation can then be calculated by inverse Fourier transforming the result Implementation editAccording to Fresnel Diffraction theory a convex lens of focal length f displaystyle f nbsp will produce the exact Fourier transform at a distance f displaystyle f nbsp behind the lens of an object placed f displaystyle f nbsp distance in front of the lens So that complex amplitudes are multiplied the light source must be coherent and is typically from a laser The input signal and filter are commonly written onto a spatial light modulator SLM A typical arrangement is the 4f correlator The input signal is written to an SLM which is illuminated with a laser This is Fourier transformed with a lens and this is then modulated with a second SLM containing the filter The resultant is again Fourier transformed with a second lens and the correlation result is captured on a camera Filter design editMany filters have been designed to be used with an optical correlator Some have been proposed to address hardware limitations others were developed to optimize a merit function or to be invariant under a certain transformation Matched filter edit The matched filter maximizes the signal to noise ratio and is simply obtained by using as a filter the Fourier transform of the reference signal r x y displaystyle r x y nbsp H 3 h R 3 h displaystyle H xi eta R xi eta nbsp Phase only filter edit The phase only filter 2 is easier to implement due to limitation of many SLMs and has been shown to be more discriminant than the matched filter H 3 h R 3 h R 3 h displaystyle H xi eta frac R xi eta left vert R xi eta right vert nbsp References edit A VanderLugt Signal detection by complex spatial filtering IEEE Transactions on Information Theory vol 10 1964 pp 139 145 J L Horner and P D Gianino Phase only matched filtering Appl Opt 23 1984 812 816 Retrieved from https en wikipedia org w index php title Optical correlator amp oldid 1024317110, wikipedia, wiki, book, books, library,
