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Aashish Mathur
Researcher at Indian Institute of Technology, Jodhpur
Publications - 42
Citations - 811
Aashish Mathur is an academic researcher from Indian Institute of Technology, Jodhpur. The author has contributed to research in topics: Fading & Bit error rate. The author has an hindex of 12, co-authored 35 publications receiving 512 citations. Previous affiliations of Aashish Mathur include Birla Institute of Technology and Science & Indian Institutes of Technology.
Papers
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Physical Layer Security of Hybrid Satellite-FSO Cooperative Systems
TL;DR: The physical layer secrecy performance of a hybrid satellite and free-space optical (FSO) cooperative system is studied and it is found that with the AF with fixed gain scheme, the secrecy diversity order of the investigated system is only dependent on the channel characteristics of the FSO link and theFSO detection type, whereas the secrecy Diversity is zero when the relay node employs DF or AF with variable-gain schemes.
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On Physical Layer Security of Double Rayleigh Fading Channels for Vehicular Communications
TL;DR: The obtained results reveal the importance of taking the eavesdropper location uncertainty into consideration while designing V2V communication systems.
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Performance Evaluation of PLC Under the Combined Effect of Background and Impulsive Noises
TL;DR: The analysis presented in this letter closely predicts the behavior of the PLC system under the combined effect of background and impulsive noises.
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Comprehensive Physical Layer Security Analysis of FSO Communications Over Málaga Channels
TL;DR: The results show that when the eavesdropper is placed near the transmitter, atmospheric condition imposes a less significant impact on secrecy performance; certain level of correlation can potentially enhance the secrecy performance for FSO communications; and the correlation imposes opposite impacts on the ASC and SOP of FSOcommunications.
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PLC Performance Analysis Over Rayleigh Fading Channel Under Nakagami- $m$ Additive Noise
TL;DR: This paper provides the performance analysis of a PLC system over Rayleigh fading channel under Nakagami- $m$ distributed additive background noise assuming binary phase shift keying modulation scheme and obtains a numerically computable expression of the analytical average bit error rate.