Has anyone tried implementing matlab's
filtfilt() function in Java (or at least in C++)? If you guys have an algorithm, that would be of great help.
Here is my implementation in C++ of the
filtfilt algorithm as implemented in MATLAB. Hope this helps you.
Allright, I know this question is ancient, but maybe I can be of help to someone else who winds up here wondering what
filtfilt actually does.
Although it is obvious from the docs that
filtfilt does forward-backward (a.k.a. zero-phase) filtering, it was not so obvious to me how it deals with things like padding and initial conditions.
As I couldn't find any other answers here (nor elsewhere) with sufficient information about these implementation details of
filtfilt, I implemented a simplified version of
scipy.signal.filtfilt, based on its source and documentation (so, not
Python). I believe the
scipy version works the same way as
To keep things simple, the code below was written specifically for a second order IIR filter, and it assumes the coefficient vectors
b are known (e.g. obtained from
scipy.signal.butter, or calculated by hand).
It matches the
filtfilt default behavior, using
odd padding of length
3 * max(len(a), len(b)), which is applied before the forward pass. The initial state is found using the approach from
Disclaimer: This code is only intended to provide some insight into certain implementation details of
filtfilt, so the goal is clarity instead of computational efficiency/performance. The
scipy.signal.filtfilt implementation is much faster (e.g. 100x faster according to a quick & dirty
timeit test on my system).
import numpy def custom_filter(b, a, x): """ Filter implemented using state-space representation. Assume a filter with second order difference equation (assuming a=1): y[n] = b*x[n] + b*x[n-1] + b*x[n-2] + ... - a*y[n-1] - a*y[n-2] """ # State space representation (transposed direct form II) A = numpy.array([[-a, 1], [-a, 0]]) B = numpy.array([b - b * a, b - b * a]) C = numpy.array([1.0, 0.0]) D = b # Determine initial state (solve zi = A*zi + B, see scipy.signal.lfilter_zi) zi = numpy.linalg.solve(numpy.eye(2) - A, B) # Scale the initial state vector zi by the first input value z = zi * x # Apply filter y = numpy.zeros(numpy.shape(x)) for n in range(len(x)): # Determine n-th output value (note this simplifies to y[n] = z + b*x[n]) y[n] = numpy.dot(C, z) + D * x[n] # Determine next state (i.e. z[n+1]) z = numpy.dot(A, z) + B * x[n] return y def custom_filtfilt(b, a, x): # Apply 'odd' padding to input signal padding_length = 3 * max(len(a), len(b)) # the scipy.signal.filtfilt default x_forward = numpy.concatenate(( [2 * x - xi for xi in x[padding_length:0:-1]], x, [2 * x[-1] - xi for xi in x[-2:-padding_length-2:-1]])) # Filter forward y_forward = custom_filter(b, a, x_forward) # Filter backward x_backward = y_forward[::-1] # reverse y_backward = custom_filter(b, a, x_backward) # Remove padding and reverse return y_backward[-padding_length-1:padding_length-1:-1]
Note that this implementation does not require
scipy. Moreover, it can easily be adapted to work in pure python, without even
numpy, by writing out the solution for
zi and using lists instead of numpy arrays. This even comes with a substantial performance benefit, because accessing individual numpy array elements in a python loop is much slower than accessing list elements.
The filter itself is implemented here in a simple
Python loop. It uses the state space representation, because this is used anyway to determine the initial conditions (see
scipy.signal.lfilter_zi). I believe that the actual
scipy implementation of the linear filter (i.e.
scipy.signal.sigtools._linear_filter) does something similar in
C, as can be seen here (thanks to this answer).
Here's some code providing a (very basic) check for equality of the
scipy output and
import numpy import numpy.testing import scipy.signal from matplotlib import pyplot from . import custom_filtfilt def sinusoid(sampling_frequency_Hz=50.0, signal_frequency_Hz=1.0, periods=1.0, amplitude=1.0, offset=0.0, phase_deg=0.0, noise_std=0.1): """ Create a noisy test signal sampled from a sinusoid (time series) """ signal_frequency_rad_per_s = signal_frequency_Hz * 2 * numpy.pi phase_rad = numpy.radians(phase_deg) duration_s = periods / signal_frequency_Hz number_of_samples = int(duration_s * sampling_frequency_Hz) time_s = (numpy.array(range(number_of_samples), float) / sampling_frequency_Hz) angle_rad = signal_frequency_rad_per_s * time_s signal = offset + amplitude * numpy.sin(angle_rad - phase_rad) noise = numpy.random.normal(loc=0.0, scale=noise_std, size=signal.shape) return signal + noise if __name__ == '__main__': # Design filter sampling_freq_hz = 50.0 cutoff_freq_hz = 2.5 order = 2 normalized_frequency = cutoff_freq_hz * 2 / sampling_freq_hz b, a = scipy.signal.butter(order, normalized_frequency, btype='lowpass') # Create test signal signal = sinusoid(sampling_frequency_Hz=sampling_freq_hz, signal_frequency_Hz=1.5, periods=3, amplitude=2.0, offset=2.0, phase_deg=25) # Apply zero-phase filters filtered_custom = custom_filtfilt(b, a, signal) filtered_scipy = scipy.signal.filtfilt(b, a, signal) # Verify near-equality numpy.testing.assert_array_almost_equal(filtered_custom, filtered_scipy, decimal=12) # Plot result pyplot.subplot(1, 2, 1) pyplot.plot(signal) pyplot.plot(filtered_scipy) pyplot.plot(filtered_custom, '.') pyplot.title('raw vs filtered signals') pyplot.legend(['raw', 'scipy filtfilt', 'custom filtfilt']) pyplot.subplot(1, 2, 2) pyplot.plot(filtered_scipy-filtered_custom) pyplot.title('difference (scipy vs custom)') pyplot.show()
This basic comparison yields a figure like below, suggesting equality to at least 14 decimals, for this specific case (machine precision, I guess?):