Department of Electrical and Electronics Engineering
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Item Outage Probability Analysis for UOWC System Over Oceanic Turbulence With Pointing Errors(IEEE, 2023-09) Zafaruddin, S.M.This letter proposes a combined underwater optical wireless communication (UOWC) system consisting of maximum ratio combining (MRC)-based direct link and optical intelligent reflecting surface (OIRS)-assisted indirect link. Oceanic turbulence is modeled by the mixture exponential–generalized gamma (EGG) distribution. We evaluate the system performance using the outage probability. An exact outage probability expression is derived for these links under EGG oceanic turbulence and pointing errors (PEs). Moreover, we derive the asymptotic expression for the outage probability to present an analytical expression of the system’s diversity order. We demonstrate that the Monte Carlo simulation results perfectly match the derived expressions, and closely align with the asymptotic expression at high signal-to-noise ratio (SNR) values. Hence, the proposed system ameliorates the connectivity of the high-speed UOWC under different underwater channel conditions.Item Exact Performance Analysis for Multi-Aperture UWOC Systems Over EGG Oceanic Turbulence(IEEE, 2024) Zafaruddin, S.M.A research gap exists in analyzing the exact performance of wireless systems that employ selection combining diversity technique with Meijer-GlFox-H function representation for signal fading. In this paper, we develop a general framework to analyze the exact performance of wireless systems that employ the Meijer-G function with integer exponents for statistical characterization. We derive exact analytical expressions for the average bit-error rate (BER) for multi-aperture underwater wireless optical communication (UWOC) system operating over exponential-generalized gamma (EGG) oceanic turbulence combined with pointing errors. We also develop asymptotic expressions at a high signal-to-noise (SNR) to capture insights into the system's performance. Our simulation findings confirm the accuracy of our analytical expressions and illustrate that the exact expression may provide a better estimate for the efficient deployment of UWOC.Item Meijer-G Function With Continued Product and Integer Exponent: Performance of Multi-Aperture UOWC System Over EGG Turbulence(IEEE, 2024) Zafaruddin, S.M.; Bandyopadhyay, Jayendra N.Signal transmission over underwater optical wireless communication (UOWC) experiences the combined effect of oceanic turbulence and pointing errors statistically modeled using the sum of two Meijer-G functions. There is a research gap in the exact statistical analysis of multi-aperture UOWC systems that use selection combining diversity techniques to enhance performance compared to single-aperture systems. In this paper, we develop a general framework for the continued product and positive integer exponent for the sum of Meijer-G functions to analyze the exact statistical performance of the UOWC system in terms of multivariate Fox-H function for both independent and non-identically distributed (i.ni.d.) and independent and identically distributed (i.i.d.) channels. We also approximate the performance of a multi-aperture UOWC system with i.i.d. channels using the single-variate Fox-H function. Using the generalized approach, we present analytical expressions for average bit-error rate (BER) and ergodic capacity for the considered system operating over exponential–generalized gamma (EGG) oceanic turbulence combined with zero-boresight pointing errors. We also develop asymptotic expressions for the average BER at a high signal-to-noise (SNR) to capture insights into the system's performance. Our simulation findings confirm the accuracy of our derived expressions and illustrate the impact of turbulence parameters for i.ni.d. and i.i.d. models for the average BER and ergodic capacity, which may provide a better estimate for the efficient deployment of UOWC.