Research of Diffusion-based Molecular Oscillation and Synchronization in Nanonetworks

Journal of System Simulation ›› 2015, Vol. 27 ›› Issue (9): 1960-1966.

Previous Articles Next Articles

Research of Diffusion-based Molecular Oscillation and Synchronization in Nanonetworks

Li Feiyan, Lin Lin, Ma Shiwei

School of Mechatronic Engineering and Automation, Shanghai University, Shanghai 200072, China

Received:2015-06-15 Revised:2015-07-30 Online:2015-09-08 Published:2020-08-07

Abstract

Abstract: Nanonetworks, the interconnection among nanomachines at nanoscale, is a novel kind of communication and information sharing interdisciplinary technology, and have huge potential prospects in the application of biomedical engineering, environmental monitoring, industrial production and military. Nanomachine is considered to be the basic functional unit, and clock period caused by oscillators is a prerequisite for nanomachines to work. A mathematical model was developed to describe the molecular diffusion characteristics giving the oscillation period expression by theoretical deviation. Research on oscillation and synchronization in nanonetworks is very limited so far, so the study is of great significance to the development and application of nanonetworks.

Key words: molecular communication, nanonetwork, oscillation and synchronization, oscillation period

CLC Number:

TP391.9

Li Feiyan, Lin Lin, Ma Shiwei. Research of Diffusion-based Molecular Oscillation and Synchronization in Nanonetworks[J]. Journal of System Simulation, 2015, 27(9): 1960-1966.

References

[1] I F Akyildiz, F Brunetti, C Blázquez.Nanonetworks: A new communication paradigm[J]. Comput. Netw.(S1865-0929), 2008, 52(12): 2260-2279.
[2] S Abadal, I F Akyildiz.Bio-Inspired Synchronization for Nanocommunication Networks[C]// Proc. IEEE GLOBECOM, 2011. USA: IEEE, 2011: 1-5.
[3] 黎作鹏, 张菁, 蔡绍滨, 等. 分子通信综述[J]. 通信学报, 2013, 34(5): 177-182.
[4] K B Xavier, B L Bassler.LuxS quorum sensing: more than just a numbers game.[J]. Current Opinion in Microbiology (S1369-5274), 2003, 6(2): 191-197.
[5] J D Dockery, J P Keener.A mathematical model for quorum sensing in Pseudomonas aeruginosa[J]. Bull. Math Biol.(S0092-8240), 2001, 63(1): 95-116.
[6] S Abadal, I F Akyildiz.Automata modeling of Quorum Sensing for nanocommunication networks[J]. Nano Commun. Netw.(S1878-7789), 2011, 2(1): 74-83.
[7] S Abadal, I Llatser, E Alarcón, et al. Cooperative signal amplification for molecular communication in nanonetworks[J]. Wireless Netw.(S1022-0038), 2014, 20(6): 1611-1626.
[8] A F Taylor, M R Tinsley, F Wang, et al. Dynamical quorum sensing and synchronization in large populations of chemical oscillators.[J]. Science (S0036-8075), 2009, 323(10): 614-617.
[9] D J Schwab, A Baetica, P Mehta.Dynamical quorum-sensing in oscillators coupled through an external medium[J]. Physica D (S0167-2789), 2012, 241(10): 1782-1788.
[10] D McMillen, N Kopell, J Hasty, et al. Synchronizing genetic relaxation oscillators by intercell signaling[C]// Proc. Natl. Acad. Sci. USA. 2002, 99: 679-684.
[11] J Garcia-Ojalvo, M B Elowitz, et al. Modeling a synthetic multicellular clock: repressilators coupled by quorum sensing[C]// Proc Natl Acad Sci USA. 2004, 101: 10955-10960.
[12] M J Moore, T Nakano.Oscillation and Synchronization of Molecular Machines by the Diffusion of Inhibitory Molecules[J]. IEEE Trans. Nanotechnol (S1536-125X), 2013, 12(4): 601-608.
[13] M J Moore, T Nakano.Synchronization of Inhibitory Molecular Spike Oscillators[M]// Bio-Inspired Models of Networks, Information, and Computing Systems: Germany: Springer, 2012: 183-195.
[14] I Llatser, I Pascual, N Garralda, et al. Exploring the Physical Channel of Diffusion-Based Molecular Communication by Simulation[C]// Proc. IEEE GLOBECOM, 2011. USA: IEEE, 2011: 1-5.
[15] I Llatser, E Alarcon, M Pierobony.Diffusion-based channel characterization in molecular nanonetworks[C]// Proc. INFOCOM WKSHPS, 2011. USA: IEEE, 2011: 467-472.
[16] N Garralda, I Llatser, A Cabellos-Aparicio, et al. Diffusion-based physical channel identification in molecular nanonetworks[J]. Nano Commun. Netw.(S1878-7789), 2011, 2(4): 196-204.
[17] M Pierobon, I F Akyildiz.A physical end-to-end model for molecular communication in nanonetworks[J]. IEEE Journal on Selected Areas in Communications (S0733-8716), 2010, 28(4): 602-611.

Research of Diffusion-based Molecular Oscillation and Synchronization in Nanonetworks

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 1

Recommended Articles

Metrics

Comments