Optical Hartley Transform
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mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
, the Hartley transform (HT) is an integral transform closely related to the
Fourier transform A Fourier transform (FT) is a mathematical transform that decomposes functions into frequency components, which are represented by the output of the transform as a function of frequency. Most commonly functions of time or space are transformed, ...
(FT), but which transforms real-valued functions to real-valued functions. It was proposed as an alternative to the Fourier transform by
Ralph V. L. Hartley Ralph Vinton Lyon Hartley (November 30, 1888 – May 1, 1970) was an American electronics researcher. He invented the Hartley oscillator and the Hartley transform, and contributed to the foundations of information theory. Biography Hartley was ...
in 1942, and is one of many known Fourier-related transforms. Compared to the Fourier transform, the Hartley transform has the advantages of transforming real functions to real functions (as opposed to requiring complex numbers) and of being its own inverse. The discrete version of the transform, the discrete Hartley transform (DHT), was introduced by
Ronald N. Bracewell Ronald Newbold Bracewell Order of Australia, AO (22 July 1921 – 12 August 2007) was the Lewis M. Terman Professor of Electrical Engineering of the Space, Telecommunications, and Radioscience Laboratory at Stanford University. Education B ...
in 1983. The two-dimensional Hartley transform can be computed by an analog optical process similar to an optical Fourier transform (OFT), with the proposed advantage that only its amplitude and sign need to be determined rather than its complex phase. However, optical Hartley transforms do not seem to have seen widespread use.


Definition

The Hartley transform of a function f(t) is defined by: H(\omega) = \left\(\omega) = \frac\int_^\infty f(t) \operatorname(\omega t) \, \mathrmt\,, where \omega can in applications be an angular frequency and \operatorname(t) = \cos(t) + \sin(t) = \sqrt \sin (t+\pi /4) = \sqrt \cos (t-\pi /4)\,, is the cosine-and-sine (cas) or ''Hartley'' kernel. In engineering terms, this transform takes a signal (function) from the time-domain to the Hartley spectral domain (frequency domain).


Inverse transform

The Hartley transform has the convenient property of being its own inverse (an involution): f = \\,.


Conventions

The above is in accord with Hartley's original definition, but (as with the Fourier transform) various minor details are matters of convention and can be changed without altering the essential properties: *Instead of using the same transform for forward and inverse, one can remove the / from the forward transform and use / for the inverse—or, indeed, any pair of normalizations whose product is (Such asymmetrical normalizations are sometimes found in both purely mathematical and engineering contexts.) *One can also use 2\pi\nu t instead of \omega t (i.e., frequency instead of angular frequency), in which case the / coefficient is omitted entirely. *One can use \cos-\sin instead of \cos+\sin as the kernel.


Relation to Fourier transform

This transform differs from the classic Fourier transform F(\omega) = \mathcal \(\omega) in the choice of the kernel. In the Fourier transform, we have the exponential kernel, where \mathrm is the imaginary unit. The two transforms are closely related, however, and the Fourier transform (assuming it uses the same 1/\sqrt normalization convention) can be computed from the Hartley transform via: F(\omega) = \frac - \mathrm \frac\,. That is, the real and imaginary parts of the Fourier transform are simply given by the
even and odd In mathematics, parity is the property of an integer of whether it is even or odd. An integer is even if it is a multiple of two, and odd if it is not.. For example, −4, 0, 82 are even because \begin -2 \cdot 2 &= -4 \\ 0 \cdot 2 &= 0 \\ 41 ...
parts of the Hartley transform, respectively. Conversely, for real-valued functions the Hartley transform is given from the Fourier transform's real and imaginary parts: \ = \Re \ - \Im \ = \Re \\,, where \Re and \Im denote the real and imaginary parts.


Properties

The Hartley transform is a real
linear operator In mathematics, and more specifically in linear algebra, a linear map (also called a linear mapping, linear transformation, vector space homomorphism, or in some contexts linear function) is a mapping V \to W between two vector spaces that pre ...
, and is symmetric (and Hermitian). From the symmetric and self-inverse properties, it follows that the transform is a unitary operator (indeed,
orthogonal In mathematics, orthogonality is the generalization of the geometric notion of ''perpendicularity''. By extension, orthogonality is also used to refer to the separation of specific features of a system. The term also has specialized meanings in ...
). There is also an analogue of the convolution theorem for the Hartley transform. If two functions x(t) and y(t) have Hartley transforms X(\omega) and respectively, then their convolution z(t) = x * y has the Hartley transform: Z(\omega) = \ = \sqrt \left( X(\omega) \left Y(\omega) + Y(-\omega) \right + X(-\omega) \left Y(\omega) - Y(-\omega) \right\right) / 2\,. Similar to the Fourier transform, the Hartley transform of an even/odd function is even/odd, respectively.


cas

The properties of the ''Hartley kernel'', for which Hartley introduced the name ''cas'' for the function (from ''cosine and sine'') in 1942, follow directly from trigonometry, and its definition as a phase-shifted trigonometric function For example, it has an angle-addition identity of: 2 \operatorname (a+b) = \operatorname(a) \operatorname(b) + \operatorname(-a) \operatorname(b) + \operatorname(a) \operatorname(-b) - \operatorname(-a) \operatorname(-b)\,. Additionally: \operatorname (a+b) = + = \cos (b) \operatorname (a) + \sin (b) \operatorname(-a)\,, and its derivative is given by: \operatorname'(a) = \frac \operatorname (a) = \cos (a) - \sin (a) = \operatorname(-a)\,.


See also

* cis (mathematics) *
Fractional Fourier transform In mathematics, in the area of harmonic analysis, the fractional Fourier transform (FRFT) is a family of linear transformations generalizing the Fourier transform. It can be thought of as the Fourier transform to the ''n''-th power, where ''n'' n ...


References

* (NB. Also translated into German and Russian.) * *


Further reading

* {{cite book , editor-first1=Kraig J. , editor-last1=Olnejniczak , editor-first2=Gerald T. , editor-last2=Heydt , chapter=Scanning the Special Section on the Hartley transform , title=Special Issue on Hartley transform , journal=
Proceedings of the IEEE The ''Proceedings of the IEEE'' is a monthly peer-reviewed scientific journal published by the Institute of Electrical and Electronics Engineers (IEEE). The journal focuses on electrical engineering and computer science. According to the ''Journa ...
, volume=82 , issue=3 , pages=372–380 , date=March 1994 , chapter-url=http://ieeexplore.ieee.org/xpl/tocresult.jsp?reload=true&isnumber=6725 , access-date=2017-10-31 , url-status=live (NB. Contains extensive bibliography.) Integral transforms Fourier analysis