Microchannel molecular communication with nanoscale carriers: Brownian motion versus active transport

In molecular communication, information is encoded and transmitted as a pattern of molecules or other very small information carriers (in this paper, vesicles are used). Nanoscale techniques, such as molecular motors or Brownian motion, are used to convey the vesicles from the transmitter to the receiver, where the transmitted message is deciphered. In this paper, the microchannel environment is considered, and the achievable information rates are compared between the use of Brownian motion and molecular motors, which are evaluated through simulation. Communication is viewed as a mass transfer problem, where messages are sent by transporting a number of vesicles from transmitter to receiver. Results are provided which suggest that active transport is best when the available number of vesicles is small, and Brownian motion is best when the number of vesicles is large.