Please use this identifier to cite or link to this item: https://dspace.ncfu.ru/handle/20.500.12258/23494
Title: A novel QCA circuit-switched network with power dissipation analysis for nano communication applications
Authors: Lyakhov, P. A.
Ляхов, П. А.
Keywords: Receiver;Transmitter;1:2 DMUX;2:1 MUX;Circuit-switched network;Coplanar circuits;Crossbar switch;Quantum-dot cellular automata
Issue Date: 2023
Citation: Vahabi, M., Rahimi, E., Lyakhov, P., Otsuki, A. A novel QCA circuit-switched network with power dissipation analysis for nano communication applications // Nano Communication Networks. - 2023. - 35, art. no. 100438. - DOI: 10.1016/j.nancom.2023.100438
Series/Report no.: Nano Communication Networks
Abstract: Today, communication links and networks are essential in transmitting data and information. Moreover, information sharing in communication devices and networks has become necessary, routine, and unavoidable. Consequently, designing and manufacturing high-speed nano-scale devices with ultra-low power consumption is very important. Among the emerging paradigms in nanotechnologies, quantum-dot cellular automata (QCA) is very popular in communication sciences. In the present study, we optimize the design and implementation of a QCA crossbar switch and use it in transmitter and receiver circuits. Subsequently, a circuit-switched network in QCA technology is implemented using these devices. All the designed circuits are coplanar with the minimum number of cells, optimal area and latency, and low power consumptions, which employ standard QCA design rules and show superiority and advantages compared to the previous designs.
URI: http://hdl.handle.net/20.500.12258/23494
Appears in Collections:Статьи, проиндексированные в SCOPUS, WOS

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