A. Elkhazin scite author profile

Abstract-The Bell Labs layered space-time (BLAST) architecture is a simple and efficient multiantenna coding structure that can achieve high spectral efficiency. Many BLAST detectors require more receiver antennas than transmitter antennas. We propose two novel turbo-processing BLAST detectors that can operate in systems with fewer receiver antennas than transmitter antennas. Both detectors are based on the group-detection strategy. The first proposed detector, the reduced-dimension maximum a posteriori (RDMAP) detector uses a dynamically formed group for each bit decision, while the second proposed detector, the group maximum a posteriori (GMAP) uses a static grouping. For both detectors, a maximum a posteriori (MAP) decision is made using a group of transmitted symbols, and the remaining signal contribution is treated as interference. The interference is characterized as nonzero mean colored-noise source that is whitened before a decision is made. Both proposed detectors are generalizations of the MAP detector and the turbo-processing minimum mean-squared error (MMSE) detector in Sellathurai and Haykin, and Abe and Matsumoto. An uncoded bit-error rate analysis for an independent Rayleigh fading environment is also presented. Simulated results are presented which show that both the RDMAP and GMAP detectors have a performance improvement over the MMSE detector, especially in systems having an excess number of transmitter antennas.Index Terms-Iterative methods, multidimensional signal detection, multiple-input multiple-output (MIMO) systems, nonlinear detection.

Reduced-dimension MAP turbo-BLAST detection

Elkhazin

Plataniotis

2006

IEEE Trans. Commun.

Absfruct-The BeU-Labs Layered Space-time (BLAST) architecture is a simple and efficient multi-antenna coding S~N C~U I V that can achieve high-spectral efficiency [l]. Many BLAST detectors require more receiver antennas than transmitter antennas. We propose a novel turbo-prncessing BLAST detector based on a group detection strategy that can operate in system with fewer receiver antennas than transmitter antennas. A maximum a pnsterinri (MAP) decision is made using a group of transmitted symbols and the remaining signal contribution is treated as interference. The interference is characterized as non-zero mean colored noise source that is whitened before a decision is made.

Irregular Convolutional Codes in Multiantenna Bit-Interleaved Coded Modulation Under Iterative Detection and Decoding

Elkhazin¹,

Plataniotis

IEEE Trans. Veh. Technol.

2010

Group MAP BLAST detector

Elkhazin¹,

Plataniotis²,

Pasupathy³

The Bell-Labs Layered Space-time (BLAST) architecture is a simple and efficient multi-antenna coding structure that can achieve high-spectral efficiency [1]. Many BLAST detectors require more receiver antennas than transmitter antennas. We propose a novel turbo-processing BLAST detector based on a group detection strategy that can operate in systems with fewer receiver antennas than transmitter antennas. A maximum a posteriori (MAP) decision is made using a group of transmitted symbols and the remaining signal contribution is treated as interference. The interference is characterized as non-zero mean colored noise source that is whitened before a decision is made. The proposed detector, the Group MAP (GMAP) detector, is a generalization of both the MAP detector and the turbo-processing Minimum Mean Squared Error (MMSE) detector in [2,3]. A novel grouping algorithm is proposed for the GMAP detector. Simulation is used to compare the GMAP detector with the MAP detector and MMSE detector.

Pulse shaping for differential offset-QPSK

Lam¹,

Elkhazin

et al. 2006

IEEE Trans. Commun.

Abstract-Pulse shaping is examined as a means to improve the performance of a differential offset quadrature phase-shift keying system in a bandwidth-constrained environment. Through optimization with respect to a composite Nyquist criterion, the derived pulse shapes have comparable performance to a 4-differential quadrature phase-shift keying in an additive white Gaussian noise (AWGN) channel and better performance in a hard-limited AWGN channel.Index Terms-Differential offset quadrature phase-shift keying (DOQPSK), pulse shaping.