Abstract
Due to the problem of inter-channel interference, the average bit error probability (ABEP) performance of the traditional multiple transmit and multiple receive antenna systems obviously deteriorates. A promising scheme to address this issue is the spatial modulation (SM) which activates only one transmit antenna at each signaling period. In addition, the demand to provide data services for high mobility users is ever increasing, where fading channels are more likely to be rapidly time-varying. Therefore, in this paper, we investigate the ABEP performance of SM under the assumption that system’s fading channels are Rayleigh and varying from one signaling period to another within the same transmitted data block. Further, to simplify the decoding complexity at the receiver, the channel is assumed to be estimated at the first location of each data block and then used to detect the received symbols at the remaining locations of the block. For such a system, and unlike other literature works, we derive novel, exact and closed-form reduced enough expressions for the average pairwise error probabilities (average-PEPs), which are then used to compute the system’s overall per-block ABEP efficiently. The derived expressions are generic and valid for both time-varying and slow fading environments. Furthermore, the obtained analytical results are exploited to quantitatively show that the time-varying fading environment degrades the SM system’s performance through irreducible error floors. Numerical and simulation results of various examples are provided to validate the theoretical analyses and also to get some insights into the effect of the different system parameters (such as the speed of the mobile, the carrier frequency, and the block size of the channel variations) on the overall SM error performance.
Highlights
Spatial modulation (SM) was introduced as a promising design to avoid some undesirable issues arise in conventional multiple-input-multiple-output (MIMO) transmission systems, such as the large number of transmitting radio frequency (RF) chains and the inevitable receiving interchannel-interference (ICI)
Based on the above discussion, in this paper, we aim at introducing a generic analytical study on the average bit error probability (ABEP) performance of SM systems operating over rapidly time-varying Rayleigh fading channels
NUMERICAL RESULTS numerical (using (40)) and Monte Carlo simulation results for the per-block ABEP performance of the time-varying fading SM communication system model under study are presented
Summary
Spatial modulation (SM) was introduced as a promising design to avoid some undesirable issues arise in conventional multiple-input-multiple-output (MIMO) transmission systems, such as the large number of transmitting radio frequency (RF) chains and the inevitable receiving interchannel-interference (ICI). In [30], the error performance of generalized SM systems with differential detection was studied under the effect of high terminals mobility where the first order auto-regressive (AR(1)) fading model was adopted to model the time varying system channels. Based on the above discussion, in this paper, we aim at introducing a generic analytical study on the ABEP performance of SM systems operating over rapidly time-varying Rayleigh fading channels. What makes our work differ from others is that under these considerations, we derive new, exact, and closed-form simplified enough expressions for the average pairwise error probabilities (PEPs) for the three well-known SM detection error types described in [12] These expressions have elegant features that they are generic and valid for time-varying as well as for quasi-static fading channels because they are expressed in terms of the communicating terminal relative speeds.
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