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Channel Characterization and Performance of a 3-D Molecular Communication System with Multiple Fully-Absorbing Receivers

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arxiv 2112.09549 v2 pith:WAFNQTLA submitted 2021-12-17 cs.IT math.IT

Channel Characterization and Performance of a 3-D Molecular Communication System with Multiple Fully-Absorbing Receivers

classification cs.IT math.IT
keywords systemchannelcommunicationfarsmultipleanalyticaldifferentmodel
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Molecular communication (MC) can enable the transfer of information between nanomachines using molecules as the information carrier. In MC systems, multiple receiver nanomachines often co-exist in the same communication channel to serve common or different purposes. However, the analytical channel model for a system with multiple fully absorbing receivers (FARs) does not exist in the literature, which is significantly different from the single FAR system due to the mutual influence of FARs. The analytical channel model is essential in analyzing systems with multiple FARs, including MIMO, SIMO, and cognitive molecular communication systems. In this work, we derive an approximate analytical expression for the hitting probability of a molecule emitted from a point source on each FAR on a diffusion-based MC system with three or more FARs. Using these expressions, we derive the channel model for a SIMO system with a single transmitter and multiple FARs arranged in a uniform circular array (UCA). We then analyze the communication performance of this SIMO system under different cooperative receiver schemes and develop several interesting insights.

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