Showing papers on "Harmonic wavelet transform published in 1968"

An Adaptation of the Fast Fourier Transform for Parallel Processing

Abstract: A modified version of the Fast Fourier Transform is developed and described. This version is well adapted for use in a special-purpose computer designed for the purpose. It is shown that only three operators are needed. One operator replaces successive pairs of data points by their sums and differences. The second operator performs a fixed permutation which is an ideal shuffle of the data. The third operator permits the multiplication of a selected subset of the data by a common complex multiplier.If, as seems reasonable, the slowest operation is the complex multiplications required, then, for reasonably sized date sets—e.g. 512 complex numbers—parallelization by the method developed should allow an increase of speed over the serial use of the Fast Fourier Transform by about two orders of magnitude.It is suggested that a machine to realize the speed improvement indicated is quite feasible.The analysis is based on the use of the Kronecker product of matrices. It is suggested that this form is of general use in the development and classification of various modifications and extensions of the algorithm.

The application of the discrete Fourier transform in the estimation of power spectra, coherence, and bispectra of geophysical data

Abstract: The computation of power spectra, cross spectra, coherence, and bispectra of various types of geophysical random processes is part of the established routine. Since it is routine, some of the standard procedures need to be examined rather carefully to be certain that the assumptions behind the procedures are applicable to the data on hand. The basic criteria for a particular method are its resolution bandwidth, its variance, and its bias. In this paper several basic power-spectrum estimation procedures are reviewed and their statistical and mathematical properties are discussed. The direct use of the discrete Fourier transform for various spectrum calculations is discussed in detail, and its properties are compared with the standard procedure that uses the cosine transform of the estimated correlation function.

A fast Fourier transform algorithm using base 8 iterations

Abstract: 1. Introduction. Cooley and Tukey stated in their original paper [1] that the Fast Fourier Transform algorithm is formally most efficient when the number of samples in a record can be expressed as a power of 3 (i.e., N = 3m), and further that there is little efficiency lost by using N = 2m or N = 4™. Later, however, it was recognized that the symmetries of the sine and cosine weighting functions made the base 4 algorithms more efficient than either the base 2 or the base 3 algorithms [2], [3]. Making use of this observation, Gentleman and Sande have constructed an algorithm which performs as many iterations of the transform as possible in a base 4 mode, and then, if required, performs the last iteration in a base 2 mode. Although this "4 + 2" algorithm is more efficient than base 2 algorithms, it is now apparent that the techniques used by Gentleman and Sande can be profitably carried one step further to an even more efficient, base 8 algorithm. The base 8 algorithms described in this paper allow one to perform as many base 8 iterations as possible and then finish the computation by performing a base 4 or a base 2 iteration if one is required. This combination preserves the versatility of the base 2 algorithm while attaining the computational advantage of the base 8 algorithm.

The Fast Fourier-Hadamard Transform and Its Use in Signal Representation and Classification,

Abstract: : A discrete time transform was studied and applied to the representation and discrimination of digitized signals. The transform consists of an orthogonal (Hadamard) matrix whose elements are all ones and minus ones. To facilitate implementation, a fast Hadamard transform (FHT) has been developed requiring only NlogN rather than N squared algebraic additions. Several properties of the FHT are revealed, including the nature of its presence in the fast Fourier transform, in which it performs the additive operations as shown by further decomposing the product of matrices representing the FFT.

A Digital Processor to Generate Spectra in Real Time

Abstract: —A digital processor capable of computing the discrete Fourier transform for a range of audio signals in real time has been built as part of a facility to conduct research in signal processing. The digitized sample values can be complex. The arithmetic unit is configured to perform complex connectives, and automatic array scaling is used to make numerical accuracy independent of signal level. The Cooley–Tukey "fast Fourier transform" is the algorithm used.

Algorithms: Algorithm 339: an algol procedure for the fast Fourier transform with arbitrary factors

Abstract: The following procedures are based on the Cooley-Tukey algor i thm [1] for comput ing the finite Fourier t r ans fo rm of a complex da ta vector; the dimension of the da t a vector is assumed here to be a power of two. Procedure COMPLEXTRANSFORM computes ei ther the complex Fourier t ransform or its inverse. Procedure REALTRANSFORM computes ei ther the Fourier coefficients of a sequence of real da ta points or eva lua tes a Fourier series wi th given cosine and sine coefficients. The number of ar i thmet ic operat ions for ei ther procedure is proport ional to n logs n, where n is the number of da ta points. Procedures FFT2, REVFFT2, REORDER, and REAL TRAN are building blocks, and are used in the two complete procedures ment ioned above. The fas t t r ans fo rm can be computed in a number of different ways, and these bui lding block procedures were wri t ten so as to make practical the comput ing of large t rans forms on a system wi th vir tual memory. Using a method proposed by Singleton [2], d a t a is accessed in sub-sequences of consecutive a r ray elements , and as m u ch comput ing as possible is done in one section of the d a t a before moving on to another. Procedure FFT2 computes the Fourier t r ans fo rm of da ta in normal order, giving a resu l t in reverse b ina ry order. Procedure REVFFT2 computes the Fourier t r ans fo rm of da ta in reverse b ina ry order and leaves the resul t in normal b inary order. Procedure REORDER permutes a complex vector f rom b inary to reverse b ina ry order or f rom reverse b inary to b inary order; this procedure also permutes real da ta in prepara t ion for efficient use of the complex Fourier t ransform. Procedures FFT2, REVFFT2, and REORDER m a y also be used to compute mul t iva r i a te Fourier t ransforms. The procedure R E A L T R A N is used to unscramble and combine the complex t rans forms of the even and odd numbered e lements of a sequence of real d a t a points . This procedure is not restr ic ted to powers of two and can be used whenever the number of da t a points is even.

Fourier transform computer

Abstract: A digital computer for rapidly determining the Fourier transform of a real input signal is disclosed. The computer utilizes the symmetries of sinusoidal functions to reduce the computations required to determine the Fourier transform. Simultaneous addition, multiplication and memory accessing are performed by the computer thereby reducing the time normally required to compute a Fourier transform.

On-line Fourier transform of video images

Abstract: An electrooptic light modulator (Pockels tube) and a coherent light source form the basis for the on-line generation of Fourier transforms of video images.

Fourier Transform Method in Cylindrical Antenna Theory

Abstract: A technique is developed in this paper which greatly reduces the numerical labor involved in the Fourier Transform solution for cylindrical antennas of exbitrary length. This method is then applied to solid antennas with two commonly used excitation geometries. It is also applied to the case of an antenna in a homogeneous conducting media. In all cases it is shown that the numerical results compare very well with the available experimental results.

A digital recording system for Fourier transform spectrometry

Abstract: A digital recording system, with an integrating digital synchronous rectifier, has been built for use with a Fourier transform spectrometer. It exhibits good linearity and accurate integration of the output. A source of systematic error has been detected and overcome. The system is ideally suited for work with Fourier transform spectrometers which are capable of yielding high quality spectra.

Recursive Fast Fourier Transforms

Abstract: The development of the Fast Fourier Transform in complex notation has obscured the savings that can be made through the use of recursive properties of trigometric functions. A disadvantage of the Fast Fourier Transform is that all samples of the function must be stored in memory before processing can start. The computation in the Fast Fourier Transform occurs after the receipt of the last sample of the function; there is no processing of the incoming data prior to this point. Thus if there are N samples of each function, and G different functions (in G "gates" or "channels"), then a total of GN words must be stored in memory.

Character Recognition by Incoherent Fourier Transformation

Abstract: (1968). Character Recognition by Incoherent Fourier Transformation. Optica Acta: International Journal of Optics: Vol. 15, No. 6, pp. 627-628.

On the Relation between z Transforms and a Transform Technique for Time-varying, Linear Systems†

Abstract: The relation between the z transform and the transform technique introduced by Naylor is discussed. In particular, behaviour as the number of samples, N, becomes large ia considered.