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Your search keyword '"McWhirter, John G."' showing total 24 results
Start Over Author "McWhirter, John G." Database Complementary Index
24 results on '"McWhirter, John G."'

1. Polynomial GSVD Beamforming for Two-User Frequency-Selective MIMO Channels.

Author

Hassan, Diyari, Redif, Soydan, McWhirter, John G., and Lambotharan, Sangarapillai

Subjects
MULTICASTING (Computer networks), SINGULAR value decomposition, ORTHOGONAL frequency division multiplexing, BIT error rate, BEAMFORMING, POLYNOMIALS, MIMO systems
Abstract

In this paper, we propose a generalized singular value decomposition (GSVD) for polynomial matrices, or polynomial GSVD (PGSVD). We then consider PGSVD-based beamforming for two-user, frequency-selective, multiple-input multiple-output (MIMO) multicasting. The PGSVD can jointly factorize two frequency-selective MIMO channels, producing a set of virtual channels (VCs), split into: private channels (PCs) and common channels (CCs). An important advantage of the proposed PGSVD-based beamformer, over the application of GSVD independently to each frequency bin of the orthogonal frequency division multiplexing (OFDM) scheme, is that it can facilitate different modulation and/or access schemes to various users. Using computer simulations, we characterize the bit error rate performance of our two-user MIMO multicasting system for different PCs/CCs configurations. Here, we also propose an OFDM-GSVD benchmark system, and show that our PGSVD-based beamformer compares favorably to this benchmark under erroneous and uncertain MIMO channel conditions, in addition to its advantage of facilitating heterogeneous modulation and access for various users. [ABSTRACT FROM AUTHOR]

Published
2021
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12. Broadband angle of arrival estimation methods in a polynomial matrix decomposition framework.

Author

Weiss, Stephan, Alrmah, Mohamed, Lambotharan, Sangarapillai, McWhirter, John G., and Kaveh, Mostafa

Abstract

A large family of broadband angle of arrival estimation algorithms are based on the coherent signal subspace (CSS) method, whereby focussing matrices appropriately align covariance matrices across narrowband frequency bins. In this paper, we analyse an auto-focussing approach in the framework of polynomial covariance matrix decompositions, leading to comparisons to two recently proposed polynomial multiple signal classification (MUSIC) algorithms. The analysis is complemented with numerical simulations. [ABSTRACT FROM PUBLISHER]

Published
2013
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13. A novel method for multichannel spectral factorization.

Author

Jafarian, Amirhossein and McWhirter, John G.

Abstract

A novel algorithm for the spectral factorization (SF) of a para-Hermitian polynomial matrix (PPM) is presented. This utilizes a series of paraunitary transformations to reconstruct the spectral factors of the PPM from the spectral factors of its eigenvalue polynomial matrix (EPM). The EPM is a diagonal polynomial matrix (DPM) obtained by applying a set of simple shift and rotation operators to the PPM using the second order best rotation (SBR2) algorithm. The spectral factors of the EPM are calculated by factorizing each of its scalar elements independently. In this paper, it is shown how to generate a series of paraunitary matrices which then map the factors of the EPM to the required spectral factors of the original PPM. The method basically introduces a sequence of stable operators which provide a direct connection between the one-dimensional spectral factorization problem and the multidimensional case. [ABSTRACT FROM PUBLISHER]

Published
2012

14. An approximate polynomial matrix eigenvalue decomposition algorithm for para-Hermitian matrices.

Author

Redif, Soydan, Weiss, Stephan, and McWhirter, John G.

Abstract

In this paper, we propose an algorithm for computing an approximate polynomial matrix eigenvalue decomposition (PEVD). The PEVD of a para-Hermitian matrix yields a factorisation into a polynomial matrix product consisting of a spectrally majorised diagonal matrix that is pre- and post-multiplied by paraunitary (PU) matrices. All current PEVD algorithms, such as the second order sequential best rotation (SBR2) algorithm, perform a factorisation whereby diagonalisation and spectral majorisation are only achieved in approximation. The purpose of this paper is to present a new iterative approach which constitutes a “Householder-like” version of SBR2 and is akin to Tkacenko's approximate EVD (AEVD); however, unlike the AEVD, the proposed method carries out the diagonalisation successively by applying arbitrary-degree, finite impulse response PU matrices. We show an application of our algorithm to the design of signal-adapted PU filter banks for subband coding. Simulation results for the proposed approach show very close agreement with the behaviour of the infinite order principal component filter banks and demonstrate its superiority compared to state-of-the-art algorithms in terms of strong decorrelation and spectral majorisation. [ABSTRACT FROM PUBLISHER]

Published
2011
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18. Sequential Matrix Diagonalization Algorithms for Polynomial EVD of Parahermitian Matrices.

Author

Redif, Soydan, Weiss, Stephan, and McWhirter, John G.

Subjects
EIGENVALUES, POLYNOMIALS, MIMO systems, WIRELESS communications, SIGNAL processing
Abstract

For parahermitian polynomial matrices, which can be used, for example, to characterize space-time covariance in broadband array processing, the conventional eigenvalue decomposition (EVD) can be generalized to a polynomial matrix EVD (PEVD). In this paper, a new iterative PEVD algorithm based on sequential matrix diagonalization (SMD) is introduced. At every step the SMD algorithm shifts the dominant column or row of the polynomial matrix to the zero lag position and eliminates the resulting instantaneous correlation. A proof of convergence is provided, and it is demonstrated that SMD establishes diagonalization faster and with lower order operations than existing PEVD algorithms. [ABSTRACT FROM PUBLISHER]

Published
2015
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19. Design of FIR Paraunitary Filter Banks for Subband Coding Using a Polynomial Eigenvalue Decomposition.

Author

Redif, Soydan, McWhirter, John G., and Weiss, Stephan

Subjects
CODING theory, POLYNOMIALS, EIGENVALUES, MATHEMATICAL decomposition, SIMULATION methods & models, SIGNAL processing, SEQUENTIAL analysis, ANALYSIS of covariance
Abstract

The problem of paraunitary (PU) filter bank design for subband coding has received considerable attention in recent years, not least because of the energy preserving property of this class of filter banks. In this paper, we consider the design of signal-adapted, finite impulse response (FIR), PU filter banks using polynomial matrix EVD (PEVD) techniques. Modifications are proposed to an iterative, time-domain PEVD method, known as the sequential best rotation (SBR2) algorithm, which enables its effective application to the problem of FIR orthonormal filter bank design for efficient subband coding. By choosing an optimization scheme that maximizes the coding gain at each stage of the algorithm, it is shown that the resulting filter bank behaves more and more like the infinite-order principle component filter bank (PCFB). The proposed method is compared to state-of-the-art techniques, namely the iterative greedy algorithm (IGA), the approximate EVD (AEVD), standard SBR2 and a fast algorithm for FIR compaction filter design, called the window method (WM). We demonstrate that for the calculation of the subband coder, the WM approach offers a low-cost alternative at lower coding gains, while at moderate to high complexity, the proposed approach outperforms the benchmarkers. In terms of run-time complexity, AEVD performs well at low orders, while the proposed algorithm offers a better coding gain than the benchmarkers at moderate to high filter order for a number of simulation scenarios. [ABSTRACT FROM AUTHOR]

Published
2011
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20. Removal of Ballistocardiogram Artifacts Using the Cyclostationary Source Extraction Method.

Author

Ghaderi, Foad, Nazarpour, Kianoush, McWhirter, John G., and Sanei, Saeid

Abstract

Ballistocardiogram (BCG) artifact is considered here as the sum of a number of independent cyclostationary components having the same cycle frequency. Our proposed method, called cyclostationary source extraction (CSE), is able to extract these components without much destructive effect on the background electroencephalogram (EEG). It is shown that the proposed method outperforms other methods particularly in preserving the remaining signals. The CSE is utilized to remove the BCG artifact from real EEG data recorded inside the magnetic resonance (MR) scanner, i.e., visual evoked potential (VEP). The results are compared to the results of benchmark BCG removal techniques. Analyzing the power spectral density of the cleaned EEG data, it is shown that CSE effectively removes the frequency components corresponding to the BCG artifact. It is also shown that VEPs recorded inside the scanner and processed using the proposed method are more correlated with the VEPs recorded outside the scanner. Moreover, there is no need for electrocardiogram (ECG) data in this method as the cycle frequency of the BCG is directly computed from the contaminated EEG signals. [ABSTRACT FROM PUBLISHER]

Published
2010
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21. An Algorithm for Calculating the QR and Singular Value Decompositions of Polynomial Matrices.

Author

Foster, Joanne A., McWhirter, John G., Davies, Martin R., and Chambers, Jonathon A.

Subjects
ALGORITHMS, MATHEMATICAL decomposition, MATRICES (Mathematics), SINGULAR value decomposition, MATHEMATICAL proofs, STOCHASTIC convergence, SIGNAL processing
Abstract

In this paper, a new algorithm for calculating the QR decomposition (QRD) of a polynomial matrix is introduced. This algorithm amounts to transforming a polynomial matrix to upper triangular form by application of a series of paraunitary matrices such as elementary delay and rotation matrices. It is shown that this algorithm can also be used to formulate the singular value decomposition (SVD) of a polynomial matrix, which essentially amounts to diagonalizing a polynomial matrix again by application of a series of paraunitary matrices. Example matrices are used to demonstrate both types of decomposition. Mathematical proofs of convergence of both decompositions are also outlined. Finally, a possible application of such decompositions in multichannel signal processing is discussed. [ABSTRACT FROM AUTHOR]

Published
2010
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22. An EVD Algorithm for Para-Hermitian Polynomial Matrices.

Author

McWhirter, John G., Baxter, Paul D., Cooper, Tom, Redif, Soydan, and Foster, Joanne

Subjects
ALGORITHMS, EIGENVALUES, MATHEMATICAL decomposition, POLYNOMIALS, MATRICES (Mathematics)
Abstract

An algorithm for computing the eigenvalue decomposition of a para-Hermitian polynomial matrix is described. This amounts to diagonalizing the polynomial matrix by means of a paraunitary "similarity" transformation. The algorithm makes use of "elementary paraunitary transformations" and constitutes a generalization of the classical Jacobi algorithm for conventional Hermitian matrix diagonalization. A proof of convergence is presented. The application to signal processing is highlighted in terms of strong decorrelation and multichannel data compaction. Some simulated results are presented to demonstrate the capability of the algorithm [ABSTRACT FROM PUBLISHER]

Published
2007
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23. Nonlinear and non-Gaussian signal processing.

Author

Cowan, Colin F.N., McWhirter, John G., and Mulgrew, Bernard

Subjects
DIGITAL signal processing, STATISTICAL process control, GAUSSIAN processes, INFORMATION measurement, SIGNAL detection, PERIODICALS
Abstract

Editorial. Introduces the February 2004 issue of the journal focusing on nonlinear and non-Gaussian statistical processing. Factors attributed to the development of digital signal processing; Information sources; Key areas identified as core to advancement in digital signal processing.

Published
2004
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