( ) ( ) = ( ) = ( ) ( )

Similar documents
Outline. Introduction Definition of fractional fourier transform Linear canonical transform Implementation of FRFT/LCT

Applications on Generalized Two-Dimensional Fractional Sine Transform In the Range

Research Article Dual-Domain Transform for Travelling Wave in FRFT Domain

Estimation of the Optimum Rotational Parameter for the Fractional Fourier Transform Using Domain Decomposition

Filtering in Time-Frequency Domain using STFrFT

Time-frequency plane behavioural studies of harmonic and chirp functions with fractional Fourier transform (FRFT)

A new method of image encryption with. multiple-parameter discrete fractional Fourier transform

Optical implementations of two-dimensional fractional Fourier transforms and linear canonical transforms with arbitrary parameters

On Wavelet Transform: An extension of Fractional Fourier Transform and its applications in optical signal processing

Comparing the Time-Deformation Method with the Fractional Fourier Transform in Filtering Non-Stationary Processes

Closed-Form Discrete Fractional and Affine Fourier Transforms

Research Article Wigner-Ville Distribution Associated with the Linear Canonical Transform

The analysis of decimation and interpolation in the linear canonical transform domain

Convolution theorem and Wigner-Ville distribution

The Discrete Fractional Fourier Transform

Reduced Order Fractional Fourier Transform A New Variant to Fractional Signal Processing: Definition and Properties

CONVOLUTION & PRODUCT THEOREMS FOR FRFT CHAPTER INTRODUCTION [45]

FIXED WINDOW FUNCTIONS WITH NEARLY MINIMUM SIDE LOBE ENERGY BY USING FRACTIONAL FOURIER TRANSFORM

Beamforming Using the Fractional Fourier Transform

INTEGRAL TRANSFORMS METHOD TO SOLVE A TIME-SPACE FRACTIONAL DIFFUSION EQUATION. Abstract

Convolution, Product and Correlation Theorems for Simplified Fractional Fourier Transform: A Mathematical Investigation

Acoustic Seabed Classification using Fractional Fourier Transform

Signal recovery from partial fractional Fourier domain information and its applications H.E. Guven 1 H.M. Ozaktas 2 A.E. Cetin 2 B.

Research Article Poisson Summation Formulae Associated with the Special Affine Fourier Transform and Offset Hilbert Transform

THE COMPARISON OF DIFFERENT METHODS OF CHRIP SIGNAL PROCESSING AND PRESENTATION OF A NEW METHOD FOR PROCESSING IT

Active Sonar Target Classification Using Classifier Ensembles

Laplace Transforms and use in Automatic Control

GENERALIZATION OF CAMPBELL S THEOREM TO NONSTATIONARY NOISE. Leon Cohen

PERIODICITY and discreteness are Fourier duals (or

Image Encryption Using Block Based Transformation With Fractional Fourier Transform

Integrated optical circuits for classical and quantum light. Part 2: Integrated quantum optics. Alexander Szameit

Chapter 3 Convolution Representation

Fractional S-Transform for Boehmians

Fractional Fourier optics

Introduction to Linear Time-Invariant Systems

Video Compression-Encryption using Three Dimensional Discrete Fractional Transforms

Opto-digital tomographic reconstruction of the Wigner distribution function of complex fields

Introduction io Fourier-Finite Mellin Transforms

Transformation and spectrum properties of partially coherent beams in the fractional Fourier transform plane

International Journal of Pure and Applied Sciences and Technology

Operators of Two-dimensional Generalized Canonical sine Transform

Fractional Hankel and Bessel wavelet transforms of almost periodic signals

Bianchi Type-VI Bulk Viscous Fluid String Cosmological Model in General Relativity

Lv's Distribution for Time-Frequency Analysis

IN MANY practical applications, desired signals are degraded

The Laplace Transform

New signal representation based on the fractional Fourier transform: definitions

A.1 THE SAMPLED TIME DOMAIN AND THE Z TRANSFORM. 0 δ(t)dt = 1, (A.1) δ(t)dt =

PROCEEDINGS OF SPIE. Teaching the concept of convolution and correlation using Fourier transform

Properties of LTI Systems

COMPARISON RESULTS OF LINEAR DIFFERENTIAL EQUATIONS WITH FUZZY BOUNDARY VALUES

Review of Computing Algorithms for Discrete Fractional Fourier Transform

International Journal of Pure and Applied Sciences and Technology

Cramer Rule and Adjoint Method for Reduced Biquaternionic Linear Equations

(1) ... (2) /$ IEEE

Application of Fractional Fourier Transform in Non-stationary Signal Time Frequency Analysis

Xu Guanlei Dalian Navy Academy

Abelian Theorem for Generalized Mellin-Whittaker Transform

STFT and DGT phase conventions and phase derivatives interpretation

NOISE ROBUST RELATIVE TRANSFER FUNCTION ESTIMATION. M. Schwab, P. Noll, and T. Sikora. Technical University Berlin, Germany Communication System Group

Short-Time Fourier Transform: Two Fundamental Properties and an Optimal Implementation

Fractional Cyclic Transforms in Optics: Theory and Applications

Fractional wavelet transform

Linear Filters and Convolution. Ahmed Ashraf

Common Fixed Point Theorem Governed by Implicit Relation and Property (E. A.)

ENGIN 211, Engineering Math. Laplace Transforms

On the decay of elements of inverse triangular Toeplitz matrix

Interconnection of LTI Systems

Matrix power converters: spectra and stability

e iωt dt and explained why δ(ω) = 0 for ω 0 but δ(0) =. A crucial property of the delta function, however, is that

Lecture 1 January 5, 2016

Parallel fractional correlation: implementation

Reading assignment: In this chapter we will cover Sections Definition and the Laplace transform of simple functions

Mathematical Methods and its Applications (Solution of assignment-12) Solution 1 From the definition of Fourier transforms, we have.

ESS Dirac Comb and Flavors of Fourier Transforms

Convolution and Linear Systems

Available online at ScienceDirect. Procedia IUTAM 19 (2016 ) IUTAM Symposium Analytical Methods in Nonlinear Dynamics

On the Integral of Almost Periodic Functions. of Several Variables

Math 308 Exam II Practice Problems

Available online at Adv. Fixed Point Theory, 3 (2013), No. 4, ISSN:

(f g)(t) = Example 4.5.1: Find f g the convolution of the functions f(t) = e t and g(t) = sin(t). Solution: The definition of convolution is,

MATH section 3.1 Maximum and Minimum Values Page 1 of 7

Journal of Science and Arts Year 17, No. 1(38), pp , 2017

Find the indicated derivative. 1) Find y(4) if y = 3 sin x. A) y(4) = 3 cos x B) y(4) = 3 sin x C) y(4) = - 3 cos x D) y(4) = - 3 sin x

The Hilbert Transform

REFINEMENTS AND SHARPENINGS OF SOME DOUBLE INEQUALITIES FOR BOUNDING THE GAMMA FUNCTION

HW 9, Math 319, Fall 2016

Definition and Properties

Functions of a Complex Variable (S1) Lecture 11. VII. Integral Transforms. Integral transforms from application of complex calculus

06/12/ rws/jMc- modif SuFY10 (MPF) - Textbook Section IX 1

Chapter 5. Section 5.1. Section ( x ) ( y ) 7. ( x ) ( y ) (0, 3 + 5) and (0, 3 5)

Fractional order Fourier transform as a tool for analyzing multi-element optical system

Comparative study of different techniques for Time-Frequency Analysis

Difference between Reconstruction from Uniform and Non-Uniform Samples using Sinc Interpolation

Available online at ISSN (Print): , ISSN (Online): , ISSN (CD-ROM):

EE 3054: Signals, Systems, and Transforms Summer It is observed of some continuous-time LTI system that the input signal.

IMPROVEMENTS OF COMPOSITION RULE FOR THE CANAVATI FRACTIONAL DERIVATIVES AND APPLICATIONS TO OPIAL-TYPE INEQUALITIES

Discrete Orthogonal Harmonic Transforms

Section Arclength and Curvature. (1) Arclength, (2) Parameterizing Curves by Arclength, (3) Curvature, (4) Osculating and Normal Planes.

The Fractional Fourier Transform and Harmonic Oscillation

Transcription:

Journal of Science and Arts Year 14 No. (7) pp. 105-110 014 ORIGINAL PAPER WEIGHTED CORRELATION ON EXTENDED FRACTIONAL FOURIER TRANSFORM DOMAIN ALKA S. GUDADHE 1 NAVEEN REDDY A. Manuscript received: 03.06.014; Accepted paper: 5.06.014; Published online: 30.06.014. Abstract. In this paper we defined the correlations based on the extended fractional Fourier transform domain. The correlation uses two functions to produce a third function in its own form. This third function is called the correlation of the two functions. Properties of correlations on the extended fractional Fourier transform domain are also presented. Keywords: Extended fractional Fourier transform fractional Fourier transform cross-correlation and auto-correlation. 1. INTRODUCTION The fractional Fourier transform (FrFT) is a generalization of the classical Fourier transform (FT) into fractional domains is introduced way back in 190 s but remained largely unknown until the work of Namias [5] in 1980. It is used in many areas of communication systems signal processing and optics [7 8]. Number of applications of his FrFT can be found in [1 8 9]. Extended fractional Fourier transform (EFrFT) is the generalization of FrFT can be seen in Jianwen Hua et. al. [4] with two more parameters as where ( ) ( ) ( ) = ( ) = F f t u F u f t K t u d t (1.1) i ( a t b u ) cot abtu csc K tu e π + =. In [3] we are introduced the properties on EFrFT domain and in [] we have enhanced the concept of convolution to the domain of EFrFT. In this paper we have defined the correlations of EFrFT and proved some properties on it. 1 Govt. Vidarbha Institute of Science and Humanities Amravati. (M. S.) India. E-mail: alka.gudadhe@gmail.com. Vidyabharti Mahavidyalaya Amravati. (M. S.) India. E-mail: anreddyssv@gmail.com. ISSN: 1844 9581

106 Weighted correlation on extended Alka S. Gudadhe Naveen Reddy A.. CROSS-CORRELATION THEOREM FOR EFrFT: Definition.1: For two functions f(t) and g(t) of extended fractional Fourier transform the weighted correlation operation can be defined as ( ) = ( )( ) = ( ) ( + ) i cot (.1) ht f g t f gt e d where is the cross correlation operation for the extended fractional Fourier transform. H = be the weighted correlation and F G and transforms of functions f g and h respectively Theorem.1. Let ht ( ) ( f g)( t) cot H u = e F u G u (.) π Proof: By (1.1) and (.1) i a ( t ) cot π ( ) cot csc π τ + τ + H u f τ g t τ e dτ e dt Replacing ( ) = ( ) ( + ). i a t b u abtu ab Hence proved. t + τ = v t = v τ and dt = dv ( ) = cot ( ) ( ) H u e F u G u π 3. PROPERTIES OF CROSS CORRELATION OF EFrFT 3.1. Commutative Law: If F G and H transform of functions f g and h respectively and ( ) cot ( ) i π a τ t+ τ ht = f g t = f gt+ e d weighted cross correlation of EFrFT of f and g f g t g f t ( )( ) Proof: Let z( t) = ( g f )( t) ( ) = ( ) ( + ) By (1.1) i a ( t ) cot iπ ( a t b u ) cot abtu csc π τ + τ + Z u g τ f t τ e e dτdt Replace t + τ = v t = v τ and dt = dv. Therefore iπbu Z u e cot = G u F u (3.1) Therefore from (.) and (3.1) ( ) www.josa.ro

Weighted correlation on extended Alka S. Gudadhe Naveen Reddy A. 107 That is ( f g)( t) ( g f )( t) ( ) ( ) H u Z u 3.. Associative Law: If F G and H transform of functions f g and h respectively and i cot ht f g t f gt e d ( ) = ( )( ) = ( ) ( + ) ( f g) y ( t) f ( g y) ( t) Proof: The proof is simple and hence omitted. 3.3. Distributive Law: If F G and H transform of functions f g and h respectively and ( ) cot ( ) i π a τ t+ τ ht = f g t = f τ gt+ τ e dτ f ( g + y) ( t) = ( f g) + ( f y) ( t) Proof: Let z1 ( t) = f ( g + y) ( t) By (1.1) EFrFT of z1 ( t ) will be ( ) = ( ) ( + ) + ( + ) i a ( t ) cot i ( a t b u ) cot i abtu Z csc 1 u π τ + τ π π f τ g t τ y t τ e e + dτdt Substituting t + τ = w t = w τ and dt = dw we obtain ( ) = cot ( ) ( ) + ( ) π Z1 u e F u G u Yab u (3.) Let z ( t) = ( f g) + ( f y) ( t) = ( f g)( t) + ( f y)( t) By (1.1) EFrFT of z ( t ) will be ( ) iπa τ( t+ cot iπa τ( t+ cot { ( ( τ} Z u = f g t + e d + f y t + e d iπ( a t + b u ) cot iπabtu csc e dt Substituting t + τ = w t = w τ and dt = dw we obtain ( ) = cot ( ) ( ) + ( ) π Z u e F u G u Yab u (3.3) Therefore from (3.) and (3.3) f g + y t = f g + f y t Hence proved. ( ) 3.4. Evenness: If F G and H transform of f g and h respectively and ISSN: 1844 9581

108 Weighted correlation on extended Alka S. Gudadhe Naveen Reddy A. ( ) = ( )( ) = ( ) ( + ) i cot ht f g t f gt e d ( f g)( t) = ( g f )( t) ( f g)( t) Proof: Let h ( t) = ( f g)( t) By (.) 1 cot H u = e F u G u (3.4) π 1 Let ( ) = ( )( ) = ( ) ( + ) iπa τ( + t cot h t f g t f g t e d By (1.1) ( ) = ( ) ( + ) i a ( t ) cot π ( ) cot csc π τ + τ + H u f τ g t τ e dτ e dt. i a t b u abtu ab Replacing τ t = v t = τ + v and dt = dv Let h ( t) = ( g f )( t) 3 Therefore by (1.1) cot H u = e F u G u (3.5) ( ) = ( ) ( ) π i a ( t) cot iπ ( a t b u ) cot abtu csc π τ τ + H u g τ f τ t e e dτdt 3 Replace τ t = v t = v + τ and dt = dv cot H u = e G u F u (3.6) π 3 By (3.4) (3.5) and (3.6) f g t = g f t f g t ( )( ) 4. AUTO-CORRELATION THEOREM FOR EFrFT: Definition 4.1. For any functions f ( t ) and ht ( ) the weighted correlation operation can be defined as ( ) = ( )( ) = ( ) ( + ) i (4.1) cot where is the auto-correlation operation for the extended fractional Fourier transform. = is the weighted correlation and F and H transforms of functions f and h respectively Theorem 4.1. Let ht ( ) ( f f)( t) Proof: By (1.1) and (4.1) cot H u = e F u F u (4.) π www.josa.ro

Weighted correlation on extended Alka S. Gudadhe Naveen Reddy A. 109 i a ( t ) cot π ( ) cot csc π τ + τ + H u f τ f t τ e dτ e dt Replacing ( ) = ( ) ( + ). i a t b u abtu ab Hence proved. t + τ = v t = v τ and dt = dv ( ) = cot ( ) ( ) H u e F u F u π 5. PROPERTIES OF AUTO-CORRELATION OF EFrFT: 5.1. Commutative Law: If F and H transform of functions f and h respectively where h is auto correlation Proof: It is obvious. i cot ( f f )( t) = ( f f )( t) 5.. Associative Law: If F and H transform of functions f and h respectively and i cot ( f f ) f ( t) f ( f f ) ( t) Proof: By associative law of cross-correlation of EFrFT. ( f f ) f ( t) f ( f f ) ( t) 5.3. Distributive Law: If F and H transform of functions f and h respectively and i cot ( + ) ( ) = ( ) + f f f t f f f f t Proof: By distributive law of cross-correlation of EFrFT. f f + f t = f f + f f t 5.4. Evenness: If F and H functions f and h respectively and ( ) transform of i cot ( f f )( t) = ( f f )( t) ISSN: 1844 9581

110 Weighted correlation on extended Alka S. Gudadhe Naveen Reddy A. Proof: By evenness of cross-correlation of EFrFT. f f t = f f t ( )( ) 6. CONCLUSIONS In this paper we have defined the weighted cross-correlation and auto correlation in the extended fractional Fourier transform domain. We have also established the cross correlation theorem and proved some related properties. It should also be noted that the theorem and properties are converted to the case of FrFt if we put a=b=1 and moreover they are transformed to the case of conventional FT if further is taken as π/. All these properties and theorem can be utilized in the theory of signal processing. REFERENCES [1] Almeida L.B. IEEE Trans. Signal Process 4(11) 3084 1994. [] Gudadhe A.S. Naveen A. Journal of Science and Arts 4(5) 345 013. [3] Gudadhe A.S. Naveen A. International Journal of Engineering Research and Technology (1) 1189 013. [4] Hua J. Liren L. Guoqiang L. J. Opt. Soc. Am. A 14(1) 3316 1997. [5] Namias V. J. Inst. Math. Appl. 5 41 1980. [6] Olcay A. Fractional convolution and correlation: simulation examples and an application to radar signal detection Norsig Proceedings 00. [7] Ozaktas H.M. Mendlovic D. J. Opt. Soc. Am. A 10 1875 1993. [8] Ozaktas H.M. Mendlovic D. J. Opt. Soc. Am. A. 10(1) 1993. [9] Ozaktas H.M. Zulevsky Z. Kutay M.A. The fractional Fourier transform with Applications in Optics and Signal Process John Wiley and Sons Chichester 001. [10] Pei. S.-C. Liu. C.-L. Lai. Y.-C. The generalized fractional Fourier transform Acoustics Speech and Signal Processing (ICASSP) IEEE 3705 01. www.josa.ro

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback