CFP last date
22 April 2024
Reseach Article

Broadband Reconfigurable Low Noise Amplifierfor Multiband Application

by Bhavna Prajapati, Swapnil Jain, Braj Bihari Soni
International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
Volume 141 - Number 8
Year of Publication: 2016
Authors: Bhavna Prajapati, Swapnil Jain, Braj Bihari Soni
10.5120/ijca2016909708

Bhavna Prajapati, Swapnil Jain, Braj Bihari Soni . Broadband Reconfigurable Low Noise Amplifierfor Multiband Application. International Journal of Computer Applications. 141, 8 ( May 2016), 28-32. DOI=10.5120/ijca2016909708

@article{ 10.5120/ijca2016909708,
author = { Bhavna Prajapati, Swapnil Jain, Braj Bihari Soni },
title = { Broadband Reconfigurable Low Noise Amplifierfor Multiband Application },
journal = { International Journal of Computer Applications },
issue_date = { May 2016 },
volume = { 141 },
number = { 8 },
month = { May },
year = { 2016 },
issn = { 0975-8887 },
pages = { 28-32 },
numpages = {9},
url = { https://ijcaonline.org/archives/volume141/number8/24806-2016909708/ },
doi = { 10.5120/ijca2016909708 },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Journal Article
%1 2024-02-06T23:43:41.291082+05:30
%A Bhavna Prajapati
%A Swapnil Jain
%A Braj Bihari Soni
%T Broadband Reconfigurable Low Noise Amplifierfor Multiband Application
%J International Journal of Computer Applications
%@ 0975-8887
%V 141
%N 8
%P 28-32
%D 2016
%I Foundation of Computer Science (FCS), NY, USA
Abstract

In this paper Broadband Reconfigurable low Noise Amplifier for Multiband Application is presented. Low noise amplifier is versatile demanded in modern technology, technology demanded amplifier have less reflection and more rejection of noise, in this paper presented differential cross feedback topology and feedback technique for designing of Broadband Reconfigurable low Noise Amplifier, the requirement of integrated circuits raises significantly with increase in the number of elements in it. However, noise and reflection should be less. The noise content is based on the number of elements and routing of components and its process of fabrication. In this paper presented method to reduce noise contents with reduction of reflection. Significantly reducing noise figure (NF) to around 0.8 db, this paper present trade off between input and noise matching. The proposed LNAs achieve an NF of 0 .1–0.8 dB over a impedance bandwidth of amplifier is1GHz to10 GHz.

References
  1. Ming-Lung Lee, Chong-Yi Liou, Student Member, IEEE,”Fully Monolithic BiCMOS Reconfigurable Power Amplifier for Multi-Mode and Multi-Band Applications” IEEE transactions on microwave theory and techniques, VOL. 63, NO. 2, February 2015 pp 613-624
  2. Çağri Ulusoy, Member, “A SiGe D-Band Low-Noise Amplifier Utilizing Gain-Boosting Technique” IEEE Microwave And Wireless Components Letters, VOL. 25, NO. 1, January 2015 pp 61-66
  3. Jongwon Lee, Jooseok Lee, and Kyounghoon Yang, Senior Member, IEEE “Reflection-Type RTD Low-Power Amplifier With Deep Sub-mW DC Power Consumption” IEEE Microwave And Wireless Components Letters, VOL. 24, NO. 8, August 2014 pp 551-553
  4. V. Giannini, P. Nuzzo, et.al Dec. 2009. “A 2 mm 0.1-to-5 GHz SDR receiver in 45 nm digital CMOS,” IEEE J. Solid-State Circuits, vol. 44, no. 12, pp. 3486–3498,
  5. R. van de Beek.et.al, Feb. 2008 “A 0.6-to-10 GHz receiver front-end in 45 nm CMOS,” in IEEE Int. Solid-State Circuits Conf. Tech. Dig., , pp. 128–129.
  6. B. G. Perumana,et.al. May 2008. “Resistive-feedback CMOS low-noise amplifiers for multiband applications,” IEEE Trans. Microw. Theory Techn., vol. 56, no. 5, pp.1218–1225.
  7. M. T. Reiha and J. R. Long, May 2007. “A1.2Vreactive-feedback 3.1–10.6 GHz low-noise amplifier in 0.13 m CMOS,” IEEE J. Solid-State Circuits, vol. 42, no. 5, pp. 1023–1033.
  8. R.-M. Weng, C.-Y. Liu, et.al, Aug. 2010. “A low-power full-band lownoise amplifier for ultra-wideband receivers,” IEEE Trans. Microw.Theory Techn., vol. 58, no. 8, pp. 2077–2083.
  9. J.-F. Chang.et.al, May 2011. “0.99 mW 3–10 GHz common-gate CMOS UWB LNA using T-match input network and self-body-bias technique,” Electron. Lett., vol. 47, no. 11, pp. 658–659.
  10. B. Park, S. Choi, Jan. 2010., “A low-noise amplifier with tunable interference rejection for 3.1- to 10.6-GHz UWB systems,” IEEE Microw. Wireless Compon. Lett., vol. 20, no. 1, pp. 40–42.
  11. K.-H. Chen, J.-H. Lu, et.al, Mar. 2007. “An ultra-wide-band 0.4–10-GHz LNA in 0.18- m CMOS,” IEEE Trans. Circuits Syst. II,Exp. Briefs, vol. 54, no. 3, pp. 217–221.
  12. Y.-T. Lo and J.-F. Kiang, Sep. 2011. “Design ofwideband LNAs using parallel-to series resonant matching network between common-gate and common source stages,” IEEE Trans. Microw. Theory Techn., vol. 59, no. 9, pp.2285–2294.
  13. D. Pepe and D. Zito, Sep. 2009. “22.7-dB gain 19.7-dBm UWB CMOS LNA,” IEEE Trans. Circuits Syst. Exp. Briefs, vol. 56
Index Terms

Computer Science
Information Sciences

Keywords

Differential cross feedback topology feedback topology S11 Impedance bandwidth