5 research outputs found
Channel Equalization and Beamforming for Quaternion-Valued Wireless Communication Systems
Quaternion-valued wireless communication systems have been studied in the past. Although progress has been made in this promising area, a crucial missing link is lack of effective and efficient quaternion-valued signal processing algorithms for channel equalization and beamforming. With most recent developments in quaternion-valued signal processing, in this work, we fill the gap to solve the problem by studying two quaternion-valued adaptive algorithms: one is the reference signal based quaternion-valued least mean square (QLMS) algorithm and the other one is the quaternion-valued constant modulus algorithm (QCMA). The quaternion-valued Wiener solution for possible block-based calculation is also derived. Simulation results are provided to show the working of the system
Polarization parameters estimation with scalar sensor arrays
The scalar sensor array (SSA) is generally assumed
insensitive to the polarization of impinging signals, and only
diversely polarized arrays, such as the vector (crossed-dipole
or tripole) sensor array (VSA), can be used for polarization
estimation. However, as shown in this paper, with the mutual
coupling effect, the SSA can become partially sensitive to
polarization of the impinging signals and therefore can be
used for polarization parameter estimation. The polarization
sensitivity model of an SSA is first established and then as
an example, a dimension-reduction method based on
multiple signal classification (MUSIC) is employed to
jointly estimate the direction-of-arrival and polarization
parameters. Computer simulations based on a planar array of
circularly polarized microstrip antennas are provided to
demonstrate the performance of the proposed method
Fully Quaternion-Valued Adaptive Beamforming Based on Crossed-Dipole Arrays
Based on crossed-dipole antenna arrays, quaternion-valued data models have been developed for both direction of arrival estimation and beamforming in the past. However, for almost all the models, and especially for adaptive beamforming, the desired signal is still complex-valued as in the quaternion-valued Capon beamformer. Since the complex-valued desired signal only has two components, while there are four components in a quaternion, only two components of the quaternion-valued beamformer output are used and the remaining two are simply discarded, leading to significant redundancy in its implementation. In this work, we consider a quaternion-valued desired signal and develop a fully quaternion-valued Capon beamformer which has a better performance and a much lower complexity. Furthermore, based on this full quaternion model, the robust beamforming problem is also studied in the presence of steering vector errors and a worst-case-based robust beamformer is developed. The performance of the proposed methods is verified by computer simulations
Twenty-five years of sensor array and multichannel signal processing: a review of progress to date and potential research directions
In this article, a general introduction to the area of sensor array and multichannel signal processing is provided, including associated activities of the IEEE Signal Processing Society (SPS) Sensor Array and Multichannel (SAM) Technical Committee (TC). The main technological advances in five SAM subareas made in the past 25 years are then presented in detail, including beamforming, direction-of-arrival (DOA) estimation, sensor location optimization, target/source localization based on sensor arrays, and multiple-input multiple-output (MIMO) arrays. Six recent developments are also provided at the end to indicate possible promising directions for future SAM research, which are graph signal processing (GSP) for sensor networks; tensor-based array signal processing, quaternion-valued array signal processing, 1-bit and noncoherent sensor array signal processing, machine learning and artificial intelligence (AI) for sensor arrays; and array signal processing for next-generation communication systems