Design and Validation of a UWB Transmitter for FPGA Implementation

Slides:



Advertisements
Similar presentations
High Rate - Ultra Wide Band (UWB) Background Ecma/GA/2005/038.
Advertisements

OFDM Transmission Technique Orthogonal Frequency Division Multiplexer
(Orthogonal Frequency Division Multiplexing )
1 PIANO+ OTONES WP3 SIGNAL PROCESSING ALGORITHMS.
VSMC MIMO: A Spectral Efficient Scheme for Cooperative Relay in Cognitive Radio Networks 1.
a By Yasir Ateeq. Table of Contents INTRODUCTION TASKS OF TRANSMITTER PACKET FORMAT PREAMBLE SCRAMBLER CONVOLUTIONAL ENCODER PUNCTURER INTERLEAVER.
Progress of MB-OFDM UWB Baseband System Wen-Hua Wu May 26, 2006.
Contents Physical layer for IEEE b Channel allocation
Doc.: IEEE /1305r1 Submission January 2011 Monnerie (Landis+Gyr), Buffington (Itron), Shimada (Yokogawa Co.), Waheed (Freescale) Slide 1 IEEE.
Wireless LANs Ethernet and all its enhancements is the major wired LAN architecture today Beyond Ethernet, the fastest growing LAN architecture is wireless.
Orthogonal Frequency Division Multiple Access (OFDMA)
National Institute Of Science & Technology OFDM Deepak Ranjan Panda (EI ) [1] Orthogonal Frequency Division multiplexing (OFDM) Technical Seminar.
Doc.: IEEE /383 Submission November1998November 1998 Jamshid Khun-Jush, ETSI-BRANSlide 1 BRAN#11 PHY Decisions & Issues to Resolved with
Implementation of OFDM Transmitter based on the IEEE d Standard Presented by: Altamash Janjua Group Partner: Umar Chohan Supervisors: Dr. Brian L.
Doc.: IEEE /0909r0 Submission July 2012 Jong S. Baek, AlereonSlide 1 Analysis, simulation and resultant data from a 6-9GHz OFDM MAC/PHY Date:
WiMedia Alliance
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANS) Submission Title: [TG3a Performance Considerations in UWB Multi-Band] Date.
FPGA Implementation of an OFDM Modem Laboratório de Telecomunicações Departamento de Engenharia Elétrica Universidade Federal.
802.11n MIMO-OFDM Standard  IEEE n group  MIMO-OFDM  Increased performance  Transmitter  MAC Enhancements  Results.
Doc.: IEEE /0205r0 Submission Jan 2015 Shiwen He, Haiming Wang Slide 1 Time Domain Multiplexed Pilots Design for IEEE802.11aj(45 GHz) SC PHY Authors/contributors:
UWB (Ultra Wideband) Communication System 長庚電機通訊組 碩一 張晉銓 指導教授 : 黃文傑博士.
S , Postgraduate Course in Radio Communications
Introduction to OFDM and Cyclic prefix
IEEE : High-rate WPAN Overview
 First generation systems utilized frequency axis to separate users into different channels  Second generation systems added time axis to increase number.
doc.: IEEE <doc#>
244-6: Higher Generation Wireless Techniques and Networks
A G3-PLC Network Simulator with Enhanced Link Level Modeling
Proposal for Statistical Channel Error Model
FPGA Implementation of an OFDM Modem
WiMAX 1EEE Protocol Stack
IEEE a b g.
4G Wireless Systems A Seminar on Presented By: Sainik Kumar Mahata
FPGA Implementation of an OFDM Modem
doc.: IEEE <doc#>
January 2016 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: pureLiFi r1 proposal for High Speed.
March 2003 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [PHY Proposal for the IEEE a standard]
HNS Proposal for n Physical Layer
doc.: IEEE g-Trends-in-SUN-capacity
John Ketchum, Bjorn A. Bjerke, and Irina Medvedev Qualcomm, Inc.
Inprocomm PHY Proposal for IEEE n: MASSDIC-OFDM
Partial Proposal: 11n Physical Layer
<doc.: IEEE −doc>
Submission Title: [Compatible DSSS g Network Communications Proposal]
CDMA2000.
Wireless LANs (Geier Book, Chapter 2)
Linglong Dai, Jintao Wang, Zhaocheng Wang and Jun Wang
January 2005 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Wisair-CFP-Response] Date Submitted: [4.
UWB Receiver Algorithm
<doc.: IEEE −doc>
Multicarrier Communication and Cognitive Radio
PHY SIG Frame Structure for IEEE aj (45GHz)
ETRI Proposal to IEEE TGn
March, 2003 doc.: IEEE /127r0 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Alternate PHY.
Wireless Mesh Networks
January 2005 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Wisair-CFP-Response] Date Submitted: [4.
doc.: IEEE <doc#>
OFDM (Orthogonal Frequency Division Multiplexing)
MAC based FEC – improvement for a
5-GHz Unified Protocol (5-UP) Proposal OFDM Extensions for a
Sept 2003 doc.: IEEE a Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: Techniques for.
Multi-block OFDM for TVWS Operation
11ac 80MHz Transmission Flow
Strawmodel ac Specification Framework
Multi-block OFDM for TVWS Operation
HNS Proposal for n Physical Layer
MSN 2009 Workshop 9th July 2009 Ali Al-Sherbaz Torben Kuseler
1MHz Dup Mode Date: Authors: Nov 2012 Month Year
IEEE a b g.
Physical Layer (2).
Presentation transcript:

Design and Validation of a UWB Transmitter for FPGA Implementation G. Liang In this work, a complete Transmitter (TX) system based on Multiband-OFDM Ultra Wideband (MB-OFDM UWB) protocol has been designed. The Hardware-in-the-loop co-simulation methodology is used for validating the whole system. This architecture is based on state-of-the art proposals, but modified and optimized for our implementation. Some proposed low-power, high-performance sub-modules have been implemented and verified on a Xilinx-Virtex 5 FPGA. The final results prove that our design is suitable for UWB communications. Project sponsored by General Information & Requirements of Ultra Wideband (UWB) SMART Utilize the unlicensed 3.1~10.7 GHz frequency band Range: 4m ~ 10m (short-reach transmission system) Support data rates from 53.3~480 Mb/s Divide the spectrum into 14 bands, each with a bandwidth of 528 MHz The data is then interleaved to different band using specified TFC MB-OFDM scheme:110 sub-carriers (100 data, 10 guard), 12 pilot, 6 NULL MB-OFDM symbol: 128 OFDM symbol+37 Zero Prefix IEEE 802.15.3a Group Multiband Orthogonal Frequency Division Multiplexing Leading Choice for UWB system Transmitter Architecture for MB-OFDM UWB system Transmitted data format: General description: PLCP Preamble PHY Header MAC Header Header Check Sequence Frame Payload Pad bits Tail bits Structure and data format is different based on different transmitted data rate, can use re-configuration technology to change the transmission mode from one to another 4-path in parallel structure for most of the sub-modules, so as to speed up the whole system while lower the power Clock-island method is used, different sub-module performs at different clock rate---Saving Power State-of-the-art architectures are utilized Hardware-in-the-loop Co-simulation Methodology Main IDEA Virtual Communication Simulation Environment HDL Functional Simulation Download Bitstream Transmitter System (Hardware) Transmission Channel Model for UWB (MATLAB Model) Cover every step in system development Efficient in time for complex hardware architecture implementation Make hardware validation much easier Convenient to monitor the output results Ensure designers focus on the design and optimization Receiver System (Hardware)