2018
DOI: 10.1016/j.nancom.2018.07.001
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Nano-networks communication architecture: Modeling and functions

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Cited by 44 publications
(46 citation statements)
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“…Results indicated that the designed Nano-RTD VCO device can surprisingly operate with ultra-low power consumption down to 0.16 mW and an excellent DC/AC conversion efficiency of 2.4% for oscillation frequencies around 500 GHz. The investigation confirms that the GaAs/AlAs Nano-RTD VCO device can be seen as a prospective candidate to be implemented in chip-scale THz technology, covering a broad range of functions such as feeder structure for nanoantennas, nanosensors, nanodetectors in THz wireless applications like in-body nano-communication, wireless nano-networks, and network-on-chip [2], [3], [9]. This paper is organized as follows: in Section II, we present the structure of the Nano-RTD device used to design the VCO.…”
Section: Introductionmentioning
confidence: 57%
“…Results indicated that the designed Nano-RTD VCO device can surprisingly operate with ultra-low power consumption down to 0.16 mW and an excellent DC/AC conversion efficiency of 2.4% for oscillation frequencies around 500 GHz. The investigation confirms that the GaAs/AlAs Nano-RTD VCO device can be seen as a prospective candidate to be implemented in chip-scale THz technology, covering a broad range of functions such as feeder structure for nanoantennas, nanosensors, nanodetectors in THz wireless applications like in-body nano-communication, wireless nano-networks, and network-on-chip [2], [3], [9]. This paper is organized as follows: in Section II, we present the structure of the Nano-RTD device used to design the VCO.…”
Section: Introductionmentioning
confidence: 57%
“…En el área computacional, las CM tienen un futuro prometedor, por las posibilidades de emplearlas en Internet of NanoThings (IoNT) e Internet of BioNanoThings (IoBNT), pero además porque podrían interactuar con redes convencionales y el internet de las cosas [13], [15], [27].…”
Section: Discussionunclassified
“…Laboratorio de un nanochip Medicina [13], [14], [7], [15] Monitoreo de la salud Medicina [7], [13], [16], [17], [14], [18], [19] Nanomedicina Medicina [20] Nanoredes moleculares intracorporales Medicina [21], [22], [12], [23] Ingeniería de tejidos Medicina [7], [15] Mejorar sistema inmunológico Medicina [5], [15] Entrega derigida de medicamentos Medicina [13], [14], [7], [5], [24], [3], [25], [3] Monitoreo del ambiente Ambiente [7] Control de desechos y contaminación Ambiente [7], [26], [25] Aplicaciones de manufactura Ambiente [7], [25] Soluciones industriales con nanoredes Industria [27], [28], [29], [30], [31], [32] Envío de mensaje corto Industria [33] Internet de las cosas (IoT) Industria [15], [27] Internet del Bionano Thing(IBoT) Industria [17] Modelización framacocinética Industria [34] Estimación d...…”
Section: Aplicaciones Disciplina Referenciasunclassified
“…Nanotechnology enables the design and fabrication of nano-scale electrodes and miniature electronic devices, referred to as nanomachines that can perform basic sensing, actuation and computing functionalities [14], [15], [16]. If interconnected, nanomachines form the concept of nanonetworks with significantly expanded possibilities [17], [18], [19]. In this study, we introduce the concept of multiple actuating nanomachines that inter-connect with individual cardiomyocytes, perform basic stimulation tasks by injecting current to the cytosol, and act synchronously in a form of a multi-nodal nano-actuator pacemaker network illustrated in Fig.…”
Section: Current Methods To Decrease the Pacemaker Battery Consumptiomentioning
confidence: 99%