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A systems-theoretic model of a biological circuit for molecular communication in nanonetworksPIEROBON, Massimiliano.Nano communication networks (Print). 2014, Vol 5, Num 1-2, pp 25-34, issn 1878-7789, 10 p.Article

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Molecular communication via microtubules and physical contact in nanonetworks: A surveyDARCHINI, Kamal; ALFA, Attahiru S.Nano communication networks (Print). 2013, Num 2, pp 73-85, issn 1878-7789, 13 p.Article

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Rate-Delay Tradeoff With Network Coding in Molecular NanonetworksUNLUTURK, Bige D; MALAK, Derya; AKAN, Ozgur B et al.IEEE transactions on nanotechnology. 2013, Vol 12, Num 2, pp 120-128, issn 1536-125X, 9 p.Article

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Coverage and throughput analysis for FRET-based mobile molecular sensor/actor nanonetworksKUSCU, Murat; AKAN, Ozgur B.Nano communication networks (Print). 2014, Vol 5, Num 1-2, pp 45-53, issn 1878-7789, 9 p.Article

End-to-End Propagation Noise and Memory Analysis for Molecular Communication over Microfluidic ChannelsBICEN, A. Ozan; AKYILDIZ, Ian F.IEEE transactions on communications. 2014, Vol 62, Num 7, pp 2432-2443, issn 0090-6778, 12 p.Article

A Service-Oriented Architecture for Body Area NanoNetworks with Neuron-based Molecular CommunicationSUZUKI, Junichi; BALASUBRAMANIAM, Sasitharan; PAUTOT, Sophie et al.Journal on special topics in mobile networks and applications. 2014, Vol 19, Num 6, pp 707-717, issn 1383-469X, 11 p.Conference Paper

Channel Model and Capacity Analysis of Molecular Communication with Brownian MotionNAKANO, Tadashi; OKAIE, Yutaka; LIU, Jian-Qin et al.IEEE communications letters. 2012, Vol 16, Num 6, pp 797-800, issn 1089-7798, 4 p.Article

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DIRECT: A model for molecular communication nanonetworks based on discrete entitiesDEMIRAY, Deniz; CABELLOS-APARICIO, Albert; ALARCON, Eduard et al.Nano communication networks (Print). 2013, Vol 4, Num 4, pp 181-188, issn 1878-7789, 8 p.Article

Molecular Communication in Fluid Media: The Additive Inverse Gaussian Noise ChannelSRINIVAS, K. V; ECKFORD, Andrew W; ADVE, Raviraj S et al.IEEE transactions on information theory. 2012, Vol 58, Num 7, pp 4678-4692, issn 0018-9448, 15 p.Article

Diffusion-Based Noise Analysis for Molecular Communication in NanonetworksPIEROBON, Massimiliano; AKYILDIZ, Ian F.IEEE transactions on signal processing. 2011, Vol 59, Num 6, pp 2532-2547, issn 1053-587X, 16 p.Article

Cooperative signal amplification for molecular communication in nanonetworksABADAL, Sergi; LLATSER, Ignacio; ALARCON, Eduard et al.Wireless networks. 2014, Vol 20, Num 6, pp 1611-1626, issn 1022-0038, 16 p.Article

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Communications and Switching in Microfluidic Systems: Pure Hydrodynamic Control for Networking Labs-on-a-ChipDE LEO, E; DONVITO, L; GALLUCCIO, L et al.IEEE transactions on communications. 2013, Vol 61, Num 11, pp 4663-4677, issn 0090-6778, 15 p.Article

Design and Analysis of Wireless Communication Systems Using Diffusion-Based Molecular Communication Among BacteriaEINOLGHOZATI, Arash; SARDARI, Mohsen; FEKRI, Faramarz et al.IEEE transactions on wireless communications. 2013, Vol 12, Num 12, pp 6096-6105, issn 1536-1276, 10 p.Article

Physical channel characterization for medium-range nanonetworks using flagellated bacteriaGREGORI, Maria; LLATSER, Ignacio; CABELLOS-APARICIO, Albert et al.Computer networks (1999). 2011, Vol 55, Num 3, pp 779-791, issn 1389-1286, 13 p.Article

A survey on bio-inspired networkingDRESSLER, Falko; AKAN, Ozgur B.Computer networks (1999). 2010, Vol 54, Num 6, pp 881-900, issn 1389-1286, 20 p.Article

Molecular communication options for long range nanonetworksPARCERISA GINE, Lluis; AKYILDIZ, Ian F.Computer networks (1999). 2009, Vol 53, Num 16, pp 2753-2766, issn 1389-1286, 14 p.Article

Optimal Transmission Probability in Binary Molecular CommunicationATAKAN, Baris.IEEE communications letters. 2013, Vol 17, Num 6, pp 1152-1155, issn 1089-7798, 4 p.Article

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