Calculation of the Signal Occupied Bandwidth for the FDD-based 4G Mobile Communication

Similar documents
Dynamic Frequency Selection method applying Mobile Security concept

802.11ax introduction and measurement solution

Investigations for Broadband Internet within High Speed Trains

2012 LitePoint Corp LitePoint, A Teradyne Company. All rights reserved.

Channel Model Considerations for P802.11af

International Telecommunication Union

IEEE Working Group Process, Status, and Technology Session #33: Seoul, Korea 30 August 2004

4G TDD MIMO OFDM Network

Performance Evaluation of 3G CDMA Networks with Antenna Arrays

Performance of Orthogonal Frequency Division Multiplexing System Based on Mobile Velocity and Subcarrier

Wireless Physical Layer Concepts: Part III

ENHANCED BANDWIDTH EFFICIENCY IN WIRELESS OFDMA SYSTEMS THROUGH ADAPTIVE SLOT ALLOCATION ALGORITHM

IMT-Advanced Standardization Process

WiMAX Summit Testing Requirements for Successful WiMAX Deployments. Fanny Mlinarsky. 28-Feb-07

Recent Developments in Indoor Radiowave Propagation

IEEE Project m as an IMT-Advanced Technology

Summary of ITU-R WP 8F work towards IMT-Advanced and the vision for the future, including examples of applications

FUTURE SPECTRUM WHITE PAPER DRAFT

Basic Radio Settings on the WAP371

WINNER+ Miia Mustonen VTT Technical Research Centre of Finland. Slide 1. Event: CWC & VTT GIGA Seminar 2008 Date: 4th of December 2008

UMTS Forum. IMT-2000 spectrum activities

Update on ITU-R Working Party 5D on IMT-2020 for 5G

FBMC for TVWS. Date: Authors: Name Affiliations Address Phone

Millimeter wave: An excursion in a new radio interface for 5G

Overview of IEEE Broadband Wireless Access Standards. Timo Smura Contents. Network topologies, frequency bands

Cohere Technologies Performance evaluation of OTFS waveform in single user scenarios Agenda item: Document for: Discussion

Wireless Networks: An Introduction

Finding right frequencies

RECOMMENDATION ITU-R F.1402*, **

Baseline Proposal for EPoC PHY Layer IEEE 802.3bn EPoC September 2012 AVI KLIGER, BROADCOM LEO MONTREUIL, BROADCOM ED BOYD, BROADCOM

Institute of Electrical and Electronics Engineers (IEEE) PROPOSED AMENDMENTS TO ANNEX 15 TO DOCUMENT 8A/202

Baseline Proposal for EPoC PHY Layer

RECOMMENDATION ITU-R BT.1832 * Digital video broadcast-return channel terrestrial (DVB-RCT) deployment scenarios and planning considerations

Data and Computer Communications. Tenth Edition by William Stallings

802.11n. Suebpong Nitichai

Partial Co-channel based Overlap Resource Power Control for Interference Mitigation in an LTE-Advanced Network with Device-to-Device Communication

Radio Resource Allocation Scheme for Device-to-Device Communication in Cellular Networks Using Fractional Frequency Reuse

Broadband Wireless Access: A Brief Introduction to IEEE and WiMAX

Technical Bulletin. DIFFERENT OPERATING MODES, SPECTRAL BEHAVIOUR & DATA THROUGHPUT Prepared by: Jack Van der Star, P.Eng.

When technology meets spectrum: Bring 5G vision into Reality

IEEE C /008. IEEE Broadband Wireless Access Working Group <

IEEE c-00/40. IEEE Broadband Wireless Access Working Group <

WiMAX and Non-Standard Solutions

The 5th Smart Antenna Workshop 21 April 2003, Hanyang University, Korea Broadband Mobile Technology Fumiyuki Adachi

SEN366 (SEN374) (Introduction to) Computer Networks

LTE & LTE-A PROSPECTIVE OF MOBILE BROADBAND

5G Synchronization Aspects

Vehicle-to-X communication for 5G - a killer application of millimeter wave

Wireless Broadband Networks

RECOMMENDATION ITU-R M.1391 METHODOLOGY FOR THE CALCULATION OF IMT-2000 SATELLITE SPECTRUM REQUIREMENTS

REPORT ITU-R M Impact of radar detection requirements of dynamic frequency selection on 5 GHz wireless access system receivers

IEEE Broadband Wireless Access Working Group < Initial PHY Layer System Proposal for Sub 11 GHz BWA

IMT-Advanced: Process, Opportunities and Usages

A Flexible Frame Structure for 5G Wide Area Pedersen, Klaus I.; Frederiksen, Frank; Berardinelli, Gilberto; Mogensen, Preben Elgaard

Realization of Peak Frequency Efficiency of 50 Bit/Second/Hz Using OFDM MIMO Multiplexing with MLD Based Signal Detection

Wireless WANS and MANS. Chapter 3

IEEE c-23. IEEE Broadband Wireless Access Working Group <

EC 551 Telecommunication System Engineering. Mohamed Khedr

Medium Access Control Protocol for WBANS

RECOMMENDATION ITU-R F Radio interface standards for broadband wireless access systems in the fixed service operating below 66 GHz

To Fragment or Not To Fragment: Viability of NC OFDMA in Multihop Networks. Muhammad Nazmul Islam WINLAB, Rutgers University

Adoption of this document as basis for broadband wireless access PHY

Signal to Noise Ratio Estimation and Bit Error Rate for Wireless MAN-OFDM

Guide to Wireless Communications, Third Edition Cengage Learning Objectives

Wireless Medium Access Control and CDMA-based Communication Lesson 16 Orthogonal Frequency Division Medium Access (OFDM)

CSC344 Wireless and Mobile Computing. Department of Computer Science COMSATS Institute of Information Technology

Study on the next generation ITS radio communication in Japan

Further Vision on TD-SCDMA Evolution

Research in Ultra Wide Band(UWB) Wireless Communications

A Multicarrier CDMA Based Low Probability of Intercept Network

Vehicle-to-X communication using millimeter waves

IEEE PROPOSED AMENDMENTS TO WORKING DOCUMENT TOWARDS PRELIMINARY DRAFT NEW RECOMMENDATION ITU-R F.[9B/BWA]

Mobile Communication Systems. Part 7- Multiplexing

Global BWA Activities in ITU

LETTER A Simple Expression of BER Performance in COFDM Systems over Fading Channels

Sang-Tae Kim, Seong-Yun Lee. Radio Technology Research Department

Improving Peak Data Rate in LTE toward LTE-Advanced Technology

Overcoming Key OTA Test Challenges from 4G to 5G

Outcomes of ITU WRC-12 for IMT & other mobile broadband

Fractional Delay Filter Based Wideband Self- Interference Cancellation

RECOMMENDATION ITU-R F Radio-frequency channel arrangements for fixed wireless systems operating in the 13 GHz ( GHz) frequency band

DESIGN OF AN S-BAND TWO-WAY INVERTED ASYM- METRICAL DOHERTY POWER AMPLIFIER FOR LONG TERM EVOLUTION APPLICATIONS

Central America and Caribbean: Digital television planning technical criteria and assumptions

University of Bristol - Explore Bristol Research. Peer reviewed version. Link to publication record in Explore Bristol Research PDF-document

ECE5984 Orthogonal Frequency Division Multiplexing and Related Technologies Fall Mohamed Essam Khedr. Fading Channels

RECOMMENDATION ITU-R F Radio-frequency channel arrangements for fixed wireless systems operating in the 7 GHz band

Testing Carrier Aggregation in LTE-Advanced Network Infrastructure

Delivering effective 5G/IMT-2020 service implementation economically. Joaquin Restrepo, Chief of Outreach and Publication Services Division,BR/ ITU

ORTHOGONAL frequency division multiplexing (OFDM)

IEEE C /07. IEEE Broadband Wireless Access Working Group <

University of Bristol - Explore Bristol Research. Link to publication record in Explore Bristol Research PDF-document.

2 nd Generation OFDM for

Radio Propagation Characteristics in the Large City

Cognitive Cellular Systems in China Challenges, Solutions and Testbed

Performance Enhancement of WiMAX System using Adaptive Equalizer

ITU-T SSG: IMT-2000 Core Network Activities

Requirements on 5G Development Device manufacturer s perspective

5G Spectrum Roadmap & Challenges IEEE 5G Summit. 2 November, 2016

CSC344 Wireless and Mobile Computing. Department of Computer Science COMSATS Institute of Information Technology

Cooperative Wireless Networking Using Software Defined Radio

Transcription:

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 258 Calculation of the Signal Occupied Bandwidth for the FDD-based 4G Mobile Communication YOUNGJU HYUN, KYUNGSEOK KIM School Electrical and Computer Eng. Chungbuk National Univ. 12 Gaeshin-dong Heungduk-gu Chongju Chungbuk 361-763 KOREA bbang7101@naver.com, kseokkim@cbnu.ac.kr Abstract: - The new wireless multimedia environment is coming because of the variety of an user requirement and a traffic increase which we can not accept in the IMT-2000 present systems. To offer the wireless multimedia service the world wireless communication company which included the ITU-R is developing the standard and technique of 4G systems. We analyzed the technique criteria of the 4G wireless communication system in this paper which is based on that of WiBro System. The mobile communication traffic is predicted Up/Down-link of non-symmetric in the future. So, we considered the communication traffic of non-symmetric. And we proposed the PHY layer parameters of occupied frequency bandwidth of Up/Down-link with both 1:3 and 1:5. And we verified this through the simulation. So we proposed the occupied frequency bandwidth for 4G wireless communication in this paper. Key-Words: - 4G, ITU-R WP8F, Standardization, Technical criterion, OFDM 1. Introduction The new wireless multimedia environment is coming because of the variety of an user requirement and a traffic increase which we can not accept in the IMT-2000 present systems. To offer the wireless multimedia service the world wireless communication company which included the ITU-R is developing the standard and technique of the forth generation (4G) systems[1][2]. The voice was the driver for second-generation mobile and has been a considerable success. Today, video and TV services are driving forward third-generation(3g) deployment. And in the future, low cost, high speed data will drive forward the forth generation(4g) as short-range communication emerges. Table 1. Paradigm shift form 1st generation toward 4G 4G systems of ITU are doing to the goal to offer to that bit transmission rate of 1Gbps for user at a low speed movement and bit transmission rate of 100Mbps for user at a high speed movement[3][4]. We summarized an upside's content and arranged to the table 1. 2. 4G vision and requirement

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 259 Table 2. ITU-R 4G Vision Figure 1. A facility area of B3G of ITU-R WP8F. Figure 1 comes to divide 3 area. Each area means that. Future Development of IMT-2000 : This area means the existing IMT-2000 develops of the left area of the Fig. 1. New Capabilities of systems beyond IMT-2000 : New wireless communication technique will be desired about in 2010 years. This system's demand data rate offer to 100Mbps at high speed movement system and it offer to 1Gbps at low speed movement and fixed systems in ITU-R WP8F. This area is right and up area(at high speed movement system), right and down area(at low speed movement and fixed systems) of the Fig.1. Relationship of IMT-2000, systems beyond IMT-2000, and other access systems : Various wireless connection systems of WPAN, WLAN, Digital brodcasting will continue the relatin with systems beyond IMT-2000 as progress continuously. 3. Design parameter of FDD-based occupied bandwidth for the 4G mobile communication system Figure 2 is the data to forecast mobile communication traffic of Asia area of 2015 years in ITU-R WP8F. The forecast of traffic difference of Up/Down-link will enlarge from 1:1.26 to 1:5.2 according to figure 2 in 2010 year. The mobile communication traffic is predicted Up/Down-link of non-symmetric in the figure 2. So, we considered the communication traffic of non-symmetric in this paper. And we proposed the PHY layer parameters of occupied bandwidth of Up/Down-link with both 1:3 and 1:5. And we verified this through the simulation. The present communication system is not enough capacity for full multimedia service, high cost. So, the present communication system is developing toward the 4G[5]. Figure 2. The traffic forecast of mobile communication in the Asia area. We designed the bandwidth of Up-link of 10MHz. And we considered down-link each bandwidth of 30MHz and 50MHz. We considered the FDD-based OFDM system. We selected the carrier frequency of the candidate bandwidth

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 260 (3.4~4.2GHz) on the 4G. The carrier frequency is used 3.6GHz at the Up-link and 4.0GHz at Down-link, respectively [6]. Table 4. Case 2 of OFDM PArameters 3.1 Design parameter of OFDM Guard band duration is T = τ K (1) Whereτ rms : 4us, G rms M K : Modulation factor(2~4). M OFMD symbol period select both equation (2) and (3). Tdata,min + TG 10log( ) Lloss ( db) T (2) T data,min T data,min Lloss /10 G (1/(10 1)) Tdata,max = TC TG = 1/ 2 fd TG (3) Where Tc : coherence time, fd : Doppler frequency. Total OFDM symbol period is guard band + symbol period. Number of subcarrier is selected of 2^n by equation (4). T fs N T fs data,min data data,max N = [[ N ]] data fs : sampling frequency. Table 3. Case 1 of OFDM Parameters (4) The table 3, 4 arranges the result to get by OFDM parameter selection of the front. We considered bandwidth for Up/Down-link of non-symmetric. Table 3 is parameters of Up/ Down-link. The Up/ Down-link rate considered in the case 1 to be 1:3. And table 4 is parameters of Up/ Down-link, too. The Up/ Down-link rate considered in the case 2 to be 1:5. 4 Simulations We proposed the PHY layer parameters of occupied frequency bandwidth of Up/Down-link with both 1:3 and 1:5. And we verified this through the simulation. The simulation block diagram is figure 3. Figure 3. Simulation block diagram 4. 1. Up-link simulation result

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 261 The figure 4, 5, 6 are the results of the Up-link simulation output. The carrier frequency of standard signal is 3.6GHz. And the carrier frequency of interference signal narrowed for view of interference effect. The figure 6, 7, 8 are the results of the Down-link simulation output. The carrier frequency of standard signal is 4.0GHz. And the carrier frequency of interference signal narrowed for same reason of Up-link case. Figure 4. Simulation result of Up-link (channel interval : 20MHz) The figure 4 is OFDM signal which has the Up-link bandwidth of the 10MHz. of the 20MHz. The SNR(Signal to Noise Ratio) is interference signal and standard signal ratio of 22dB in figure 4. Figure 6. Simulation result of Down-link case 1 (channel interval : 40MHz) The figure 6 is OFDM signal which has the Down-link bandwidth of the 30MHz. of the 40MHz. The SNR(Signal to Noise Ratio) is interference signal and standard signal ratio of 24dB in figure 6. Figure 5. Simulation result of Up-link (channel interval : 8MHz) The figure 5 is the result when the channel interval is narrow than the occupied bandwidth. The occupied bandwidth is about 9.741MHz. And channel interval is 8MHz. A standard signal is namely the case to take serious influence by an adjacent channel. Figure 7. Simulation result of Down-link case 1 (channel interval : 30MHz) of the 30MHz. The SNR(Signal to Noise Ratio) is interference signal and standard signal ratio of 18dB in figure 7. 4. 2. Down-link simulation result of case 1

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 262 Figure 8. Simulation result of Down-link case 1 (channel interval : 20MHz) Figure 10. Simulation result of Down-link case 2 (channel interval : 50MHz) The figure 8 is the result when the channel interval is narrow than the occupied bandwidth. The occupied bandwidth is about 24.595MHz. And channel interval is 20MHz. A standard signal is namely the case to take serious influence by an adjacent channel. 4. 3. Down-link simulation result of case 2 The figure 9, 10, 11 are the results of the Down-link simulation output. The carrier frequency of standard signal is 4.0GHz same. Figure 11. Simulation result of Down-link case 2 (channel interval : 40MHz) The figure 11 is the results when the channel interval is narrow than the occupied bandwidth same of other results. The occupied bandwidth is about 45MHz. And channel interval is 40MHz. A standard signal is namely the case to take serious influence by an adjacent channel. Figure 9. Simulation result of Down-link case 2 (channel interval : 60MHz) The figure 9 is OFDM signal which has the Down-link bandwidth of the 50MHz. of the 60MHz. The SNR(Signal to Noise Ratio) is interference signal and standard signal ratio of 23dB in figure 9. 5 Conclusions In this paper we studied occupied frequency bandwidth of common technique criteria among the technique criteria for the 4G mobile communication of Up/Down-link. And we calculated of FDD-based. The mobile communication traffic is predicted Up/Down-link of non-symmetric in the future. So, we considered the communication traffic of non-symmetric. And we proposed the PHY layer parameters of occupied frequency bandwidth of Up/Down-link with both 1:3 and 1:5. And we verified this through the simulation. So we proposed the occupied frequency bandwidth for the 4G mobile communication in this paper.

Proceedings of the 7th WSEAS International Conference on Multimedia, Internet & Video Technologies, Beijing, China, September 15-17, 2007 263 References: [1] ITU-R, Doc. 8F/Temp 316 "ITU-R PDNR M.[IMT-VIS]- Preliminary Draft New Recommendation(PDNR): Vision Framework and Overall Objectives of the Future Development of IMT-2000 and of Systems Beyond IMT-2000. " [2] Working Document Towards Draft Report ; Vision and Objectives for the Ongoing Enhancement of IMT-2000 and Future Systems Beyond IMT-2000, ITU-R WP8F/TEMP/25-E 23 Aug. 2000 [3] Rec, ITU-R. M1645, " Framework and overall objectives of the future development of IMT 2000 and systems beyond IMT 2000," 2003. [4] Standardization Roadmap for IT839 Strategy Ver. 2007 [5] Working document IEEE 802.16-2004/ Cor1-D2, 2005-04-04. [6] "Scalable OFDMA Physical Layer in IEEE 802.16 WirelessMAN", Intel Technology Journal, Volume 8, Issue 3, August 2004

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback