Adjustable Radio Technology Using BPSK Modulation
Keywords:
RF Power Gating, MSK, BPSK, Phase detectionAbstract
This research paper proposes a technique called a radio gating, called an RF gating, which consists of a symbolic change of the active time radio (ATR) on the RF foreground. This technique is particularly suitable for adapting the receiver's energy consumption to performance requirements without changing its architecture. In the specific case of binary turn-key signalling, the effect of this method on the Bit Error Rate (BER) performance is studied (BPSK).In existing it Minimum shift keying signalling will used in RF Power gating technique, it will have, low efficiency, and more bit error rate. In this paper to modified the Minimum shift keying technique to Binary shift keying technique. Finally this work is implemented in VHDL, and synthesized with Xilinx FPGA Vertex-5, and shown the area, power and delay variations.
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M.Raveendranad, Mr. D.M.K. Chaitanya M Tech (VLSI ,M.E. (Ph.d), M.B.A, Associate Professor &Head,Dept. of ECE Avanthi Institute of Engineering & technology, Hyderabad. “An Architecture Design of Novel Mobile Jammer using FPGA”ISSN-2321 -3361 © 2014 IJESC.
SeongahJeong, Keonkook Lee, Heon Huh, and Joonhyuk Kang Secure “Transmission in Downlink Cellular Network with a Cooperative Jammer” IEEE wireless communications letters, vol. 2, no. 4, august 2013.
Juan Pablo Martinez Brito, Sergio Bampi PGMICRO – Graduate Program on Microelectronics Federal University of Rio Grande do Sul, UFRGS “Design of a Digital FM Demodulator based on a 2ndº Order All-Digital Phase-Locked Loop”
Bluetooth Specification, Core Package v4.0, Bluetooth-SIG, Kirkland, WA, USA, Jun. 2010.
N. M. Pletcher, S. Gambini, and J. Rabaey, “A 52 ?W wake-up receiver with ?72 dBm sensitivity using an uncertain-IF architecture,” IEEE J. Solid-State Circuits, vol. 44, no. 1, pp. 269–280, Jan. 2009.
X. Huang, S. Rampu, X. Wang, G. Dolmans, and H. de Groot, “A 2.4 GHz/915 MHz 51 ?W wake-up receiver with offset and noise suppression,” in IEEE Int. Solid-State Circuits Conf. Dig. Tech. Papers (ISSCC), Feb. 2010, pp. 222–223.
A. Didioui, “Energy-aware transceiver for energy harvesting wireless sensor networks,” Ph.D. dissertation, Dept. Signal Image Process., Univ. Rennes 1, Rennes, France, 2014.
K. Ghosal, T. Anand, V. Chaturvedi, and B. Amrutur, “A power-scalable RF CMOS receiver for 2.4 GHz wireless sensor network applications,” in Proc. 19th IEEE Int. Conf. Electron., Circuits, Syst. (ICECS), Dec. 2012, pp. 161–164.
A. Didioui, C. Bernier, L. Q. V. Tran, O. Sentieys, and A. Didioui, “EnvAdapt: An energy-aware simulation framework for power-scalable transceivers for wireless sensor networks,” in Proc. 20th Eur. Wireless Conf., May 2014, pp. 1–6.
M. Kubisch, H. Karl, A. Wolisz, L. C. Zhong, and J. Rabaey, “Distributed algorithms for transmission power control in wireless sensor networks,” in Proc. IEEE Wireless Commun. Netw. (WCNC), vol. 1. Mar. 2003, pp. 558–563.
J. Porter et al., “Wireless sensor networks for ecology,” BioScience, vol. 55, no. 7, pp. 561–572, 2005.
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