Quaternion Fractional Fourier Transform: Bridging Signal Processing and Probability Theory

Muhammad Adnan Samad; Yuanqing Xia; Saima Siddiqui; Muhammad Younus Bhat; Didar Urynbassarova; Altyn Urynbassarova

doi:10.3390/math13020195

Quaternion Fractional Fourier Transform: Bridging Signal Processing and Probability Theory

Muhammad Adnan Samad
, Yuanqing Xia^*
, Saima Siddiqui
, Muhammad Younus Bhat
, Didar Urynbassarova
, Altyn Urynbassarova

^*Corresponding author for this work

School of Automation

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

The one-dimensional quaternion fractional Fourier transform (1DQFRFT) introduces a fractional-order parameter that extends traditional Fourier transform techniques, providing new insights into the analysis of quaternion-valued signals. This paper presents a rigorous theoretical foundation for the 1DQFRFT, examining essential properties such as linearity, the Plancherel theorem, conjugate symmetry, convolution, and a generalized Parseval’s theorem that collectively demonstrate the transform’s analytical power. We further explore the 1DQFRFT’s unique applications to probabilistic methods, particularly for modeling and analyzing stochastic processes within a quaternionic framework. By bridging quaternionic theory with probability, our study opens avenues for advanced applications in signal processing, communications, and applied mathematics, potentially driving significant advancements in these fields.

Original language	English
Article number	195
Journal	Mathematics
Volume	13
Issue number	2
DOIs	https://doi.org/10.3390/math13020195
Publication status	Published - Jan 2025

Keywords

characteristic function
probability theory
quaternion algebra
quaternion fractional Fourier transform
quaternion-valued signals
statistical analysis
stochastic processes

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10.3390/math13020195

Cite this

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title = "Quaternion Fractional Fourier Transform: Bridging Signal Processing and Probability Theory",

abstract = "The one-dimensional quaternion fractional Fourier transform (1DQFRFT) introduces a fractional-order parameter that extends traditional Fourier transform techniques, providing new insights into the analysis of quaternion-valued signals. This paper presents a rigorous theoretical foundation for the 1DQFRFT, examining essential properties such as linearity, the Plancherel theorem, conjugate symmetry, convolution, and a generalized Parseval{\textquoteright}s theorem that collectively demonstrate the transform{\textquoteright}s analytical power. We further explore the 1DQFRFT{\textquoteright}s unique applications to probabilistic methods, particularly for modeling and analyzing stochastic processes within a quaternionic framework. By bridging quaternionic theory with probability, our study opens avenues for advanced applications in signal processing, communications, and applied mathematics, potentially driving significant advancements in these fields.",

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T2 - Bridging Signal Processing and Probability Theory

AU - Samad, Muhammad Adnan

AU - Xia, Yuanqing

AU - Siddiqui, Saima

AU - Bhat, Muhammad Younus

AU - Urynbassarova, Didar

AU - Urynbassarova, Altyn

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AB - The one-dimensional quaternion fractional Fourier transform (1DQFRFT) introduces a fractional-order parameter that extends traditional Fourier transform techniques, providing new insights into the analysis of quaternion-valued signals. This paper presents a rigorous theoretical foundation for the 1DQFRFT, examining essential properties such as linearity, the Plancherel theorem, conjugate symmetry, convolution, and a generalized Parseval’s theorem that collectively demonstrate the transform’s analytical power. We further explore the 1DQFRFT’s unique applications to probabilistic methods, particularly for modeling and analyzing stochastic processes within a quaternionic framework. By bridging quaternionic theory with probability, our study opens avenues for advanced applications in signal processing, communications, and applied mathematics, potentially driving significant advancements in these fields.

KW - characteristic function

KW - probability theory

KW - quaternion algebra

KW - quaternion fractional Fourier transform

KW - quaternion-valued signals

KW - statistical analysis

KW - stochastic processes

UR - https://www.scopus.com/pages/publications/85215817558

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DO - 10.3390/math13020195

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VL - 13

JO - Mathematics

JF - Mathematics

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ER -

Quaternion Fractional Fourier Transform: Bridging Signal Processing and Probability Theory

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Keywords

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