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The internet of Bio-Nano things
TLDR
The IoBNT stands as a paradigm-shifting concept for communication and network engineering, where novel challenges are faced to develop efficient and safe techniques for the exchange of information, interaction, and networking within the biochemical domain, while enabling an interface to the electrical domain of the Internet.
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A physical end-to-end model for molecular communication in nanonetworks
TLDR
A new physical end-to-end (including the channel) model for molecular communication is introduced, which is related to a specific process involving particle exchanges, namely, particle emission, particle diffusion and particle reception.
View on IEEE
Detection Techniques for Diffusion-based Molecular Communication
TLDR
This work considers a scenario of Diffusion-based Molecular Communication (DMC), a promising paradigm that has been recently proposed to implement nanonetworks, and two techniques for the detection of the molecular pulses, namely, amplitude detection and energy detection, are compared.
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Noise Analysis in Ligand-Binding Reception for Molecular Communication in Nanonetworks
TLDR
The objective of this paper is to provide a mathematical study of the noise at the reception of the molecular information in a diffusion-based MC system when the ligand-binding reception is employed, andumerical results are provided to demonstrate that the analytical formulation of the reception noise in terms of stochastic chemical kinetics is compliant with the reception Noise behavior resulting from the lig and-receptor kinetics simulations.
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Diffusion-Based Noise Analysis for Molecular Communication in Nanonetworks
TLDR
The objective of this paper is the analysis of the noise sources in diffusion-based MC using tools from signal processing, statistics and communication engineering to evaluate the capability of the stochastic model to express the diffusion- based noise sources represented by the physical model.
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Capacity of a Diffusion-Based Molecular Communication System With Channel Memory and Molecular Noise
TLDR
A closed-form expression for the information capacity of an MC system based on the free diffusion of molecules, which is of primary importance to understand the performance of the MC paradigm.
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A routing framework for energy harvesting wireless nanosensor networks in the Terahertz Band
TLDR
A routing framework for WNSNs is proposed to optimize the use of the harvested energy to guarantee the perpetual operation of the WNSN while, at the same time, increasing the overall network throughput.
View on Springer
A Molecular Communication System Model for Particulate Drug Delivery Systems
TLDR
The study of novel optimization techniques for a more effective and less invasive drug delivery will be aided by this model, while paving the way for novel communication techniques for Intrabody communication networks.
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Diffusion-based physical channel identification in molecular nanonetworks
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A Statistical–Physical Model of Interference in Diffusion-Based Molecular Nanonetworks
TLDR
Numerical results in terms of received PSD probability distribution and probability of interference are presented to compare the proposed statistical-physical model with the outcomes of simulations.
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