Throughput and efficiency of molecular communication between nanomachines

This paper focuses on throughput and efficiency of molecular communication between a pair of sender and receiver nanomachines. In the molecular communication considered in this paper, the sender transmits molecules at a fixed rate, the molecules propagate in the environment, and the receiver captures and processes the molecules following simple enzyme kinetics. We define throughput as the average number of molecules processed by the receiver per unit time, and efficiency as the throughput divided by the number of molecules transmitted by the sender per unit time. An upper bound on throughput and efficiency at steady-state are first derived. Simulation results are then provided to show that the throughput increases as the transmission rate increases and that the efficiency has an optimal transmission rate to achieve the maximum.

[1]  Kazuhiro Oiwa,et al.  Molecular Communication: Modeling Noise Effects on Information Rate , 2009, IEEE Transactions on NanoBioscience.

[2]  Massimiliano Pierobon,et al.  A physical end-to-end model for molecular communication in nanonetworks , 2010, IEEE Journal on Selected Areas in Communications.

[3]  Jian-Qin Liu,et al.  Design and Analysis of Molecular Relay Channels: An Information Theoretic Approach , 2010, IEEE Transactions on NanoBioscience.

[4]  Özgür B. Akan,et al.  Deterministic capacity of information flow in molecular nanonetworks , 2010, Nano Commun. Networks.

[5]  Özgür B. Akan,et al.  Mobile Ad Hoc Nanonetworks with Collision-Based Molecular Communication , 2012, IEEE Transactions on Mobile Computing.

[6]  Ian F. Akyildiz,et al.  Nanonetworks: A new communication paradigm , 2008, Comput. Networks.

[7]  N. Farsad,et al.  Microchannel molecular communication with nanoscale carriers: Brownian motion versus active transport , 2010, 10th IEEE International Conference on Nanotechnology.

[8]  Andrew W. Eckford,et al.  Nanoscale Communication with Brownian Motion , 2007, 2007 41st Annual Conference on Information Sciences and Systems.

[9]  Massimiliano Pierobon,et al.  Diffusion-Based Noise Analysis for Molecular Communication in Nanonetworks , 2011, IEEE Transactions on Signal Processing.

[10]  Tatsuya Suda,et al.  Molecular communication for health care applications , 2006, Fourth Annual IEEE International Conference on Pervasive Computing and Communications Workshops (PERCOMW'06).

[11]  Özgür B. Akan,et al.  On Molecular Multiple-Access, Broadcast, and Relay Channels in Nanonetworks , 2008, BIONETICS.

[12]  Raviraj S. Adve,et al.  A Framework to Study the Molecular Communication System , 2009, 2009 Proceedings of 18th International Conference on Computer Communications and Networks.

[13]  Satoshi Hiyama,et al.  Molecular communication: Harnessing biochemical materials to engineer biomimetic communication systems , 2010, Nano Commun. Networks.

[14]  Tadashi Nakano,et al.  Repeater design and modeling for molecular communication networks , 2011, 2011 IEEE Conference on Computer Communications Workshops (INFOCOM WKSHPS).

[15]  H. T. Mouftah,et al.  On the characterization of binary concentration-encoded molecular communication in nanonetworks , 2010, Nano Commun. Networks.