# Matlab filtfilt() function implementation in Java

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.

• do one convolution left to right, then redo it right to left on the result, that's your `filtfilt` – Hoki Dec 1 '14 at 11:18

## 2 Answers

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 `Python`'s `scipy.signal.filtfilt`, based on its source and documentation (so, not `Java`, nor `C++`, but `Python`). I believe the `scipy` version works the same way as `Matlab`'s.

To keep things simple, the code below was written specifically for a second order IIR filter, and it assumes the coefficient vectors `a` and `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 `scipy.signal.lfilter_zi` (docs).

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[0]=1):

y[n] = b[0]*x[n] + b[1]*x[n-1] + b[2]*x[n-2] + ...
- a[1]*y[n-1] - a[2]*y[n-2]

"""
# State space representation (transposed direct form II)
A = numpy.array([[-a[1], 1], [-a[2], 0]])
B = numpy.array([b[1] - b[0] * a[1], b[2] - b[0] * a[2]])
C = numpy.array([1.0, 0.0])
D = b[0]

# 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[0]

# 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[0] + b[0]*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[0] - 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 `custom` output:

``````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?):