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The Wavelet Tutorial

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Title: The Wavelet Tutorial


1
The Wavelet Tutorial
  • Dr. Charturong Tantibundhit

2
What is a transform?
  • Mathematical transformations are applied to
    signals to obtain a further information from that
    signal that is not readily available in the raw
    signal.
  • In the following tutorial, I will assume a
    time-domain signal as a raw signal, and a signal
    that has been "transformed" by any of the
    available mathematical transformations as a
    processed signal

3
Time-Domain
  • time-amplitude representation
  • In many cases, the most distinguished information
    is hidden in the frequency content of the signal
  • The frequency SPECTRUM of a signal is basically
    the frequency components (spectral components) of
    that signal.

4
Spectrum
The Fourier transform (FT) of the 50 Hz signal
given in previous figure
5
Transforms
  • FT is probably the most popular transform being
    used.
  • Many other transforms are used quite often by
    engineers and mathematicians
  • Hilbert transform
  • Short-time Fourier transform (STFT)
  • Wigner distributions
  • Wavelet transform

6
Fourier Transform (FT)
  • FT is a reversible transform
  • No frequency information is available in the
    time-domain signal
  • No time information is available in the Fourier
    transformed signal
  • Is that is it necessary to have both the time and
    the frequency information at the same time?
  • This information is not required when the signal
    is so-called stationary

7
Stationary Signals
  • Signals whose frequency content do not change in
    time
  • x(t)cos(2pi10t)cos(2pi25t)cos(2pi50t)
    cos(2pi100t)

8
Non-Stationary Signals
  • A signal whose frequency changes in time
  • Ex. Chirp signal

9
Multiple Freq Presented Different Time
The interval 0 to 300 ms has a 100 Hz sinusoid,
the interval 300 to 600 ms has a 50 Hz sinusoid,
the interval 600 to 800 ms has a 25 Hz sinusoid,
and finally the interval 800 to 1000 ms has a 10
Hz sinusoid
10
  • FT is not a suitable technique for non-stationary
    signal
  • FT gives what frequency components (spectral
    components) exist in the signal. Nothing more,
    nothing less.
  • When the time localization of the spectral
    components are needed, a transform giving the
    TIME-FREQUENCY REPRESENTATION of the signal is
    needed

11
Wavelet Transform
  • Provides the time-frequency representation
  • Capable of providing the time and frequency
    information simultaneously
  • WT was developed to overcome some resolution
    related problems of the STFT
  • We pass the time-domain signal from various
    highpass and low pass filters, which filters out
    either high frequency or low frequency portions
    of the signal. This procedure is repeated, every
    time some portion of the signal corresponding to
    some frequencies being removed from the signal

12
Uncertainty Principle
  • We cannot exactly know what frequency exists at
    what time instance , but we can only know what
    frequency bands exist at what time intervals
  • This is a problem of resolution, and it is the
    main reason why researchers have switched to WT
    from STFT
  • The main reason why researchers have switched to
    WT from STFT. STFT gives a fixed resolution at
    all times, whereas WT gives a variable resolution

13
  • Suppose we have a signal which has frequencies up
    to 1000 Hz. In the first stage we split up the
    signal in to two parts by passing the signal from
    a highpass and a lowpass filter (filters should
    satisfy some certain conditions, so-called
    admissibility condition) which results in two
    different versions of the same signal portion of
    the signal corresponding to 0-500 Hz (low pass
    portion), and 500-1000 Hz (high pass portion).
  • Then, we take either portion (usually low pass
    portion) or both, and do the same thing again.
    This operation is called decomposition
  • Assuming that we have taken the lowpass portion,
    we now have 3 sets of data, each corresponding to
    the same signal at frequencies 0-250 Hz, 250-500
    Hz, 500-1000 Hz

14
Wavelet Transform
  • Higher frequencies are better resolved in time,
    and lower frequencies are better resolved in
    frequency
  • A certain high frequency component can be located
    better in time (with less relative error) than a
    low frequency component
  • A low frequency component can be located better
    in frequency compared to high frequency component

15
STFT
16
Fourier Transform
  • The information provided by the integral,
    corresponds to all time instances
  • whether the frequency component "f" appears at
    time t1 or t2 , it will have the same effect on
    the integration

17
  • x(t)cos(2pi5t)cos(2pi10t)cos(2pi20t)
  • cos(2pi50t)

18
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19
Sort-Time Fourier Transform (STFT)
  • How are we going to insert this time business
    into our frequency plots
  • Can we assume that, some portion of a
    non-stationary signal is stationary?
  • The signal is stationary every 250 time unit
    intervals (previous figure)
  • If this region where the signal can be assumed to
    be stationary is too small, then we look at that
    signal from narrow windows, narrow enough that
    the portion of the signal seen from these windows
    are indeed stationary

20
STFT
  • In STFT, the signal is divided into small enough
    segments, where these segments (portions) of the
    signal can be assumed to be stationary
  • A window function "w" is chosen. The width of
    this window must be equal to the segment of the
    signal where its stationarity is valid

21
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23
  • If we use a window of infinite length, we get the
    FT, which gives perfect frequency resolution, but
    no time information
  • The narrower we make the window, the better the
    time resolution, and better the assumption of
    stationarity, but poorer the frequency resolution
  • Narrow window gtgood time resolution, poor
    frequency resolution.
  • Wide window gtgood frequency resolution, poor
    time resolution.

24
Different Window Sizes
  • w(t)exp(-a(t2)/2)

25
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