International Journal of Microelectronics and Digital Integrated Circuits

Nano fabrication efficacy has been efficient features to the system of Bluetooth low energy (BLE) from assigned overcome from discrete-time (DT) superheterodyne receiver (RX). Additional characteristic of DT-RX system is for applicability to internet-of-things (IoT), commercial Bluetooth and 2G cellular radios, while alternative to software-defined radio applicability. Implicative produce has furnished evolve of programmable capacitor for switched-capacitor (SC) structure. Program has added to flex digitally intensive scriptive system, which has reduced sensitivity to some variables such as voltage, and temperature variation. Large surface-to-volume ratios, high carrier mobility, low power consumption and compatible integrant to electronics has reticulated nanoelectronic devices by nanomaterials, given by, configurative nanowire, carbon nanotube, graphene and transition metal dichalcogenide. Adoptive studies are beneficial for various sensor designations applicable to liquid and gas phase detectability. Ethical sensory act has classed usual as direct current (DC) sense, impedance sense, noise sense and descriptive issued wave mix add an addendum of heterodyne towards superhetrodyne sense. In other words, latter has been signal between conductive modulated score as well alternating current (AC) excitation in electronic sense owing to gain in convened devised two-terminus.

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Sandro Binsfeld Ferreira, Feng-Wei Kuo, Masoud Babaie, et, al. System Design of a 2.75-mW Discrete-Time Superheterodyne Receiver for Bluetooth Low Energy; IEEE Transactions on Microwave Theory & Techniques. May 2017; 65(5): 1904-1913.

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Djilali Hammou, Mourad Nedil, and Serioja O. Tatu: New Implementation of Mm-Wave Heterodyne Receiver Based on Six-Port Technology: Circuit Characterization and High Data-Rate Demodulation Results; Progress in Electromagnetics Research C. 2016; 65: 139–151.

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