Fundamentals of wireless communication
Fundamentals of wireless communication
Wireless Communications & Mobile Computing
Space shift keying modulation for MIMO channels
IEEE Transactions on Wireless Communications
Trellis coded spatial modulation
IEEE Transactions on Wireless Communications
Spatial modulation with partial-CSI at the receiver: optimal detector and performance evaluation
Sarnoff'10 Proceedings of the 33rd IEEE conference on Sarnoff
IEEE Transactions on Communications
Improving the performance of space shift keying (SSK) modulation via opportunistic power allocation
IEEE Communications Letters
Multiple-antenna techniques for wireless communications - a comprehensive literature survey
IEEE Communications Surveys & Tutorials
IEEE Transactions on Wireless Communications
Using the physical layer for wireless authentication in time-variant channels
IEEE Transactions on Wireless Communications
Bivariate nakagami-m distribution with arbitrary correlation and fading parameters
IEEE Transactions on Wireless Communications - Part 2
Multiple transmit antenna differential detection from generalized orthogonal designs
IEEE Transactions on Information Theory
New bounds for the Marcum Q-function
IEEE Transactions on Information Theory
A simple transmit diversity technique for wireless communications
IEEE Journal on Selected Areas in Communications
A differential detection scheme for transmit diversity
IEEE Journal on Selected Areas in Communications
A decomposition technique for efficient generation of correlated Nakagami fading channels
IEEE Journal on Selected Areas in Communications
Spatial modulation with partial-CSI at the receiver: optimal detector and performance evaluation
Sarnoff'10 Proceedings of the 33rd IEEE conference on Sarnoff
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Space Shift Keying (SSK) modulation is a new and recently proposed transmission technology for Multiple-Input-Multiple-Output (MIMO) wireless systems, which has been shown to be a promising low-complexity alternative to several state-of-the-art MIMO schemes. So far, only optimal or heuristic transceivers with Full Channel State Information (F-CSI) at the receiver have been investigated, and their performance analyzed over fading channels. In this paper, we develop and study the performance of the optimal Maximum-Likelihood (ML) detector with unknown phase reference at the receiver (i.e., Partial-CSI, P-CSI, knowledge). A very accurate analytical framework for the analysis and optimization of this novel detector over generically correlated and non-identically distributed Nakagami-m fading channels is proposed, and its performance compared to the optimal receiver design with F-CSI. Numerical results will point out that: i) the performance of SSK modulation is significantly affected by the characteristics of fading channels, e.g., channel correlation, fading severity, and, particularly, power imbalance among the transmit-receive wireless links, and ii) unlike ordinary modulation schemes, there is a substantial performance loss when the receiver cannot exploit the phase information for optimal receiver design. This latter result highlights the importance of accurate and reliable channel estimation mechanisms for the efficient operation of SSK modulation over fading channels. Analytical frameworks and theoretical findings will also be substantiated via Monte Carlo simulations.