Performance analysis of hybrid combining schemes under Middleton class‐A andimpulsive noise model
Abstract
Impulsive noise poses a significant challenge to single input multiple output wireless communication systems. This paper assesses the effectiveness of hybrid combining techniques, namely selection combining‐equal gain combining and selection combining‐maximal ratio combining, in mitigating impulsive noise impact caused by both man‐made and natural phenomena. The evaluation considers three different noise models: Additive white Gaussian noise, Middleton class‐A impulsive noise, and symmetric alpha stable impulsive noise, across Rayleigh and Rician fading channels. Bit error rate is employed to gauge channel performance. Our research contribution lies in the comprehensive assessment of hybrid combining techniques under diverse noise models, addressing a critical research gap in wireless communication. Findings indicate that impulsive noise has a more pronounced impact on channel performance than additive white Gaussian noise, and hybrid combining techniques prove more effective in mitigating these effects. The results hold significant implications for single input multiple output wireless communication systems, guiding the development of more robust and reliable communication systems in impulsive noise scenarios.
The article evaluates hybrid combining techniques (selection combining‐equal gain combining and selection combining‐maximal ratio combining) under various impulsive noise models (Middleton Class‐A, symmetric alpha stable, and additive white Gaussian noise) in both Rayleigh and Rician fading channels, using bit error rate as the metric. It highlights the significant impact of impulsive noise on channel performance and demonstrates the effectiveness of hybrid combining in mitigating it, offering practical insights for single input multiple output wireless communication systems operating in impulsive noise environments.image