Space-time diversity systems based on linear constellation precoding

Yan Xin; Zhengdao Wang; Georgios B. Giannakis

doi:10.1109/TWC.2003.808970

Space-time diversity systems based on linear constellation precoding

Yan Xin, Zhengdao Wang, Georgios B. Giannakis

Electrical and Computer Engineering

Research output: Contribution to journal › Article › peer-review

318 Scopus citations

Abstract

We present a unified approach to designing space-time (ST) block codes using linear constellation precoding (LCP). Our designs are based either on parameterizations of unitary matrices, or on algebraic number-theoretic constructions. With an arbitrary number of N_t transmit- and N _r receive-antennas, ST-LCP achieves rate 1 symbol/s/Hz and enjoys diversity gain as high as N_tN_r over (possibly correlated) quasi-static and fast fading channels. As figures of merit, we use diversity and coding gains, as well as mutual information of the underlying multiple-input-multiple-output system. We show that over quadrature-amplitude modulation and pulse-amplitude modulation, our LCP achieves the upper bound on the coding gain of all linear precoders for certain values of N_t and comes close to this upper bound for other values of N_t, in both correlated and independent fading channels. Compared with existing ST block codes adhering to an orthogonal design (ST-OD), ST-LCP offers not only better performance, but also higher mutual information for N_t > 2. For decoding ST-LCP, we adopt the near-optimum sphere-decoding algorithm, as well as reduced-complexity sub-optimum alternatives. Although ST-OD codes afford simpler decoding, the tradeoff between performance and rate versus complexity favors the ST-LCP codes when N_t, N_r, or the spectral efficiency of the system increase. Simulations corroborate our theoretical findings.

Original language	English (US)
Pages (from-to)	294-309
Number of pages	16
Journal	IEEE Transactions on Wireless Communications
Volume	2
Issue number	2
DOIs	https://doi.org/10.1109/TWC.2003.808970
State	Published - Mar 2003

Bibliographical note

Funding Information:
Manuscript received March 7, 2001; revised October 22, 2001 and January 25, 2002; accepted February 25, 2002. The editor coordinating the review of this paper and approving it for publication is A. F. Molisch. This work was supported in part by the National Science Foundation (NSF) under Grant 9979443 and Grant 012243, and in part by an ARL/CTA Grant DAAD19-01-2-011. This work was presented in part at Asilomar Conference on Signals, Systems and Computers, Pacific Grove, CA, October 2000, at the International Conference on Acoustics, Speech and Signal Processing (ICASSP), Salt Lake, UT, May 2001, and in part at the Global Telecommunications Conference (GLOBECOM), San Antonio, TX, November 2001.

Keywords

Diversity
Multiantenna
Rotated constellations
Space-time (ST) codes
Wireless communication

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10.1109/TWC.2003.808970

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title = "Space-time diversity systems based on linear constellation precoding",

abstract = "We present a unified approach to designing space-time (ST) block codes using linear constellation precoding (LCP). Our designs are based either on parameterizations of unitary matrices, or on algebraic number-theoretic constructions. With an arbitrary number of Nt transmit- and N r receive-antennas, ST-LCP achieves rate 1 symbol/s/Hz and enjoys diversity gain as high as NtNr over (possibly correlated) quasi-static and fast fading channels. As figures of merit, we use diversity and coding gains, as well as mutual information of the underlying multiple-input-multiple-output system. We show that over quadrature-amplitude modulation and pulse-amplitude modulation, our LCP achieves the upper bound on the coding gain of all linear precoders for certain values of Nt and comes close to this upper bound for other values of Nt, in both correlated and independent fading channels. Compared with existing ST block codes adhering to an orthogonal design (ST-OD), ST-LCP offers not only better performance, but also higher mutual information for Nt > 2. For decoding ST-LCP, we adopt the near-optimum sphere-decoding algorithm, as well as reduced-complexity sub-optimum alternatives. Although ST-OD codes afford simpler decoding, the tradeoff between performance and rate versus complexity favors the ST-LCP codes when Nt, Nr, or the spectral efficiency of the system increase. Simulations corroborate our theoretical findings.",

keywords = "Diversity, Multiantenna, Rotated constellations, Space-time (ST) codes, Wireless communication",

author = "Yan Xin and Zhengdao Wang and Giannakis, \{Georgios B.\}",

note = "Funding Information: Manuscript received March 7, 2001; revised October 22, 2001 and January 25, 2002; accepted February 25, 2002. The editor coordinating the review of this paper and approving it for publication is A. F. Molisch. This work was supported in part by the National Science Foundation (NSF) under Grant 9979443 and Grant 012243, and in part by an ARL/CTA Grant DAAD19-01-2-011. This work was presented in part at Asilomar Conference on Signals, Systems and Computers, Pacific Grove, CA, October 2000, at the International Conference on Acoustics, Speech and Signal Processing (ICASSP), Salt Lake, UT, May 2001, and in part at the Global Telecommunications Conference (GLOBECOM), San Antonio, TX, November 2001.",

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AU - Giannakis, Georgios B.

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N2 - We present a unified approach to designing space-time (ST) block codes using linear constellation precoding (LCP). Our designs are based either on parameterizations of unitary matrices, or on algebraic number-theoretic constructions. With an arbitrary number of Nt transmit- and N r receive-antennas, ST-LCP achieves rate 1 symbol/s/Hz and enjoys diversity gain as high as NtNr over (possibly correlated) quasi-static and fast fading channels. As figures of merit, we use diversity and coding gains, as well as mutual information of the underlying multiple-input-multiple-output system. We show that over quadrature-amplitude modulation and pulse-amplitude modulation, our LCP achieves the upper bound on the coding gain of all linear precoders for certain values of Nt and comes close to this upper bound for other values of Nt, in both correlated and independent fading channels. Compared with existing ST block codes adhering to an orthogonal design (ST-OD), ST-LCP offers not only better performance, but also higher mutual information for Nt > 2. For decoding ST-LCP, we adopt the near-optimum sphere-decoding algorithm, as well as reduced-complexity sub-optimum alternatives. Although ST-OD codes afford simpler decoding, the tradeoff between performance and rate versus complexity favors the ST-LCP codes when Nt, Nr, or the spectral efficiency of the system increase. Simulations corroborate our theoretical findings.

AB - We present a unified approach to designing space-time (ST) block codes using linear constellation precoding (LCP). Our designs are based either on parameterizations of unitary matrices, or on algebraic number-theoretic constructions. With an arbitrary number of Nt transmit- and N r receive-antennas, ST-LCP achieves rate 1 symbol/s/Hz and enjoys diversity gain as high as NtNr over (possibly correlated) quasi-static and fast fading channels. As figures of merit, we use diversity and coding gains, as well as mutual information of the underlying multiple-input-multiple-output system. We show that over quadrature-amplitude modulation and pulse-amplitude modulation, our LCP achieves the upper bound on the coding gain of all linear precoders for certain values of Nt and comes close to this upper bound for other values of Nt, in both correlated and independent fading channels. Compared with existing ST block codes adhering to an orthogonal design (ST-OD), ST-LCP offers not only better performance, but also higher mutual information for Nt > 2. For decoding ST-LCP, we adopt the near-optimum sphere-decoding algorithm, as well as reduced-complexity sub-optimum alternatives. Although ST-OD codes afford simpler decoding, the tradeoff between performance and rate versus complexity favors the ST-LCP codes when Nt, Nr, or the spectral efficiency of the system increase. Simulations corroborate our theoretical findings.

KW - Diversity

KW - Multiantenna

KW - Rotated constellations

KW - Space-time (ST) codes

KW - Wireless communication

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Space-time diversity systems based on linear constellation precoding

Abstract

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