Metadata-Version: 2.1
Name: adaptfilt
Version: 0.3
Summary: Adaptive filtering module for Python
Home-page: https://github.com/Wramberg/adaptfilt
Author: Jesper Wramberg & Mathias Tausen
Author-email: jesper.wramberg@gmail.com & mathias.tausen@gmail.com
License: MIT
Keywords: adaptive filter,adaptive filtering,signal processing,lms,apa,nlms,rls
Classifier: Development Status :: 5 - Production/Stable
Classifier: Programming Language :: Python
Classifier: Intended Audience :: Education
Classifier: Intended Audience :: Developers
Classifier: Topic :: Software Development :: Libraries :: Python Modules
License-File: LICENSE.txt

Adaptfilt
=========

Adaptfilt is an adaptive filtering module for Python. It includes simple, procedural implementations of the following filtering algorithms:

* **Least-mean-squares (LMS)** - including traditional and leaky filtering
* **Normalized least-mean-squares (NLMS)** - including traditional and leaky filtering with recursively updated input energy
* **Affine projection (AP)** - including traditional and leaky filtering
* **Recursive least squares (RLS)**

The algorithms are implemented using Numpy for computational efficiency. Further optimization have also been done, but this is very limited and only on the most computationally intensive parts of the source code.

| **Authors**: Jesper Wramberg & Mathias Tausen
| **Version**: 0.3
| **PyPI**: https://pypi.python.org/pypi/adaptfilt
| **GitHub**: https://github.com/Wramberg/adaptfilt
| **License**: MIT

Installation
------------
To install from PyPI using pip simply run::

   sudo pip install adaptfilt

Alternatively, the module can also be downloaded at https://pypi.python.org/pypi/adaptfilt or 
https://github.com/Wramberg/adaptfilt. The latter is also used for issue tracking. Note that adaptfilt requires Numpy to run (tested using version 1.9.0).

Usage
-----
Once installed, the module should be available for import by calling::

   import adaptfilt

Following the reference sections, examples are provided to show the modules functionality. Please do not hesitate to star us on GitHub if you found the module useful.

Function Reference
------------------
In this section, the functions provided by adaptfilt are described. The descriptions correspond with excerpts from the function docstrings and are only included here for your convenience.

**y, e, w = lms(u, d, M, step, leak=0., initCoeffs=None, N=None, returnCoeffs=False)**

    Perform least-mean-squares (LMS) adaptive filtering on u to minimize error
    given by e=d-y, where y is the output of the adaptive filter.

    Parameters
        u : array-like
            One-dimensional filter input.
        d : array-like
            One-dimensional desired signal, i.e., the output of the unknown FIR
            system which the adaptive filter should identify. Must have length >=
            len(u), or N+M-1 if number of iterations are limited (via the N
            parameter).
        M : int
            Desired number of filter taps (desired filter order + 1), must be
            non-negative.
        step : float
            Step size of the algorithm, must be non-negative.

    Optional Parameters
        leak : float
            Leakage factor, must be equal to or greater than zero and smaller than
            one. When greater than zero a leaky LMS filter is used. Defaults to 0,
            i.e., no leakage.
        initCoeffs : array-like
            Initial filter coefficients to use. Should match desired number of
            filter taps, defaults to zeros.
        N : int
            Number of iterations, must be less than or equal to len(u)-M+1
            (default).
        returnCoeffs : boolean
            If true, will return all filter coefficients for every iteration in an
            N x M matrix. Does not include the initial coefficients. If false, only
            the latest coefficients in a vector of length M is returned. Defaults
            to false.

    Returns
        y : numpy.array
            Output values of LMS filter, array of length N.
        e : numpy.array
            Error signal, i.e, d-y. Array of length N.
        w : numpy.array
            Final filter coefficients in array of length M if returnCoeffs is
            False. NxM array containing all filter coefficients for all iterations
            otherwise.

    Raises
        TypeError
            If number of filter taps M is not type integer, number of iterations N
            is not type integer, or leakage leak is not type float/int.
        ValueError
            If number of iterations N is greater than len(u)-M, number of filter
            taps M is negative, or if step-size or leakage is outside specified
            range.

**y, e, w = nlmsru(u, d, M, step, eps=0.001, leak=0, initCoeffs=None, N=None, returnCoeffs=False)**

    Same as nlms but updates input energy recursively for faster computation. Note that this can cause instability due to rounding errors.

**y, e, w = nlms(u, d, M, step, eps=0.001, leak=0, initCoeffs=None, N=None, returnCoeffs=False)**

    Perform normalized least-mean-squares (NLMS) adaptive filtering on u to
    minimize error given by e=d-y, where y is the output of the adaptive
    filter.

    Parameters
        u : array-like
            One-dimensional filter input.
        d : array-like
            One-dimensional desired signal, i.e., the output of the unknown FIR
            system which the adaptive filter should identify. Must have length >=
            len(u), or N+M-1 if number of iterations are limited (via the N
            parameter).
        M : int
            Desired number of filter taps (desired filter order + 1), must be
            non-negative.
        step : float
            Step size of the algorithm, must be non-negative.

    Optional Parameters
        eps : float
            Regularization factor to avoid numerical issues when power of input
            is close to zero. Defaults to 0.001. Must be non-negative.
        leak : float
            Leakage factor, must be equal to or greater than zero and smaller than
            one. When greater than zero a leaky LMS filter is used. Defaults to 0,
            i.e., no leakage.
        initCoeffs : array-like
            Initial filter coefficients to use. Should match desired number of
            filter taps, defaults to zeros.
        N : int
            Number of iterations to run. Must be less than or equal to len(u)-M+1.
            Defaults to len(u)-M+1.
        returnCoeffs : boolean
            If true, will return all filter coefficients for every iteration in an
            N x M matrix. Does not include the initial coefficients. If false, only
            the latest coefficients in a vector of length M is returned. Defaults
            to false.

    Returns
        y : numpy.array
            Output values of LMS filter, array of length N.
        e : numpy.array
            Error signal, i.e, d-y. Array of length N.
        w : numpy.array
            Final filter coefficients in array of length M if returnCoeffs is
            False. NxM array containing all filter coefficients for all iterations
            otherwise.

    Raises
        TypeError
            If number of filter taps M is not type integer, number of iterations N
            is not type integer, or leakage leak is not type float/int.
        ValueError
            If number of iterations N is greater than len(u)-M, number of filter
            taps M is negative, or if step-size or leakage is outside specified
            range.


**y, e, w = ap(u, d, M, step, K, eps=0.001, leak=0, initCoeffs=None, N=None, returnCoeffs=False)**

    Perform affine projection (AP) adaptive filtering on u to minimize error
    given by e=d-y, where y is the output of the adaptive filter.

    Parameters
        u : array-like
            One-dimensional filter input.
        d : array-like
            One-dimensional desired signal, i.e., the output of the unknown FIR
            system which the adaptive filter should identify. Must have length >=
            len(u), or N+M-1 if number of iterations are limited (via the N
            parameter).
        M : int
            Desired number of filter taps (desired filter order + 1), must be
            non-negative.
        step : float
            Step size of the algorithm, must be non-negative.
        K : int
            Projection order, must be integer larger than zero.

    Optional Parameters
        eps : float
            Regularization factor to avoid numerical issues when power of input
            is close to zero. Defaults to 0.001. Must be non-negative.
        leak : float
            Leakage factor, must be equal to or greater than zero and smaller than
            one. When greater than zero a leaky LMS filter is used. Defaults to 0,
            i.e., no leakage.
        initCoeffs : array-like
            Initial filter coefficients to use. Should match desired number of
            filter taps, defaults to zeros.
        N : int
            Number of iterations to run. Must be less than or equal to len(u)-M+1.
            Defaults to len(u)-M+1.
        returnCoeffs : boolean
            If true, will return all filter coefficients for every iteration in an
            N x M matrix. Does not include the initial coefficients. If false, only
            the latest coefficients in a vector of length M is returned. Defaults
            to false.

    Returns
        y : numpy.array
            Output values of LMS filter, array of length N.
        e : numpy.array
            Error signal, i.e, d-y. Array of length N.
        w : numpy.array
            Final filter coefficients in array of length M if returnCoeffs is
            False. NxM array containing all filter coefficients for all iterations
            otherwise.

    Raises
        TypeError
            If number of filter taps M is not type integer, number of iterations N
            is not type integer, or leakage leak is not type float/int.
        ValueError
            If number of iterations N is greater than len(u)-M, number of filter
            taps M is negative, or if step-size or leakage is outside specified
            range.


Helper Function Reference
-------------------------
**mswe = mswe(w, v)**

    Calculate mean squared weight error between estimated and true filter
    coefficients, in respect to iterations.

    Parameters
        v : array-like
            True coefficients used to generate desired signal, must be a
            one-dimensional array.
        w : array-like
            Estimated coefficients from adaptive filtering algorithm. Must be an
            N x M matrix where N is the number of iterations, and M is the number
            of filter coefficients.

    Returns
        mswe : numpy.array
            One-dimensional array containing the mean-squared weight error for
            every iteration.

    Raises
        TypeError
            If inputs have wrong dimensions

    Note
        To use this function with the adaptive filter functions set the optional
        parameter returnCoeffs to True. This will return a coefficient matrix w
        corresponding with the input-parameter w.


Examples
--------
The following examples illustrate the use of the adaptfilt module. Note that the matplotlib.pyplot module is required to run them. 

Acoustic echo cancellation
++++++++++++++++++++++++++
::

  """
  Acoustic echo cancellation in white background noise with NLMS.

  Consider a scenario where two individuals, John and Emily, are talking over the
  Internet. John is using his loudspeakers, which means Emily can hear herself
  through John's microphone. The speech signal that Emily hears, is a distorted
  version of her own. This is caused by the acoustic path from John's
  loudspeakers to his microphone. This path includes attenuated echoes, etc.

  Now for the problem!

  Emily wishes to cancel the echo she hears from John's microphone. Emily only
  knows the speech signal she sends to him, call that u(n), and the speech signal
  she receives from him, call that d(n). To successfully remove her own echo
  from d(n), she must approximate the acoustic path from John's loudspeakers to
  his microphone. This path can be approximated by a FIR filter, which means an
  adaptive NLMS FIR filter can be used to identify it. The model which Emily uses
  to design this filter looks like this:

        u(n) ------->->------+----------->->-----------
                             |                        |
                    +-----------------+      +------------------+
                +->-| Adaptive filter |      |    John's Room   |
                |   +-----------------+      +------------------+
                |            | -y(n)                  |
                |            |           d(n)         |
        e(n) ---+---<-<------+-----------<-<----------+----<-<---- v(n)

  As seen, the signal that is sent to John is also used as input to the adaptive
  NLMS filter. The output of the filter, y(n), is subtracted from the signal
  received from John, which results in an error signal e(n) = d(n)-y(n). By
  feeding the error signal back to the adaptive filter, it can minimize the error
  by approximating the impulse response (that is the FIR filter coefficients) of
  John's room. Note that so far John's speech signal v(n) has not been taken into
  account. If John speaks, the error should equal his speech, that is, e(n)
  should equal v(n). For this simple example, however, we assume John is quiet
  and v(n) is equal to white Gaussian background noise with zero-mean.

  In the following example we keep the impulse response of John's room constant.
  This is not required, however, since the advantage of adaptive filters, is that
  they can be used to track changes in the impulse response.

  A short speech sample is included in speech.npy, available on github or pypi in
  the examples folder. The sample is single-channel and is in floating-point
  format to keep the example simple. The original recording is sampled at 44.1
  kHz, and has been downsampled by a factor of 4. To listen to any of the audio
  signals of the example, they can be normalized and stored as wav files with
  scipy:

      from scipy.io.wavfile import write
      write("d.wav", 44100/4, d/np.max(d))
  """

  import numpy as np
  import matplotlib.pyplot as plt
  import adaptfilt as adf

  # Get u(n) - this is available on github or pypi in the examples folder
  u = np.load('speech.npy')

  # Generate received signal d(n) using randomly chosen coefficients
  coeffs = np.concatenate(([0.8], np.zeros(8), [-0.7], np.zeros(9),
                           [0.5], np.zeros(11), [-0.3], np.zeros(3),
                           [0.1], np.zeros(20), [-0.05]))

  d = np.convolve(u, coeffs)

  # Add background noise
  v = np.random.randn(len(d)) * np.sqrt(5000)
  d += v

  # Apply adaptive filter
  M = 100  # Number of filter taps in adaptive filter
  step = 0.1  # Step size
  y, e, w = adf.nlms(u, d, M, step, returnCoeffs=True)

  # Calculate mean square weight error
  mswe = adf.mswe(w, coeffs)

  # Plot speech signals
  plt.figure()
  plt.title("Speech signals")
  plt.plot(u, label="Emily's speech signal, u(n)")
  plt.plot(d, label="Speech signal from John, d(n)")
  plt.grid()
  plt.legend()
  plt.xlabel('Samples')

  # Plot error signal - note how the measurement noise affects the error
  plt.figure()
  plt.title('Error signal e(n)')
  plt.plot(e)
  plt.grid()
  plt.xlabel('Samples')

  # Plot mean squared weight error - note that the measurement noise causes the
  # error the increase at some points when Emily isn't speaking
  plt.figure()
  plt.title('Mean squared weight error')
  plt.plot(mswe)
  plt.grid()
  plt.xlabel('Samples')

  # Plot final coefficients versus real coefficients
  plt.figure()
  plt.title('Real coefficients vs. estimated coefficients')
  plt.plot(w[-1], 'g', label='Estimated coefficients')
  plt.plot(coeffs, 'b--', label='Real coefficients')
  plt.grid()
  plt.legend()
  plt.xlabel('Samples')

  plt.show()

.. image:: https://raw.githubusercontent.com/Wramberg/adaptfilt/master/examples/echocancel-input.png
.. image:: https://raw.githubusercontent.com/Wramberg/adaptfilt/master/examples/echocancel-error.png
.. image:: https://raw.githubusercontent.com/Wramberg/adaptfilt/master/examples/echocancel-mswe.png
.. image:: https://raw.githubusercontent.com/Wramberg/adaptfilt/master/examples/echocancel-coeffs.png


Convergence comparison
++++++++++++++++++++++
::

   """
   Convergence comparison of different adaptive filtering algorithms (with
   different step sizes) in white Gaussian noise.
   """
   
   import numpy as np
   import matplotlib.pyplot as plt
   import adaptfilt as adf
   
   # Generating input and desired signal
   N = 3000
   coeffs = np.concatenate(([-4, 3.2], np.zeros(20), [0.7], np.zeros(33), [-0.1]))
   u = np.random.randn(N)
   d = np.convolve(u, coeffs)
   
   # Perform filtering
   M = 60  # No. of taps to estimate
   mu1 = 0.0008  # Step size 1 in LMS
   mu2 = 0.0004  # Step size 1 in LMS
   beta1 = 0.08  # Step size 2 in NLMS and AP
   beta2 = 0.04  # Step size 2 in NLMS and AP
   K = 3  # Projection order 1 in AP
   
   # LMS
   y_lms1, e_lms1, w_lms1 = adf.lms(u, d, M, mu1, returnCoeffs=True)
   y_lms2, e_lms2, w_lms2 = adf.lms(u, d, M, mu2, returnCoeffs=True)
   mswe_lms1 = adf.mswe(w_lms1, coeffs)
   mswe_lms2 = adf.mswe(w_lms2, coeffs)
   
   # NLMS
   y_nlms1, e_nlms1, w_nlms1 = adf.nlms(u, d, M, beta1, returnCoeffs=True)
   y_nlms2, e_nlms2, w_nlms2 = adf.nlms(u, d, M, beta2, returnCoeffs=True)
   mswe_nlms1 = adf.mswe(w_nlms1, coeffs)
   mswe_nlms2 = adf.mswe(w_nlms2, coeffs)
   
   # AP
   y_ap1, e_ap1, w_ap1 = adf.ap(u, d, M, beta1, K, returnCoeffs=True)
   y_ap2, e_ap2, w_ap2 = adf.ap(u, d, M, beta2, K, returnCoeffs=True)
   mswe_ap1 = adf.mswe(w_ap1, coeffs)
   mswe_ap2 = adf.mswe(w_ap2, coeffs)
   
   # Plot results
   plt.figure()
   plt.title('Convergence comparison of different adaptive filtering algorithms')
   plt.plot(mswe_lms1, 'b', label='LMS with stepsize=%.4f' % mu1)
   plt.plot(mswe_lms2, 'b--', label='LMS with stepsize=%.4f' % mu2)
   plt.plot(mswe_nlms1, 'g', label='NLMS with stepsize=%.2f' % beta1)
   plt.plot(mswe_nlms2, 'g--', label='NLMS with stepsize=%.2f' % beta2)
   plt.plot(mswe_ap1, 'r', label='AP with stepsize=%.2f' % beta1)
   plt.plot(mswe_ap2, 'r--', label='AP with stepsize=%.2f' % beta2)
   plt.legend()
   plt.grid()
   plt.xlabel('Iterations')
   plt.ylabel('Mean-squared weight error')
   plt.show()

.. image:: https://raw.githubusercontent.com/Wramberg/adaptfilt/master/examples/convergence-result.png

Release History
---------------
0.3
+++
| Included RLS filtering function.
| Added support for complex signals.
| Support Python 3

0.2
+++
| Included NLMS filtering function with recursive updates of input energy.
| Included acoustic echo cancellation example.

0.1
+++
| Initial module with LMS, NLMS and AP filtering functions.
