Performance Investigation of Long Term Evolution- LTE- Based on OFDM Using QPSK & 64 QAM
Internet of Things and Cloud Computing
Volume 6, Issue 4, December 2018, Pages: 69-74
Received: Jan. 10, 2018; Accepted: Mar. 26, 2018; Published: Dec. 24, 2018
Views 342      Downloads 36
Authors
Jaskaran Singh, Department of Electronics and Communication Engineering, Amritsar College of Engineering & Technology, Amritsar, India
Tania Sharma, Department of Electronics and Communication Engineering, Amritsar College of Engineering & Technology, Amritsar, India
Gaurav Soni, Department of Electronics and Communication Engineering, Amritsar College of Engineering & Technology, Amritsar, India
Article Tools
Follow on us
Abstract
Long Term Evolution (LTE) based on OFDM technology is popular 3rd Generation Partnership Project that dominates the 4th generation of mobile telecommunication network. In this paper our work is unique in providing a detailed performance study based on NI VST 5644. Our performance study includes TDD and FDD operation modes for uplink and downlink transmission in physical channel, data modulation, EVM, SEM etc. In this paper LTE performance is being evaluated using VST with QPSK, QAM modulation schemes.
Keywords
TE, EVM, QAM, QPSK, VST
To cite this article
Jaskaran Singh, Tania Sharma, Gaurav Soni, Performance Investigation of Long Term Evolution- LTE- Based on OFDM Using QPSK & 64 QAM, Internet of Things and Cloud Computing. Vol. 6, No. 4, 2018, pp. 69-74. doi: 10.11648/j.iotcc.20180604.11
Copyright
Copyright © 2018 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
References
[1]
Zhaokun Qin, Lin Zhang, Ming Jiang, A dynamic subcarrier exchange scheme for SFR-aided LTE networks, Physical Communication 13 (2014) 133–141.
[2]
Sonia BenRejeb, Nidal Nasser, SamiTabbane, A novel resource allocation scheme for LTE network in the presence of mobility, Journal of Network and Computer Applications 46(2014)352–361.
[3]
Salam Doumiatia, Hassan Artaila*, David M. Gutierrez-Estevez, A framework for LTE-A Proximity-based Device-to-Device Service Registration and Discovery, Procedia Computer Science, 34 ( 2014) 87–94.
[4]
Rohit Prasad, Rajat Kathuria, The value of 1800 MHz and 2100 MHz spectrums in India and implications for auction design, Telecommunications Policy38(2014)223–235.
[5]
Rasha Alkhansaa, Hassan Artaila*, David M. Gutierrez-Estevezb, LTE-WiFi Carrier Aggregation for Future 5G Systems: A Feasibility Study and Research Challenges, Procedia Computer Science 34 ( 2014 ) 133–140.
[6]
Nora A. Ali, Mohamed A. El-Dakroury, Magdi El-Soudani, Hany M. ElSayed, Ramez M. Daoud, Hassanein H. Amer, New hybrid frequency reuse method for packet loss minimization in LTE network, Journal of Advanced Research (2014).
[7]
Mourad Abdeljebbar, Rachid El Kouch, Fast Authentication during Handover in 4G LTE/SAE Networks, IERI Procedia 10 ( 2014) 11–18.
[8]
Liljana Gavrilovska, Jaap van de Beek, Yong Xie, Erik Lidström, Janne Riihijärvi, Petri Mähönen, Vladimir Atanasovski, Daniel Denkovski, Valentin Rakovic, Enabling LTE in TVWS with radio environment maps: From an architecture design towards a system level prototype, Computer Communications 53 (2014) 62–72.
[9]
Ji-Su Kim a, Jae-Hyun Kim a, Sunghyun Cho, Enhanced handoff scheme based on efficient uplink quality estimation in LTE-Advanced system, Computer Networks 69 (2014) 133–146.
[10]
Giovanni, Antonio Virdis, A comprehensive simulation analysis of LTE Discontinuous Reception (DRX), Computer Networks 73 (2014) 22–40.
[11]
Bahattin Karakaya, Hakan A. Çırpan b, 1, Hüseyin Arslan, Channel interpolation for LTE uplink systems with high mobility using Slepian sequences, Physical Communication 10 (2014) 169–178.
[12]
Wei Kuang Lai ⇑, Chang-Lung Tang, QoS-aware downlink packet scheduling for LTE networks, Computer Networks 57 (2013) 1689–1698.
[13]
WANG Jun, GUAN Bao, LIU Shou-yin, XIE Wen-wu, Frequency offset estimation based on peak power ratio in LTE system, December 2013, 20(6): 49–54.
[14]
Nadine Akkari, An IMS-based integration architecture for WiMax/LTE handover, Computer Networks 57 (2013) 3790–3798.
[15]
Mehmet Bahadır Çelebi, İsmail Güvençb, Hüseyin Arslan, Khalid A. Qaraqe, Interference suppression for the LTE uplink, Physical Communication 9 (2013) 23–44.
[16]
Padmapriya Praveenkumara, Rengarajan Amirtharajanb, K Thenmozhib and John Bosco Balaguru Rayappanb, Phase for Face saving - a multicarrier Stego, Procedia Engineering 30 (2012) 790–797.
[17]
Jos´e Fernando Ortega Mu˜noz, H´ector Manuel F´elix Ibarra, Arturo Garc´ıa Melchor, Guillermo Galaviz, David H. Covarrubias Rosales, Resource assignment without service priorities using channel quality information in LTE-advanced systems, Procedia Engineering 35 ( 2012 ) 126–134.
[18]
Jooyoung Kwak, Heejin Lee, Do Bum Chung, The evolution of alliance structure in China’s mobile telecommunication industry and implications for international standardization, Telecommunications Policy 36 (2012) 966–976.
[19]
Yang Sun, JosephR. Cavallaro, Efficient hardware implementation of a highly-parallel 3GPP LTE/LTE-advance turbo decoder, integration, the VLSI journal 44(2011)305–315.
[20]
Ping’an Lia, Bin Wu, An Effective Approach to Detect Random Access Preamble in LTE Systems in Low SNR, Procedia Engineering 15 (2011) 2339–2343.
[21]
Pablo Ameigeiras, Juan J. Ramos-Munoz, Jorge Navarro-Ortiz, Preben Mogensen, Juan M. Lopez-Soler, QoE oriented cross-layer design of a resource allocation algorithm in beyond 3G systems, Computer Communications 33 (2010) 571–582.
[22]
Ian F. Akyildiz, David M. Gutierrez-Estevez, Elias Chavarria Reyes, The evolution to 4G cellular systems: LTE-Advanced, Physical Communication 3 (2010) 217–244.
ADDRESS
Science Publishing Group
1 Rockefeller Plaza,
10th and 11th Floors,
New York, NY 10020
U.S.A.
Tel: (001)347-983-5186