Ultra-Wideband%20Research%20and%20Implementation - PowerPoint PPT Presentation

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Ultra-Wideband%20Research%20and%20Implementation

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Ultra-Wideband Research and Implementation By Jarrod Cook and Nathan Gove Advisors: Dr. Brian Huggins Dr. In Soo Ahn Dr. Prasad Shastry Jarrod & Nate: * ?? ?? ?? – PowerPoint PPT presentation

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Title: Ultra-Wideband%20Research%20and%20Implementation


1
Ultra-Wideband Research and Implementation
  • By Jarrod Cook and Nathan Gove
  • Advisors
  • Dr. Brian Huggins
  • Dr. In Soo Ahn
  • Dr. Prasad Shastry

2
Presentation Outline
  • Introduction
  • Brief History
  • Benefits of UWB
  • Initial Project Goals
  • Actual Project Goals
  • Project Achievements
  • Project Issues
  • Results
  • Future Work
  • Conclusion
  • Questions?

3
Introduction to UWB
  • Ultra-wideband technology is a wireless
    transmission technique approved for unlicensed
    use in 2002 under the FCC Part 15
  • Ultra-Wideband is defined by the FCC as a
    transmission whose bandwidth is either
  • 20 of its center frequency
  • At least 500 MHz wide

4
Benefits of UWB
  • UWB allows devices to transmit data up to USB 2.0
    speeds (480 Mb/s)
  • Power spectral density is extremely low (-41.3
    dBm/MHz)
  • Low power consumption

5
Comparison of UWB with other schemes
  • Narrowband
  • Advantages
  • Range
  • Conservation of spectrum
  • Cost
  • Disadvantages
  • Power consumption
  • Limited bandwidth
  • Limited data rates
  • Wideband
  • Advantages
  • High data rates
  • Low power consumption
  • Spectrum coexistence
  • Disadvantages
  • Range
  • Power output regulations to prevent interference

6
One Disadvantage of UWB
7
(No Transcript)
8
Initial Project Goals
  • Bring UWB technology and research to the Bradley
    ECE department.
  • UWB development kit was to be researched and
    purchased for testing.

9
Initial Project Goals
  • Testing could lead to other projects in the UWB
    area.
  • Connect a computer with a USB device.

10
Initial Project Goals
  • The idea was to test the development kit
    thoroughly and match the results with UWB
    performance specs.
  • Spectrum measurements
  • Data rate measurements
  • Bit Error Rate (BER)
  • Transmission range
  • Power consumption
  • Antenna and RF characteristics

11
Why these goals failed
  • Upon doing research for companies working on
    development kits, the list was narrowed down to
    five companies
  • Staccato Communications
  • Focus Enhancement
  • Wisair
  • Alereon
  • PulsON Time Domain

12
Why these goals failed
  • None of these companies worked out.
  • Staccato Communications Too expensive
  • Focus Enhancement Still in development
  • Wisair Too expensive
  • Alereon Still in development
  • PulsON Time Domain Wrong modulation scheme

13
Brief History (1865-2002)
  • 1865 - Experiments by Heinrich Hertz
  • 1900s to 1950s - Communications goes Narrowband

1970s to 1980s UWB impulse radio invented
  • 2002 FCC approved UWB for unlicensed use under
    Part 15

14
Brief History (2002-current)
  • 2003 January IEEE 802.15.3a task group created
  • 2003 to 2004- WiMedia Alliance was created (or
    MBOA)
  • 2005- ECMA releases its UWB Standard (ECMA 368
    369)
  • WiMedia Alliance is working with global agencies
    to get ECMA UWB Standards approved world wide

Currently
15
UWB Theory of Operation
Basic UWB Transmitter Block Diagram
16
UWB Theory of Operation
  • Modulation
  • p/4 QPSK or 4-QAM
  • Gray Coded Mapping
  • Used for data rates from80 to 200 Mb/s
  • 16-QAM or DCM
  • Used for data rates from320 Mb/s to 480 Mb/s

17
UWB Theory of Operation
  • OFDM

18
UWB Theory of Operation
  • OFDM
  • Benefits
  • Resistance to multi-path fading
  • Spectrum
  • Full ECMA standardized UWB spectrum
  • UWB Spectrum
  • 3.1 to 10.6 GHz
  • 14 Sub-bands
  • -41.3 dBm/MHz
  • FCC part 15 limit

19
UWB Theory of Operation
  • Multiband OFDM (MB-OFDM)
  • Benefits
  • Reduces Complexity
  • Increases Robustness

20
Actual Project Goals
  • Developing a scaled-down transceiver pair by
    using
  • Simulink to create the baseband modulation models
    for the transmitter and receiver
  • Digital Signal Processing (DSP) platforms to
    perform the baseband modulation
  • Radio Frequency (RF) components to perform
    quadrature modulation and up conversion

21
Actual Project Goals
  • Time constraints shaped the project goals and
    outcomes
  • Use a wired connection between Tx and Rx
  • Antenna research and design
  • Power limitations

22
Actual Project Goals
  • Consulted Software Defined Radio by Vercimak
    and Weyeneth
  • Used the paper for guidance on some of the
    difficult aspects of the transmitter and receiver.

23
Project Implementation
  • Overall Model Block Diagram

24
Transmitter Simulink Model
Transmitter Spectrum
25
Transmitter Preamble
  • UWB Preamble Time Frequency Code 5
  • The only TF code that was for transmission in the
    1st sub band of band number one.
  • Preamble Length 165 repeated 24 times
  • Autocorrelation of Preamble

26
Project Implementation
  • Overall Model Block Diagram

27
Receiver Simulink Model
28
Receiver Frame Sync.
29
Receiver Frame Sync.
30
Receiver Simulink Model
31
Receiver Symbol Sync.
  • Adapted Luke Vercimaks Model to work with UWB
    model.
  • Lukes Project was implementation of OFDM Radio
    with 802.11 wireless standard (2006).

32
Receiver Simulink Model
33
RF Hardware
  • RF components were ordered from Hittite Microwave
    Corporation.
  • Quadrature Modulator
  • Quadrature Demodulator
  • Voltage Controlled Oscillator

34
RF Hardware
Quadrature Modulator
35
RF Hardware
Quadrature Demodulator
36
RF Hardware
  • Modulator Specifications
  • Demodulator Specifications
  • DC to 700 MHz Baseband input
  • Up to 6 dBm output power
  • 100 MHz to 4 GHz RF frequency range.
  • 100 MHz to 4 GHz RF frequency range.

37
Overall Hardware setup
38
Project Issues / Challenges
  • Speed of converters on hardware
  • DACs and ADCs max freq. 96kHz
  • For real UWB freq. 528 MHz required
  • Daughter-boards with faster converters
  • Complexity of integration with Simulink is its
    own Senior Project.
  • Code-composer limitations
  • Max of 7 simultaneous periodic sample rates.
  • Transmitter had 5-6 / Receiver had 13-15

39
Project Issues / Challenges
  • Simulink Learning Curve
  • Common misconception
  • Simulink Blocks will automatically take care of
    all the little details.
  • Simulink requires that information being
    processed must enter a block at the same rate.
  • Very useful tool but has many subtleties.

40
Results Transmitter
  • Able to port the Simulink model with
    Code-composer studio onto the DSP boards.

41
Results Transmitter
42
Results Receiver Sync.
Unsynchronized
Synchronized
Transmitted
Frame
Symbol
43
RF Results
  • Used HP ESG Signal Generator for I/Q baseband
    signals and local oscillator.
  • Tested the modulator and demodulator using time
    and frequency domain measurements.
  • All of the RF subsystem worked correctly.

44
RF Results
45
RF Results
Local Oscillator Signal
Modulated data
46
RF Results
In-phase input to modulator
In-phase output from demodulator
47
Final Project Schedule
48
Future Project Goals
  • Purchase a full-scaled development kit (if one
    exists).
  • Purchase Daughter Boards for the current TI DSPs.
  • New DSP platform with faster onboard peripherals.
  • Use the faster system to implement a high-speed
    wireless data system.

49
Conclusion
  • UWB will revolutionize consumer electronics.
  • It allows speeds up to USB 2.0 (480 Mb/s).
  • Low interference/coexistence.
  • Low power consumption.

50
Questions
?
?
U W B Standards
PS Dr. Ahn is limited to a maximum of 3
questions.
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