The development of cascode low noise amplifier with double feedback technique architecture for wireless application

This study aims to develop cascode low noise amplifier that operate at 5.8 GHz bymaximizing gain and minimize the noise figure for the topic of Development ofCascode Low Noise Amplifier by using Double Feedback Te...

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Main Author:	Nurul Husna Abdul Kahar
Format:	thesis
Language:	eng
Published:	2021
Subjects:	Q Science
Online Access:	https://ir.upsi.edu.my/detailsg.php?det=7189
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institution	Universiti Pendidikan Sultan Idris
collection	UPSI Digital Repository
language	eng
topic	Q Science
spellingShingle	Q Science Nurul Husna Abdul Kahar The development of cascode low noise amplifier with double feedback technique architecture for wireless application
description	<p>This study aims to develop cascode low noise amplifier that operate at 5.8 GHz by</p><p>maximizing gain and minimize the noise figure for the topic of Development of</p><p>Cascode Low Noise Amplifier by using Double Feedback Technique Architecture for</p><p>Wireless Application. To verify the idea, FHX76LP Super Low Noise HEMT which</p><p>compliant with wireless application especially long-term evolution (LTE) standard</p><p>manage to outlines the possibility to improves the design of low noise amplifier within</p><p>parameters of gain, noise figure, bandwidth, sensitivity, stability, power consumption</p><p>and complexity. The cascode low noise amplifier used T-matching network for inputoutput</p><p>impedance matching and implementation an innovative double feedback</p><p>technique to compliant with circuit design. The study using the Advance Design System</p><p>(ADS) software in aid for collecting the data in smith chart and s-parameter that</p><p>practical tool used in designing and simulating the circuit and data. Based on</p><p>simulation, the approach compliant with gain (S21) of 20.887 dB with noise figure of</p><p>0.341 dB. The input return loss (S11) and output return loss (S22) are - 14.354 dB and</p><p>- 11.879 dB respectively. In conclusion, the outcome for this topic is good based on</p><p>comparison simulation with other circuit method. Implications, the use of this study</p><p>will contribute in providing a better wireless signal receiver especially for the LTE</p><p>standard and it potentially in addressing wireless communication issues in rural areas.</p>
format	thesis
qualification_name
qualification_level	Master's degree
author	Nurul Husna Abdul Kahar
author_facet	Nurul Husna Abdul Kahar
author_sort	Nurul Husna Abdul Kahar
title	The development of cascode low noise amplifier with double feedback technique architecture for wireless application
title_short	The development of cascode low noise amplifier with double feedback technique architecture for wireless application
title_full	The development of cascode low noise amplifier with double feedback technique architecture for wireless application
title_fullStr	The development of cascode low noise amplifier with double feedback technique architecture for wireless application
title_full_unstemmed	The development of cascode low noise amplifier with double feedback technique architecture for wireless application
title_sort	development of cascode low noise amplifier with double feedback technique architecture for wireless application
granting_institution	Universiti Pendidikan Sultan Idris
granting_department	Fakulti Teknikal dan Vokasional
publishDate	2021
url	https://ir.upsi.edu.my/detailsg.php?det=7189
_version_	1747833365003763712
spelling	oai:ir.upsi.edu.my:71892022-06-20 The development of cascode low noise amplifier with double feedback technique architecture for wireless application 2021 Nurul Husna Abdul Kahar Q Science <p>This study aims to develop cascode low noise amplifier that operate at 5.8 GHz by</p><p>maximizing gain and minimize the noise figure for the topic of Development of</p><p>Cascode Low Noise Amplifier by using Double Feedback Technique Architecture for</p><p>Wireless Application. To verify the idea, FHX76LP Super Low Noise HEMT which</p><p>compliant with wireless application especially long-term evolution (LTE) standard</p><p>manage to outlines the possibility to improves the design of low noise amplifier within</p><p>parameters of gain, noise figure, bandwidth, sensitivity, stability, power consumption</p><p>and complexity. The cascode low noise amplifier used T-matching network for inputoutput</p><p>impedance matching and implementation an innovative double feedback</p><p>technique to compliant with circuit design. The study using the Advance Design System</p><p>(ADS) software in aid for collecting the data in smith chart and s-parameter that</p><p>practical tool used in designing and simulating the circuit and data. Based on</p><p>simulation, the approach compliant with gain (S21) of 20.887 dB with noise figure of</p><p>0.341 dB. The input return loss (S11) and output return loss (S22) are - 14.354 dB and</p><p>- 11.879 dB respectively. In conclusion, the outcome for this topic is good based on</p><p>comparison simulation with other circuit method. Implications, the use of this study</p><p>will contribute in providing a better wireless signal receiver especially for the LTE</p><p>standard and it potentially in addressing wireless communication issues in rural areas.</p> 2021 thesis https://ir.upsi.edu.my/detailsg.php?det=7189 https://ir.upsi.edu.my/detailsg.php?det=7189 text eng closedAccess Masters Universiti Pendidikan Sultan Idris Fakulti Teknikal dan Vokasional <p>A. B. Ibrahim, & A. Z. M. Ali. (2016). Simulation of Single Stage LNA Based on Ladder</p><p>Matching Networks for WiMAX Application. International Journal of Information</p><p>and Electronics Engineering, 6(3), 161165.</p><p></p><p>A. B. Ibrahim, H. F. Hanafi, F. H. Yahya & N. H. A. Kahar. (2019). Low Noise Amplifier</p><p>for LTE Application Using High-Performance Low Noise Pseudomorphic High</p><p>Electron Mobility Transistor (PHEMT). International Journal of Advanced Science</p><p>and Technology, 28(8), 806 811.</p><p></p><p>A.B. Ibrahim, M. N. Husain, A. R. 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The development of cascode low noise amplifier with double feedback technique architecture for wireless application

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