System Modeling of Microfluidic Molecular Communication: A Markov Approach
By: Ruifeng Zheng , Pengjie Zhou , Pit Hofmann and more
Potential Business Impact:
Models tiny tubes sending messages with chemicals.
This paper presents a Markov-based system model for microfluidic molecular communication (MC) channels. By discretizing the advection-diffusion dynamics, the proposed model establishes a physically consistent state-space formulation. The transition matrix explicitly captures diffusion, advective flow, reversible binding, and flow-out effects. The resulting discrete-time formulation enables analytical characterization of both transient and equilibrium responses through a linear system representation. Numerical results verify that the proposed framework accurately reproduces channel behaviors across a wide range of flow conditions, providing a tractable basis for the design and analysis of MC systems in microfluidic environments.
Similar Papers
Three-Dimensional Channel Modeling for Molecular Communications in Tubular Environments with Heterogeneous Boundary Conditions
Information Theory
Helps tiny messages travel through tubes.
Vessel Network Topology in Molecular Communication: Insights from Experiments and Theory
Quantitative Methods
Lets tiny particles send messages inside your body.
The CAM Model: An in vivo Testbed for Molecular Communication Systems
Systems and Control
Tests tiny medicine delivery inside eggs.