Inverse Fast Walsh-Hadamard transform
y = ifwht(x)
y = ifwht(x,n)
y = ifwht(x,n,ordering)
y = ifwht(x) returns the coefficients of
the inverse discrete fast Walsh-Hadamard transform of the input
x is a matrix, the inverse fast Walsh-Hadamard
transform is calculated on each column of
inverse fast Walsh-Hadamard transform operates only on signals with
length equal to a power of 2. If the length of
less than a power of 2, its length is padded with zeros to the next
greater power of two before processing.
y = ifwht(x,n) returns the
inverse discrete Walsh-Hadamard transform, where
be a power of 2.
y = ifwht(x,n,ordering) specifies the ordering
to use for the returned inverse Walsh-Hadamard transform coefficients.
To specify the ordering, you must enter a value for the length
to use the default behavior, specify an empty vector (
n. Valid values for the ordering are the following:
|Coefficients in order of ascending sequency value, where each row has an additional zero crossing. This is the default ordering.|
|Coefficients in normal Hadamard order.|
|Coefficients in Gray code order, where a single bit change occurs from one coefficient to the next.|
Use an electrocardiogram (ECG) signal to illustrate working with the Walsh-Hadamard transform. ECG signals typically are very large and need to be stored for analysis and retrieval at a future time. Walsh-Hadamard transforms are particularly well-suited to this application because they provide compression and thus require less storage space. They also provide rapid signal reconstruction.
Start with an ECG signal. Replicate it to create a longer signal and insert some additional random noise.
xe = ecg(512); xr = repmat(xe,1,8); x = xr + 0.1.*randn(1,length(xr));
Transform the signal using the fast Walsh-Hadamard transform. Plot the original signal and the transformed signal.
y = fwht(x); subplot(2,1,1) plot(x) xlabel('Sample index') ylabel('Amplitude') title('ECG Signal') subplot(2,1,2) plot(abs(y)) xlabel('Sequency index') ylabel('Magnitude') title('WHT Coefficients')
The plot shows that most of the signal energy is in the lower sequency values, below approximately 1100. Store only the first 1024 coefficients (out of 4096). Try to reconstruct the signal accurately from only these stored coefficients.
y(1025:length(x)) = 0; xHat = ifwht(y); figure plot(x) hold on plot(xHat) xlabel('Sample Index') ylabel('ECG Signal Amplitude') legend('Original','Reconstructed')
The reproduced signal is very close to the original but has been compressed to a quarter of the size. Storing more coefficients is a tradeoff between increased resolution and increased noise, while storing fewer coefficients can cause loss of peaks.
The inverse fast Walsh-Hadamard transform algorithm is similar to the Cooley-Tukey algorithm used for the inverse FFT. Both use a butterfly structure to determine the transform coefficients. See the references for details.
 Beauchamp, Kenneth G. Applications of Walsh and Related Functions: With an Introduction to Sequency Theory. London: Academic Press, 1984.
 Beer, Tom. “Walsh Transforms.” American Journal of Physics. Vol. 49, 1981, pp. 466–472.