Abstract
Sums of fading envelopes occur in several wireless communications applications. The exact mathematical solution to this statistic is, however, rather intricate. In this paper, we derive a novel closedform approximation to the sum of not necessarily identically distributed Nakagami-m random variables. The necessary parameters of the approximate solution are estimated by using the well-known expectation maximization algorithm with a Nakagami-m mixture model. The proposed approximation finds applicability in obtaining important performance metrics of communications systems where sums of variates arise. More specifically, we apply the proposed method to derive a closed-form expression for average bit error probability (ABEP) of multibranch equal-gain combining receivers. The presented models are general and can be applied to any modulation scheme. Furthermore, simplified asymptotic closed-form expressions for the ABEP have been derived to examine the achievable diversity and coding gains. Finally, the performance of the proposed approach is verified by comparing itself against both the exact evaluation and the previous results in the literature.
Highlights
Several distributions have been proposed for theorical modeling of physical fading radio channels
This paper presented a novel closed-form expression to approximate the probability density function (PDF) of the sum of independent random variables by using a Mixture Model of 2 Nakagami-m through Expectation Maximization Algorithm
We analyzed the asymptotic behavior of the average bit error probability (ABEP) at high Signal to Noise Ratio (SNR) regime, and these expressions provide a good approximation
Summary
Several distributions have been proposed for theorical modeling of physical fading radio channels. An improved approximation for the PDF of the sum of arbitrary number of independent but not identically distributed (i.n.i.d.) Nakagami-m RVs was derived in [13] via moment-based estimators. An approximation of a sum of correlated Nakagami-m random variables RVs with identical and integer fading parameters was presented in [16] to study the performance of EGC systems. The set of samples required in the EM-NMM are obtained through the Monte Carlo (MC) simulations, where the random values from the Nakagami-m distribution are computed by a pseudo-random number generator This procedure allows improving the accuracy of approximations and reduces the computational efforts in the sum of several envelopes.
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