Saeid Sanei

EEG Signal Processing and Machine Learning


Скачать книгу

an estimate of the coefficients is:

      (4.46)equation

      The cut‐off frequency is reduced by a factor 2 at each step, allowing a reduction of the number of samples by this factor. The wavelet coefficients at the scale j + 1 are:

      (4.47)equation

      and they can be computed directly from Cj by:

      (4.48)equation

      where G is the following discrete‐time filter:

      (4.49)equation

      and for images and images:

      (4.50)equation

      The frequency band is also reduced by a factor of two at each step. These relationships are also valid for DWT following Section 4.5.1.4.

      4.5.1.6 Reconstruction

      The reconstruction of the data from its wavelet coefficients can be performed step‐by‐step, starting from the lowest resolution. At each scale, we compute:

      (4.51)equation

      (4.52)equation

      we look for Cj knowing Cj + 1, Wj + 1, h, and g. Then images is restored by minimizing:

      (4.53)equation

      using a least minimum squares estimator. images and images are weight functions which permit a general solution to the restoration of images. The relationship from of images is in the form of:

      (4.54)equation

      where the conjugate filters have the expressions:

      The denominator is reduced if we choose:

      (4.57)equation

      This corresponds to the case where the wavelet is the difference between the squares of two resolutions:

      (4.58)equation

      The reconstruction algorithm then carries out the following steps:

      1 Compute the fast Fourier transform (FFT) of the signal at the low resolution.

      2 Set j to np (number of WT resolutions); perform the following iteration steps:

      3 Compute the FFT of the wavelet coefficients at the scale j.

      4 Multiply the wavelet coefficients Wj by .

      5 Multiply the signal coefficients at the lower resolution Cj by .

      6 The inverse Fourier transform of gives the coefficients Cj‐1.

      7 j = j − 1 and return to step 3.

      The use of a band‐limited scaling function allows a reduction of sampling at each scale and limits the computation complexity.

      The WT has been widely used in EEG signal analysis. Its application to seizure detection, especially for neonates, modelling of the neuron potentials, and the detection of EP and ERPs will be discussed in the corresponding chapters of this book.

      4.5.2 Synchro‐Squeezed Wavelet Transform

equation

      (4.60)equation