Differential Spatial Multiplexing from Orthogonal Designs

Yu Deng; Alister G. Burr; Lingyang Song

Differential Spatial Multiplexing from Orthogonal Designs

Yu Deng, Alister G. Burr, Lingyang Song

Electronic Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

We propose a differential spatial multiplexing (SM) scheme based on complex square orthogonal designs, referred to as differential orthogonal spatial multiplexing (DOSM). The receiver of DOSM does not require estimation of channel fading coefficients, channel power, signal power, or noise power to decode the data symbols and the decision is based on the two consecutively received codewords. A constellation rotation strategy is introduced to enhance the transmission rate. An upper bound of the pair-wise error probability (PEP) for DOSM in Rayleigh fading channels is derived. Based on this bound we propose design criteria for the constellation rotation angel and use them to search for the optimal rotation angle for PSK constellations. Simulation results show that the proposed DOSM outperforms the existing differential spatial multiplexing schemes in terms of error-rate performance over quasi-static and time-selective Rayleigh fading channels. Furthermore, it is estimated from the bound that DOSM is only 0.4 dB poorer than coherent SM in a two-input two-output system at high SNR. The computational complexity of DOSM is moderate among the differential SM systems.

Original language	English
Title of host publication	2008 IEEE 9TH WORKSHOP ON SIGNAL PROCESSING ADVANCES IN WIRELESS COMMUNICATIONS, VOLS 1 AND 2
Place of Publication	NEW YORK
Publisher	IEEE
Pages	311-315
Number of pages	5
ISBN (Print)	978-1-4244-2045-2
Publication status	Published - 2008

Keywords

Multiple-input multiple output (MIMO) systems
differential space-time modulation
differential spatial multiplexing
constellation rotation
SPACE-TIME MODULATION
TRANSMIT DIVERSITY
COMMUNICATION
CAPACITY
CODES

Cite this

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title = "Differential Spatial Multiplexing from Orthogonal Designs",

abstract = "We propose a differential spatial multiplexing (SM) scheme based on complex square orthogonal designs, referred to as differential orthogonal spatial multiplexing (DOSM). The receiver of DOSM does not require estimation of channel fading coefficients, channel power, signal power, or noise power to decode the data symbols and the decision is based on the two consecutively received codewords. A constellation rotation strategy is introduced to enhance the transmission rate. An upper bound of the pair-wise error probability (PEP) for DOSM in Rayleigh fading channels is derived. Based on this bound we propose design criteria for the constellation rotation angel and use them to search for the optimal rotation angle for PSK constellations. Simulation results show that the proposed DOSM outperforms the existing differential spatial multiplexing schemes in terms of error-rate performance over quasi-static and time-selective Rayleigh fading channels. Furthermore, it is estimated from the bound that DOSM is only 0.4 dB poorer than coherent SM in a two-input two-output system at high SNR. The computational complexity of DOSM is moderate among the differential SM systems.",

keywords = "Multiple-input multiple output (MIMO) systems, differential space-time modulation, differential spatial multiplexing, constellation rotation, SPACE-TIME MODULATION, TRANSMIT DIVERSITY, COMMUNICATION, CAPACITY, CODES",

author = "Yu Deng and Burr, {Alister G.} and Lingyang Song",

year = "2008",

language = "English",

isbn = "978-1-4244-2045-2",

pages = "311--315",

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publisher = "IEEE",

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TY - GEN

T1 - Differential Spatial Multiplexing from Orthogonal Designs

AU - Deng, Yu

AU - Burr, Alister G.

AU - Song, Lingyang

PY - 2008

Y1 - 2008

N2 - We propose a differential spatial multiplexing (SM) scheme based on complex square orthogonal designs, referred to as differential orthogonal spatial multiplexing (DOSM). The receiver of DOSM does not require estimation of channel fading coefficients, channel power, signal power, or noise power to decode the data symbols and the decision is based on the two consecutively received codewords. A constellation rotation strategy is introduced to enhance the transmission rate. An upper bound of the pair-wise error probability (PEP) for DOSM in Rayleigh fading channels is derived. Based on this bound we propose design criteria for the constellation rotation angel and use them to search for the optimal rotation angle for PSK constellations. Simulation results show that the proposed DOSM outperforms the existing differential spatial multiplexing schemes in terms of error-rate performance over quasi-static and time-selective Rayleigh fading channels. Furthermore, it is estimated from the bound that DOSM is only 0.4 dB poorer than coherent SM in a two-input two-output system at high SNR. The computational complexity of DOSM is moderate among the differential SM systems.

AB - We propose a differential spatial multiplexing (SM) scheme based on complex square orthogonal designs, referred to as differential orthogonal spatial multiplexing (DOSM). The receiver of DOSM does not require estimation of channel fading coefficients, channel power, signal power, or noise power to decode the data symbols and the decision is based on the two consecutively received codewords. A constellation rotation strategy is introduced to enhance the transmission rate. An upper bound of the pair-wise error probability (PEP) for DOSM in Rayleigh fading channels is derived. Based on this bound we propose design criteria for the constellation rotation angel and use them to search for the optimal rotation angle for PSK constellations. Simulation results show that the proposed DOSM outperforms the existing differential spatial multiplexing schemes in terms of error-rate performance over quasi-static and time-selective Rayleigh fading channels. Furthermore, it is estimated from the bound that DOSM is only 0.4 dB poorer than coherent SM in a two-input two-output system at high SNR. The computational complexity of DOSM is moderate among the differential SM systems.

KW - Multiple-input multiple output (MIMO) systems

KW - differential space-time modulation

KW - differential spatial multiplexing

KW - constellation rotation

KW - SPACE-TIME MODULATION

KW - TRANSMIT DIVERSITY

KW - COMMUNICATION

KW - CAPACITY

KW - CODES

UR - http://www.scopus.com/inward/record.url?scp=67649921159&partnerID=8YFLogxK

M3 - Conference contribution

SN - 978-1-4244-2045-2

SP - 311

EP - 315

BT - 2008 IEEE 9TH WORKSHOP ON SIGNAL PROCESSING ADVANCES IN WIRELESS COMMUNICATIONS, VOLS 1 AND 2

PB - IEEE

CY - NEW YORK

ER -

Differential Spatial Multiplexing from Orthogonal Designs

Abstract

Keywords

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