Your search keyword '"Full channel state information"' showing total 2 results

1. Extension of the MIMO Precoder Based on the Minimum Euclidean Distance: A Cross-Form Matrix.

Author

Vrigneau, B., Letessier, J., Rostaing, P., Collin, L., and Burel, G.

Abstract

Under full channel state information at the transmitter side (Tx-CSI), MIMO precoders can be designed by the optimization of many pertinent criteria, like, for example, the maximizing post-processing signal-to-noise ratio (max-SNR or beamforming solution), or the minimizing weighted mean square error between transmit and receive vector-symbols (W-MMSE solution). These solutions decouple the MIMO channel into b parallel independent datastreams. This diagonal structure reduces the complexity of the maximum likelihood (ML) decisions but the diversity order of these schemes is limited. Recently, we proposed a precoder, max-dmjn solution, which optimizes the exact expression of the minimum Euclidean distance and leads to a non diagonal structure allowing to achieve maximum diversity order. However, the result is available only for two transmit datastreams (6 = 2) and BPSK and QPSK modulations. In this paper, we propose a heuristic method to deal with the case b > 2, which provides a suboptimal, but good solution to this general problem. The new precoder, Equal-dm;n (E-dmin), is based on a non diagonal cross-form structure. It significantly enhances the transmit diversity in the eigen-subchannels. We demonstrate that the achieved diversity order is greater than that of precoders with diagonal structure for the same number of datastreams despite a tradeoff between rate and diversity. This design can also ensure quality of service (QoS) by using an adapted power allocation strategy. Performance comparisons show the BER improvement for MIMO and MIMO-OFDM systems. [ABSTRACT FROM PUBLISHER]

Published

2008

2. Optimum power control for transmitter cooperation in OFDMA based wireless networks

Author

Sezi Bakim, Onur Kaya, Işık Üniversitesi, Mühendislik Fakültesi, Elektrik-Elektronik Mühendisliği Bölümü, Işık University, Faculty of Engineering, Department of Electrical-Electronics Engineering, Bakım, İsmail Sezi, and Kaya, Onur

Subjects

Transmitter cooperation, Orthogonal frequency-division multiplexing, Computer science, Iterative methods, Cooperative OFDMA system, Orthogonal frequency-division multiple access, Decoding, OFDM modulation, Optimal power distribution, Fading channels, Subgradient algorithm, Radio transmitters, Subcarrier, Block Markov superposition encoding, Telecommunications link, Wireless networks, Cooperative communication, Channel code, Wireless network, Resource management, Markov processes, Transmitter, Rate region boundary, Full channel state information, Vectors, Channel coding, Block codes, Frequency division multiple access, Optimal control, Power control, Decoding methods, Uplink, Block code, Mathematical optimization, Optimum power control, Inter-subchannel cooperative encoding, Data_CODINGANDINFORMATIONTHEORY, Radio networks, Fading, Computer Science::Information Theory, Optimal power allocation policy, Frequency-division multiple access, Resource-allocation, Telecommunication control, Systems, Cooperative orthogonal frequency division multiple access system, Transmitters, Iterative waterfilling-like algorithm, Channel state information, Encoding

Abstract

For a cooperative orthogonal frequency division multiple access (OFDMA) system with two transmitters (TXs), and full channel state information (CSI), we obtain the optimal power allocation (PA) policies which maximize the rate region achievable by a recently introduced version of block Markov superposition encoding (BMSE): inter-subchannel cooperative encoding (ISCE) [1]. We provide the optimality conditions that need to be satisfied by the powers associated with the transmitted codewords. We propose two algorithms that yield the optimal power distribution: a subgradient algorithm which achieves an arbitrary rate point on the achievable rate region boundary, and an iterative waterfilling-like algorithm which maximizes the sum rate, and converges much faster. We observe that, utilization of power control to take advantage of the diversity offered by the cooperative OFDMA system, not only leads to a remarkable improvement in achievable rates, but also may help determine how the subchannels have to be instantaneously allocated to various tasks in cooperation. Publisher's Version

Published

2011