Wireless multiuser communication systems: diversity receiver performance analysis, GSMuD design, and fading channel simulator

In this paper, novel mathematical approach for evaluation of probability density function (PDF) of instantaneous signal-to-interference ratio (SIR) at the receiver output in interference-limited environment is proposed. Dual-branch selection combining (SC) receiver operating over correlated Weibull fading channels applying SIR algorithm is considered. Analytical expression for joint PDF of desired signal and interference at the receiver output is derived and used for evaluation of PDF of instantaneous SIR. The expression for PDF of SIR is used for system performance analysis via outage probability, average bit error probability (ABEP) and average output SIR as system performance measures. Numerical results are graphically presented showing the effects of fading severity, average SIR at the input and level of correlation on the diversity receiver performance. In addition, results obtained for the PDF of instantaneous SIR in this paper, are compared to the results when the PDF of instantaneous SIR is directly calculated.

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FPGA Implementation of a Nakagami-m fading channel Simulator using Random Number Generator

Indonesian Journal of Electrical Engineering and Computer Science ◽

10.11591/ijeecs.v4.i1.pp133-140 ◽

2016 ◽

Vol 4 (1) ◽

pp. 133

Author(s):

Santhosh Kumar B ◽

K. Ayyappa Swamy

Keyword(s):

Fading Channels ◽

Fading Channel ◽

Random Number ◽

Random Number Generator ◽

Rician Fading ◽

Size Parameter ◽

Rician Fading Channel ◽

Signal Fading ◽

Fading Channel Simulator ◽

Channel Simulator

<p class="abstract">By realizing the concept of implementation of the radio propagation channels on simulators is the eminent intention of this work. Even though prototyping software simulators are effortless to design we prefer hardware simulators as they endeavors distinguishable quickness, compared to earlier. Prior to this work fading channels like Gaussian, Rayleigh and Rician fading channel simulators were executed on hard ware.(i.e. FPGA) The significant target of this attempt is to implement Nakagami-m fading channel on hardware as they preserved for unsubstantial consideration. While differentiating with other fading channels Nakagami-m fading channel acquires wide spread applications, as its capability of providing appropriate fit for practical fading data, as this is flexible through its size parameter ‘m’, over which representation of signal fading conditions that vary from serious to modest, to normal fading or no fading is accomplished . The proposed hardware simulator can hatches complex Nakagami variates after it was implemented on XilinxSpartan-xc3s500e-4fg320 FPGA. This is operated at 50MHz.</p>

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An Accurate Hardware Sum-of-Cisoids Fading Channel Simulator for Isotropic and Non-Isotropic Mobile Radio Environments

Modelling and Simulation in Engineering ◽

10.1155/2012/542198 ◽

2012 ◽

Vol 2012 ◽

pp. 1-12 ◽

Cited By ~ 3

Author(s):

L. Vela-Garcia ◽

J. Vázquez Castillo ◽

R. Parra-Michel ◽

Matthias Pätzold

Keyword(s):

Fading Channel ◽

Technological Development ◽

Isotropic Scattering ◽

Approximation Technique ◽

Piecewise Polynomial Approximation ◽

Power Spectral ◽

Average Duration Of Fades ◽

Doppler Power ◽

Fading Channel Simulator ◽

Channel Simulator

The rapid technological development in the field of wireless communications calls for devices capable of reproducing and simulating the behavior of the channel under realistic propagation conditions. This paper presents a hardware fading channel simulator that is able to generate stochastic processes characterized by symmetrical and asymmetrical Doppler power spectral densities (PSDs) depending on the assumption of isotropic or non-isotropic scattering. The concept of the proposed hardware simulator is based on an implementation of the sum-of-cisoids (SOC) method. The hardware simulator is capable of handling any configuration of the cisoid's amplitudes, frequencies, and phases. Each of the cisoids that constitutes the SOC model is implemented using a piecewise polynomial approximation technique. The investigation of the higher-order statistics of the generated fading processes, like the level-crossing rate (LCR) and the average duration of fades (ADF), shows that our design is able to reproduce accurately the key features of realistic channel models that are considered as candidates for the latest wireless communication standards.

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