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Main Authors: Mandic, Danilo P., Talebi, Sayed Pouria, Took, Clive Cheong, Xia, Yili, Xu, Dongpo, Xiang, Min, Bourigault, Pauline
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.16771
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author Mandic, Danilo P.
Talebi, Sayed Pouria
Took, Clive Cheong
Xia, Yili
Xu, Dongpo
Xiang, Min
Bourigault, Pauline
author_facet Mandic, Danilo P.
Talebi, Sayed Pouria
Took, Clive Cheong
Xia, Yili
Xu, Dongpo
Xiang, Min
Bourigault, Pauline
contents From their inception, quaternions and their division algebra have proven to be advantageous in modelling rotation/orientation in three-dimensional spaces and have seen use from the initial formulation of electromagnetic filed theory through to forming the basis of quantum filed theory. Despite their impressive versatility in modelling real-world phenomena, adaptive information processing techniques specifically designed for quaternion-valued signals have only recently come to the attention of the machine learning, signal processing, and control communities. The most important development in this direction is introduction of the HR-calculus, which provides the required mathematical foundation for deriving adaptive information processing techniques directly in the quaternion domain. In this article, the foundations of the HR-calculus are revised and the required tools for deriving adaptive learning techniques suitable for dealing with quaternion-valued signals, such as the gradient operator, chain and product derivative rules, and Taylor series expansion are presented. This serves to establish the most important applications of adaptive information processing in the quaternion domain for both single-node and multi-node formulations. The article is supported by Supplementary Material, which will be referred to as SM.
format Preprint
id arxiv_https___arxiv_org_abs_2311_16771
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle The HR-Calculus: Enabling Information Processing with Quaternion Algebra
Mandic, Danilo P.
Talebi, Sayed Pouria
Took, Clive Cheong
Xia, Yili
Xu, Dongpo
Xiang, Min
Bourigault, Pauline
Machine Learning
Signal Processing
From their inception, quaternions and their division algebra have proven to be advantageous in modelling rotation/orientation in three-dimensional spaces and have seen use from the initial formulation of electromagnetic filed theory through to forming the basis of quantum filed theory. Despite their impressive versatility in modelling real-world phenomena, adaptive information processing techniques specifically designed for quaternion-valued signals have only recently come to the attention of the machine learning, signal processing, and control communities. The most important development in this direction is introduction of the HR-calculus, which provides the required mathematical foundation for deriving adaptive information processing techniques directly in the quaternion domain. In this article, the foundations of the HR-calculus are revised and the required tools for deriving adaptive learning techniques suitable for dealing with quaternion-valued signals, such as the gradient operator, chain and product derivative rules, and Taylor series expansion are presented. This serves to establish the most important applications of adaptive information processing in the quaternion domain for both single-node and multi-node formulations. The article is supported by Supplementary Material, which will be referred to as SM.
title The HR-Calculus: Enabling Information Processing with Quaternion Algebra
topic Machine Learning
Signal Processing
url https://arxiv.org/abs/2311.16771