forked from 170010011/fr
4425 lines
148 KiB
Python
4425 lines
148 KiB
Python
# Author: Travis Oliphant
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# 1999 -- 2002
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import operator
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import math
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import timeit
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from scipy.spatial import cKDTree
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from . import sigtools, dlti
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from ._upfirdn import upfirdn, _output_len, _upfirdn_modes
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from scipy import linalg, fft as sp_fft
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from scipy.fft._helper import _init_nd_shape_and_axes
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from scipy._lib._util import prod as _prod
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import numpy as np
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from scipy.special import lambertw
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from .windows import get_window
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from ._arraytools import axis_slice, axis_reverse, odd_ext, even_ext, const_ext
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from .filter_design import cheby1, _validate_sos
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from .fir_filter_design import firwin
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from ._sosfilt import _sosfilt
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import warnings
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__all__ = ['correlate', 'correlation_lags', 'correlate2d',
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'convolve', 'convolve2d', 'fftconvolve', 'oaconvolve',
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'order_filter', 'medfilt', 'medfilt2d', 'wiener', 'lfilter',
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'lfiltic', 'sosfilt', 'deconvolve', 'hilbert', 'hilbert2',
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'cmplx_sort', 'unique_roots', 'invres', 'invresz', 'residue',
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'residuez', 'resample', 'resample_poly', 'detrend',
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'lfilter_zi', 'sosfilt_zi', 'sosfiltfilt', 'choose_conv_method',
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'filtfilt', 'decimate', 'vectorstrength']
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_modedict = {'valid': 0, 'same': 1, 'full': 2}
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_boundarydict = {'fill': 0, 'pad': 0, 'wrap': 2, 'circular': 2, 'symm': 1,
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'symmetric': 1, 'reflect': 4}
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def _valfrommode(mode):
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try:
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return _modedict[mode]
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except KeyError as e:
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raise ValueError("Acceptable mode flags are 'valid',"
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" 'same', or 'full'.") from e
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def _bvalfromboundary(boundary):
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try:
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return _boundarydict[boundary] << 2
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except KeyError as e:
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raise ValueError("Acceptable boundary flags are 'fill', 'circular' "
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"(or 'wrap'), and 'symmetric' (or 'symm').") from e
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def _inputs_swap_needed(mode, shape1, shape2, axes=None):
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"""Determine if inputs arrays need to be swapped in `"valid"` mode.
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If in `"valid"` mode, returns whether or not the input arrays need to be
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swapped depending on whether `shape1` is at least as large as `shape2` in
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every calculated dimension.
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This is important for some of the correlation and convolution
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implementations in this module, where the larger array input needs to come
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before the smaller array input when operating in this mode.
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Note that if the mode provided is not 'valid', False is immediately
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returned.
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"""
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if mode != 'valid':
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return False
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if not shape1:
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return False
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if axes is None:
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axes = range(len(shape1))
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ok1 = all(shape1[i] >= shape2[i] for i in axes)
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ok2 = all(shape2[i] >= shape1[i] for i in axes)
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if not (ok1 or ok2):
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raise ValueError("For 'valid' mode, one must be at least "
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"as large as the other in every dimension")
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return not ok1
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def correlate(in1, in2, mode='full', method='auto'):
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r"""
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Cross-correlate two N-dimensional arrays.
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Cross-correlate `in1` and `in2`, with the output size determined by the
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`mode` argument.
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Parameters
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----------
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in1 : array_like
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First input.
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in2 : array_like
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Second input. Should have the same number of dimensions as `in1`.
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mode : str {'full', 'valid', 'same'}, optional
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A string indicating the size of the output:
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``full``
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The output is the full discrete linear cross-correlation
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of the inputs. (Default)
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``valid``
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The output consists only of those elements that do not
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rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
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must be at least as large as the other in every dimension.
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``same``
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The output is the same size as `in1`, centered
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with respect to the 'full' output.
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method : str {'auto', 'direct', 'fft'}, optional
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A string indicating which method to use to calculate the correlation.
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``direct``
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The correlation is determined directly from sums, the definition of
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correlation.
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``fft``
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The Fast Fourier Transform is used to perform the correlation more
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quickly (only available for numerical arrays.)
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``auto``
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Automatically chooses direct or Fourier method based on an estimate
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of which is faster (default). See `convolve` Notes for more detail.
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.. versionadded:: 0.19.0
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Returns
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-------
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correlate : array
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An N-dimensional array containing a subset of the discrete linear
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cross-correlation of `in1` with `in2`.
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See Also
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--------
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choose_conv_method : contains more documentation on `method`.
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correlation_lags : calculates the lag / displacement indices array for 1D
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cross-correlation.
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Notes
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-----
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The correlation z of two d-dimensional arrays x and y is defined as::
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z[...,k,...] = sum[..., i_l, ...] x[..., i_l,...] * conj(y[..., i_l - k,...])
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This way, if x and y are 1-D arrays and ``z = correlate(x, y, 'full')``
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then
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.. math::
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z[k] = (x * y)(k - N + 1)
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= \sum_{l=0}^{||x||-1}x_l y_{l-k+N-1}^{*}
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for :math:`k = 0, 1, ..., ||x|| + ||y|| - 2`
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where :math:`||x||` is the length of ``x``, :math:`N = \max(||x||,||y||)`,
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and :math:`y_m` is 0 when m is outside the range of y.
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``method='fft'`` only works for numerical arrays as it relies on
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`fftconvolve`. In certain cases (i.e., arrays of objects or when
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rounding integers can lose precision), ``method='direct'`` is always used.
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When using "same" mode with even-length inputs, the outputs of `correlate`
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and `correlate2d` differ: There is a 1-index offset between them.
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Examples
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--------
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Implement a matched filter using cross-correlation, to recover a signal
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that has passed through a noisy channel.
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>>> from scipy import signal
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>>> import matplotlib.pyplot as plt
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>>> sig = np.repeat([0., 1., 1., 0., 1., 0., 0., 1.], 128)
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>>> sig_noise = sig + np.random.randn(len(sig))
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>>> corr = signal.correlate(sig_noise, np.ones(128), mode='same') / 128
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>>> clock = np.arange(64, len(sig), 128)
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>>> fig, (ax_orig, ax_noise, ax_corr) = plt.subplots(3, 1, sharex=True)
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>>> ax_orig.plot(sig)
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>>> ax_orig.plot(clock, sig[clock], 'ro')
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>>> ax_orig.set_title('Original signal')
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>>> ax_noise.plot(sig_noise)
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>>> ax_noise.set_title('Signal with noise')
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>>> ax_corr.plot(corr)
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>>> ax_corr.plot(clock, corr[clock], 'ro')
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>>> ax_corr.axhline(0.5, ls=':')
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>>> ax_corr.set_title('Cross-correlated with rectangular pulse')
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>>> ax_orig.margins(0, 0.1)
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>>> fig.tight_layout()
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>>> plt.show()
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Compute the cross-correlation of a noisy signal with the original signal.
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>>> x = np.arange(128) / 128
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>>> sig = np.sin(2 * np.pi * x)
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>>> sig_noise = sig + np.random.randn(len(sig))
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>>> corr = signal.correlate(sig_noise, sig)
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>>> lags = signal.correlation_lags(len(sig), len(sig_noise))
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>>> corr /= np.max(corr)
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>>> fig, (ax_orig, ax_noise, ax_corr) = plt.subplots(3, 1, figsize=(4.8, 4.8))
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>>> ax_orig.plot(sig)
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>>> ax_orig.set_title('Original signal')
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>>> ax_orig.set_xlabel('Sample Number')
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>>> ax_noise.plot(sig_noise)
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>>> ax_noise.set_title('Signal with noise')
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>>> ax_noise.set_xlabel('Sample Number')
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>>> ax_corr.plot(lags, corr)
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>>> ax_corr.set_title('Cross-correlated signal')
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>>> ax_corr.set_xlabel('Lag')
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>>> ax_orig.margins(0, 0.1)
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>>> ax_noise.margins(0, 0.1)
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>>> ax_corr.margins(0, 0.1)
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>>> fig.tight_layout()
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>>> plt.show()
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"""
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in1 = np.asarray(in1)
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in2 = np.asarray(in2)
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if in1.ndim == in2.ndim == 0:
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return in1 * in2.conj()
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elif in1.ndim != in2.ndim:
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raise ValueError("in1 and in2 should have the same dimensionality")
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# Don't use _valfrommode, since correlate should not accept numeric modes
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try:
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val = _modedict[mode]
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except KeyError as e:
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raise ValueError("Acceptable mode flags are 'valid',"
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" 'same', or 'full'.") from e
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# this either calls fftconvolve or this function with method=='direct'
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if method in ('fft', 'auto'):
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return convolve(in1, _reverse_and_conj(in2), mode, method)
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elif method == 'direct':
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# fastpath to faster numpy.correlate for 1d inputs when possible
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if _np_conv_ok(in1, in2, mode):
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return np.correlate(in1, in2, mode)
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# _correlateND is far slower when in2.size > in1.size, so swap them
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# and then undo the effect afterward if mode == 'full'. Also, it fails
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# with 'valid' mode if in2 is larger than in1, so swap those, too.
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# Don't swap inputs for 'same' mode, since shape of in1 matters.
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swapped_inputs = ((mode == 'full') and (in2.size > in1.size) or
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_inputs_swap_needed(mode, in1.shape, in2.shape))
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if swapped_inputs:
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in1, in2 = in2, in1
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if mode == 'valid':
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ps = [i - j + 1 for i, j in zip(in1.shape, in2.shape)]
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out = np.empty(ps, in1.dtype)
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z = sigtools._correlateND(in1, in2, out, val)
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else:
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ps = [i + j - 1 for i, j in zip(in1.shape, in2.shape)]
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# zero pad input
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in1zpadded = np.zeros(ps, in1.dtype)
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sc = tuple(slice(0, i) for i in in1.shape)
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in1zpadded[sc] = in1.copy()
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if mode == 'full':
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out = np.empty(ps, in1.dtype)
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elif mode == 'same':
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out = np.empty(in1.shape, in1.dtype)
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z = sigtools._correlateND(in1zpadded, in2, out, val)
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if swapped_inputs:
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# Reverse and conjugate to undo the effect of swapping inputs
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z = _reverse_and_conj(z)
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return z
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else:
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raise ValueError("Acceptable method flags are 'auto',"
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" 'direct', or 'fft'.")
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def correlation_lags(in1_len, in2_len, mode='full'):
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r"""
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Calculates the lag / displacement indices array for 1D cross-correlation.
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Parameters
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----------
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in1_size : int
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First input size.
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in2_size : int
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Second input size.
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mode : str {'full', 'valid', 'same'}, optional
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A string indicating the size of the output.
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See the documentation `correlate` for more information.
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See Also
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--------
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correlate : Compute the N-dimensional cross-correlation.
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Returns
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-------
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lags : array
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Returns an array containing cross-correlation lag/displacement indices.
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Indices can be indexed with the np.argmax of the correlation to return
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the lag/displacement.
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Notes
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-----
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Cross-correlation for continuous functions :math:`f` and :math:`g` is
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defined as:
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.. math ::
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\left ( f\star g \right )\left ( \tau \right )
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\triangleq \int_{t_0}^{t_0 +T}
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\overline{f\left ( t \right )}g\left ( t+\tau \right )dt
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Where :math:`\tau` is defined as the displacement, also known as the lag.
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Cross correlation for discrete functions :math:`f` and :math:`g` is
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defined as:
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.. math ::
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\left ( f\star g \right )\left [ n \right ]
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\triangleq \sum_{-\infty}^{\infty}
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\overline{f\left [ m \right ]}g\left [ m+n \right ]
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Where :math:`n` is the lag.
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Examples
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--------
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Cross-correlation of a signal with its time-delayed self.
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>>> from scipy import signal
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>>> rng = np.random.RandomState(0)
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>>> x = rng.standard_normal(1000)
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>>> y = np.concatenate([rng.standard_normal(100), x])
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>>> correlation = signal.correlate(x, y, mode="full")
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>>> lags = signal.correlation_lags(x.size, y.size, mode="full")
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>>> lag = lags[np.argmax(correlation)]
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"""
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# calculate lag ranges in different modes of operation
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if mode == "full":
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# the output is the full discrete linear convolution
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# of the inputs. (Default)
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lags = np.arange(-in2_len + 1, in1_len)
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elif mode == "same":
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# the output is the same size as `in1`, centered
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# with respect to the 'full' output.
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# calculate the full output
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lags = np.arange(-in2_len + 1, in1_len)
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# determine the midpoint in the full output
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mid = lags.size // 2
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# determine lag_bound to be used with respect
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# to the midpoint
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lag_bound = in1_len // 2
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# calculate lag ranges for even and odd scenarios
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if in1_len % 2 == 0:
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lags = lags[(mid-lag_bound):(mid+lag_bound)]
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else:
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lags = lags[(mid-lag_bound):(mid+lag_bound)+1]
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elif mode == "valid":
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# the output consists only of those elements that do not
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# rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
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# must be at least as large as the other in every dimension.
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# the lag_bound will be either negative or positive
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# this let's us infer how to present the lag range
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lag_bound = in1_len - in2_len
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if lag_bound >= 0:
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lags = np.arange(lag_bound + 1)
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else:
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lags = np.arange(lag_bound, 1)
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return lags
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def _centered(arr, newshape):
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# Return the center newshape portion of the array.
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newshape = np.asarray(newshape)
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currshape = np.array(arr.shape)
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startind = (currshape - newshape) // 2
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endind = startind + newshape
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myslice = [slice(startind[k], endind[k]) for k in range(len(endind))]
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return arr[tuple(myslice)]
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def _init_freq_conv_axes(in1, in2, mode, axes, sorted_axes=False):
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"""Handle the axes argument for frequency-domain convolution.
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Returns the inputs and axes in a standard form, eliminating redundant axes,
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swapping the inputs if necessary, and checking for various potential
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errors.
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Parameters
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----------
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in1 : array
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First input.
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in2 : array
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Second input.
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mode : str {'full', 'valid', 'same'}, optional
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A string indicating the size of the output.
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See the documentation `fftconvolve` for more information.
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axes : list of ints
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Axes over which to compute the FFTs.
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sorted_axes : bool, optional
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If `True`, sort the axes.
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Default is `False`, do not sort.
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Returns
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-------
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in1 : array
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The first input, possible swapped with the second input.
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in2 : array
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The second input, possible swapped with the first input.
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axes : list of ints
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Axes over which to compute the FFTs.
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"""
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s1 = in1.shape
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s2 = in2.shape
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noaxes = axes is None
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_, axes = _init_nd_shape_and_axes(in1, shape=None, axes=axes)
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if not noaxes and not len(axes):
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raise ValueError("when provided, axes cannot be empty")
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# Axes of length 1 can rely on broadcasting rules for multipy,
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# no fft needed.
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axes = [a for a in axes if s1[a] != 1 and s2[a] != 1]
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if sorted_axes:
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axes.sort()
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if not all(s1[a] == s2[a] or s1[a] == 1 or s2[a] == 1
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for a in range(in1.ndim) if a not in axes):
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raise ValueError("incompatible shapes for in1 and in2:"
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" {0} and {1}".format(s1, s2))
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# Check that input sizes are compatible with 'valid' mode.
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if _inputs_swap_needed(mode, s1, s2, axes=axes):
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# Convolution is commutative; order doesn't have any effect on output.
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in1, in2 = in2, in1
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return in1, in2, axes
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def _freq_domain_conv(in1, in2, axes, shape, calc_fast_len=False):
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"""Convolve two arrays in the frequency domain.
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This function implements only base the FFT-related operations.
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Specifically, it converts the signals to the frequency domain, multiplies
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them, then converts them back to the time domain. Calculations of axes,
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shapes, convolution mode, etc. are implemented in higher level-functions,
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such as `fftconvolve` and `oaconvolve`. Those functions should be used
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instead of this one.
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Parameters
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----------
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in1 : array_like
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First input.
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in2 : array_like
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Second input. Should have the same number of dimensions as `in1`.
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axes : array_like of ints
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Axes over which to compute the FFTs.
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shape : array_like of ints
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The sizes of the FFTs.
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calc_fast_len : bool, optional
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If `True`, set each value of `shape` to the next fast FFT length.
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Default is `False`, use `axes` as-is.
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Returns
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-------
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out : array
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An N-dimensional array containing the discrete linear convolution of
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`in1` with `in2`.
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"""
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if not len(axes):
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return in1 * in2
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complex_result = (in1.dtype.kind == 'c' or in2.dtype.kind == 'c')
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if calc_fast_len:
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# Speed up FFT by padding to optimal size.
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fshape = [
|
|
sp_fft.next_fast_len(shape[a], not complex_result) for a in axes]
|
|
else:
|
|
fshape = shape
|
|
|
|
if not complex_result:
|
|
fft, ifft = sp_fft.rfftn, sp_fft.irfftn
|
|
else:
|
|
fft, ifft = sp_fft.fftn, sp_fft.ifftn
|
|
|
|
sp1 = fft(in1, fshape, axes=axes)
|
|
sp2 = fft(in2, fshape, axes=axes)
|
|
|
|
ret = ifft(sp1 * sp2, fshape, axes=axes)
|
|
|
|
if calc_fast_len:
|
|
fslice = tuple([slice(sz) for sz in shape])
|
|
ret = ret[fslice]
|
|
|
|
return ret
|
|
|
|
|
|
def _apply_conv_mode(ret, s1, s2, mode, axes):
|
|
"""Calculate the convolution result shape based on the `mode` argument.
|
|
|
|
Returns the result sliced to the correct size for the given mode.
|
|
|
|
Parameters
|
|
----------
|
|
ret : array
|
|
The result array, with the appropriate shape for the 'full' mode.
|
|
s1 : list of int
|
|
The shape of the first input.
|
|
s2 : list of int
|
|
The shape of the second input.
|
|
mode : str {'full', 'valid', 'same'}
|
|
A string indicating the size of the output.
|
|
See the documentation `fftconvolve` for more information.
|
|
axes : list of ints
|
|
Axes over which to compute the convolution.
|
|
|
|
Returns
|
|
-------
|
|
ret : array
|
|
A copy of `res`, sliced to the correct size for the given `mode`.
|
|
|
|
"""
|
|
if mode == "full":
|
|
return ret.copy()
|
|
elif mode == "same":
|
|
return _centered(ret, s1).copy()
|
|
elif mode == "valid":
|
|
shape_valid = [ret.shape[a] if a not in axes else s1[a] - s2[a] + 1
|
|
for a in range(ret.ndim)]
|
|
return _centered(ret, shape_valid).copy()
|
|
else:
|
|
raise ValueError("acceptable mode flags are 'valid',"
|
|
" 'same', or 'full'")
|
|
|
|
|
|
def fftconvolve(in1, in2, mode="full", axes=None):
|
|
"""Convolve two N-dimensional arrays using FFT.
|
|
|
|
Convolve `in1` and `in2` using the fast Fourier transform method, with
|
|
the output size determined by the `mode` argument.
|
|
|
|
This is generally much faster than `convolve` for large arrays (n > ~500),
|
|
but can be slower when only a few output values are needed, and can only
|
|
output float arrays (int or object array inputs will be cast to float).
|
|
|
|
As of v0.19, `convolve` automatically chooses this method or the direct
|
|
method based on an estimation of which is faster.
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
First input.
|
|
in2 : array_like
|
|
Second input. Should have the same number of dimensions as `in1`.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear convolution
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
|
|
must be at least as large as the other in every dimension.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
axes : int or array_like of ints or None, optional
|
|
Axes over which to compute the convolution.
|
|
The default is over all axes.
|
|
|
|
Returns
|
|
-------
|
|
out : array
|
|
An N-dimensional array containing a subset of the discrete linear
|
|
convolution of `in1` with `in2`.
|
|
|
|
See Also
|
|
--------
|
|
convolve : Uses the direct convolution or FFT convolution algorithm
|
|
depending on which is faster.
|
|
oaconvolve : Uses the overlap-add method to do convolution, which is
|
|
generally faster when the input arrays are large and
|
|
significantly different in size.
|
|
|
|
Examples
|
|
--------
|
|
Autocorrelation of white noise is an impulse.
|
|
|
|
>>> from scipy import signal
|
|
>>> sig = np.random.randn(1000)
|
|
>>> autocorr = signal.fftconvolve(sig, sig[::-1], mode='full')
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> fig, (ax_orig, ax_mag) = plt.subplots(2, 1)
|
|
>>> ax_orig.plot(sig)
|
|
>>> ax_orig.set_title('White noise')
|
|
>>> ax_mag.plot(np.arange(-len(sig)+1,len(sig)), autocorr)
|
|
>>> ax_mag.set_title('Autocorrelation')
|
|
>>> fig.tight_layout()
|
|
>>> fig.show()
|
|
|
|
Gaussian blur implemented using FFT convolution. Notice the dark borders
|
|
around the image, due to the zero-padding beyond its boundaries.
|
|
The `convolve2d` function allows for other types of image boundaries,
|
|
but is far slower.
|
|
|
|
>>> from scipy import misc
|
|
>>> face = misc.face(gray=True)
|
|
>>> kernel = np.outer(signal.windows.gaussian(70, 8),
|
|
... signal.windows.gaussian(70, 8))
|
|
>>> blurred = signal.fftconvolve(face, kernel, mode='same')
|
|
|
|
>>> fig, (ax_orig, ax_kernel, ax_blurred) = plt.subplots(3, 1,
|
|
... figsize=(6, 15))
|
|
>>> ax_orig.imshow(face, cmap='gray')
|
|
>>> ax_orig.set_title('Original')
|
|
>>> ax_orig.set_axis_off()
|
|
>>> ax_kernel.imshow(kernel, cmap='gray')
|
|
>>> ax_kernel.set_title('Gaussian kernel')
|
|
>>> ax_kernel.set_axis_off()
|
|
>>> ax_blurred.imshow(blurred, cmap='gray')
|
|
>>> ax_blurred.set_title('Blurred')
|
|
>>> ax_blurred.set_axis_off()
|
|
>>> fig.show()
|
|
"""
|
|
in1 = np.asarray(in1)
|
|
in2 = np.asarray(in2)
|
|
|
|
if in1.ndim == in2.ndim == 0: # scalar inputs
|
|
return in1 * in2
|
|
elif in1.ndim != in2.ndim:
|
|
raise ValueError("in1 and in2 should have the same dimensionality")
|
|
elif in1.size == 0 or in2.size == 0: # empty arrays
|
|
return np.array([])
|
|
|
|
in1, in2, axes = _init_freq_conv_axes(in1, in2, mode, axes,
|
|
sorted_axes=False)
|
|
|
|
s1 = in1.shape
|
|
s2 = in2.shape
|
|
|
|
shape = [max((s1[i], s2[i])) if i not in axes else s1[i] + s2[i] - 1
|
|
for i in range(in1.ndim)]
|
|
|
|
ret = _freq_domain_conv(in1, in2, axes, shape, calc_fast_len=True)
|
|
|
|
return _apply_conv_mode(ret, s1, s2, mode, axes)
|
|
|
|
|
|
def _calc_oa_lens(s1, s2):
|
|
"""Calculate the optimal FFT lengths for overlapp-add convolution.
|
|
|
|
The calculation is done for a single dimension.
|
|
|
|
Parameters
|
|
----------
|
|
s1 : int
|
|
Size of the dimension for the first array.
|
|
s2 : int
|
|
Size of the dimension for the second array.
|
|
|
|
Returns
|
|
-------
|
|
block_size : int
|
|
The size of the FFT blocks.
|
|
overlap : int
|
|
The amount of overlap between two blocks.
|
|
in1_step : int
|
|
The size of each step for the first array.
|
|
in2_step : int
|
|
The size of each step for the first array.
|
|
|
|
"""
|
|
# Set up the arguments for the conventional FFT approach.
|
|
fallback = (s1+s2-1, None, s1, s2)
|
|
|
|
# Use conventional FFT convolve if sizes are same.
|
|
if s1 == s2 or s1 == 1 or s2 == 1:
|
|
return fallback
|
|
|
|
if s2 > s1:
|
|
s1, s2 = s2, s1
|
|
swapped = True
|
|
else:
|
|
swapped = False
|
|
|
|
# There cannot be a useful block size if s2 is more than half of s1.
|
|
if s2 >= s1/2:
|
|
return fallback
|
|
|
|
# Derivation of optimal block length
|
|
# For original formula see:
|
|
# https://en.wikipedia.org/wiki/Overlap-add_method
|
|
#
|
|
# Formula:
|
|
# K = overlap = s2-1
|
|
# N = block_size
|
|
# C = complexity
|
|
# e = exponential, exp(1)
|
|
#
|
|
# C = (N*(log2(N)+1))/(N-K)
|
|
# C = (N*log2(2N))/(N-K)
|
|
# C = N/(N-K) * log2(2N)
|
|
# C1 = N/(N-K)
|
|
# C2 = log2(2N) = ln(2N)/ln(2)
|
|
#
|
|
# dC1/dN = (1*(N-K)-N)/(N-K)^2 = -K/(N-K)^2
|
|
# dC2/dN = 2/(2*N*ln(2)) = 1/(N*ln(2))
|
|
#
|
|
# dC/dN = dC1/dN*C2 + dC2/dN*C1
|
|
# dC/dN = -K*ln(2N)/(ln(2)*(N-K)^2) + N/(N*ln(2)*(N-K))
|
|
# dC/dN = -K*ln(2N)/(ln(2)*(N-K)^2) + 1/(ln(2)*(N-K))
|
|
# dC/dN = -K*ln(2N)/(ln(2)*(N-K)^2) + (N-K)/(ln(2)*(N-K)^2)
|
|
# dC/dN = (-K*ln(2N) + (N-K)/(ln(2)*(N-K)^2)
|
|
# dC/dN = (N - K*ln(2N) - K)/(ln(2)*(N-K)^2)
|
|
#
|
|
# Solve for minimum, where dC/dN = 0
|
|
# 0 = (N - K*ln(2N) - K)/(ln(2)*(N-K)^2)
|
|
# 0 * ln(2)*(N-K)^2 = N - K*ln(2N) - K
|
|
# 0 = N - K*ln(2N) - K
|
|
# 0 = N - K*(ln(2N) + 1)
|
|
# 0 = N - K*ln(2Ne)
|
|
# N = K*ln(2Ne)
|
|
# N/K = ln(2Ne)
|
|
#
|
|
# e^(N/K) = e^ln(2Ne)
|
|
# e^(N/K) = 2Ne
|
|
# 1/e^(N/K) = 1/(2*N*e)
|
|
# e^(N/-K) = 1/(2*N*e)
|
|
# e^(N/-K) = K/N*1/(2*K*e)
|
|
# N/K*e^(N/-K) = 1/(2*e*K)
|
|
# N/-K*e^(N/-K) = -1/(2*e*K)
|
|
#
|
|
# Using Lambert W function
|
|
# https://en.wikipedia.org/wiki/Lambert_W_function
|
|
# x = W(y) It is the solution to y = x*e^x
|
|
# x = N/-K
|
|
# y = -1/(2*e*K)
|
|
#
|
|
# N/-K = W(-1/(2*e*K))
|
|
#
|
|
# N = -K*W(-1/(2*e*K))
|
|
overlap = s2-1
|
|
opt_size = -overlap*lambertw(-1/(2*math.e*overlap), k=-1).real
|
|
block_size = sp_fft.next_fast_len(math.ceil(opt_size))
|
|
|
|
# Use conventional FFT convolve if there is only going to be one block.
|
|
if block_size >= s1:
|
|
return fallback
|
|
|
|
if not swapped:
|
|
in1_step = block_size-s2+1
|
|
in2_step = s2
|
|
else:
|
|
in1_step = s2
|
|
in2_step = block_size-s2+1
|
|
|
|
return block_size, overlap, in1_step, in2_step
|
|
|
|
|
|
def oaconvolve(in1, in2, mode="full", axes=None):
|
|
"""Convolve two N-dimensional arrays using the overlap-add method.
|
|
|
|
Convolve `in1` and `in2` using the overlap-add method, with
|
|
the output size determined by the `mode` argument.
|
|
|
|
This is generally much faster than `convolve` for large arrays (n > ~500),
|
|
and generally much faster than `fftconvolve` when one array is much
|
|
larger than the other, but can be slower when only a few output values are
|
|
needed or when the arrays are very similar in shape, and can only
|
|
output float arrays (int or object array inputs will be cast to float).
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
First input.
|
|
in2 : array_like
|
|
Second input. Should have the same number of dimensions as `in1`.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear convolution
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
|
|
must be at least as large as the other in every dimension.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
axes : int or array_like of ints or None, optional
|
|
Axes over which to compute the convolution.
|
|
The default is over all axes.
|
|
|
|
Returns
|
|
-------
|
|
out : array
|
|
An N-dimensional array containing a subset of the discrete linear
|
|
convolution of `in1` with `in2`.
|
|
|
|
See Also
|
|
--------
|
|
convolve : Uses the direct convolution or FFT convolution algorithm
|
|
depending on which is faster.
|
|
fftconvolve : An implementation of convolution using FFT.
|
|
|
|
Notes
|
|
-----
|
|
.. versionadded:: 1.4.0
|
|
|
|
Examples
|
|
--------
|
|
Convolve a 100,000 sample signal with a 512-sample filter.
|
|
|
|
>>> from scipy import signal
|
|
>>> sig = np.random.randn(100000)
|
|
>>> filt = signal.firwin(512, 0.01)
|
|
>>> fsig = signal.oaconvolve(sig, filt)
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> fig, (ax_orig, ax_mag) = plt.subplots(2, 1)
|
|
>>> ax_orig.plot(sig)
|
|
>>> ax_orig.set_title('White noise')
|
|
>>> ax_mag.plot(fsig)
|
|
>>> ax_mag.set_title('Filtered noise')
|
|
>>> fig.tight_layout()
|
|
>>> fig.show()
|
|
|
|
References
|
|
----------
|
|
.. [1] Wikipedia, "Overlap-add_method".
|
|
https://en.wikipedia.org/wiki/Overlap-add_method
|
|
.. [2] Richard G. Lyons. Understanding Digital Signal Processing,
|
|
Third Edition, 2011. Chapter 13.10.
|
|
ISBN 13: 978-0137-02741-5
|
|
|
|
"""
|
|
in1 = np.asarray(in1)
|
|
in2 = np.asarray(in2)
|
|
|
|
if in1.ndim == in2.ndim == 0: # scalar inputs
|
|
return in1 * in2
|
|
elif in1.ndim != in2.ndim:
|
|
raise ValueError("in1 and in2 should have the same dimensionality")
|
|
elif in1.size == 0 or in2.size == 0: # empty arrays
|
|
return np.array([])
|
|
elif in1.shape == in2.shape: # Equivalent to fftconvolve
|
|
return fftconvolve(in1, in2, mode=mode, axes=axes)
|
|
|
|
in1, in2, axes = _init_freq_conv_axes(in1, in2, mode, axes,
|
|
sorted_axes=True)
|
|
|
|
s1 = in1.shape
|
|
s2 = in2.shape
|
|
|
|
if not axes:
|
|
ret = in1 * in2
|
|
return _apply_conv_mode(ret, s1, s2, mode, axes)
|
|
|
|
# Calculate this now since in1 is changed later
|
|
shape_final = [None if i not in axes else
|
|
s1[i] + s2[i] - 1 for i in range(in1.ndim)]
|
|
|
|
# Calculate the block sizes for the output, steps, first and second inputs.
|
|
# It is simpler to calculate them all together than doing them in separate
|
|
# loops due to all the special cases that need to be handled.
|
|
optimal_sizes = ((-1, -1, s1[i], s2[i]) if i not in axes else
|
|
_calc_oa_lens(s1[i], s2[i]) for i in range(in1.ndim))
|
|
block_size, overlaps, \
|
|
in1_step, in2_step = zip(*optimal_sizes)
|
|
|
|
# Fall back to fftconvolve if there is only one block in every dimension.
|
|
if in1_step == s1 and in2_step == s2:
|
|
return fftconvolve(in1, in2, mode=mode, axes=axes)
|
|
|
|
# Figure out the number of steps and padding.
|
|
# This would get too complicated in a list comprehension.
|
|
nsteps1 = []
|
|
nsteps2 = []
|
|
pad_size1 = []
|
|
pad_size2 = []
|
|
for i in range(in1.ndim):
|
|
if i not in axes:
|
|
pad_size1 += [(0, 0)]
|
|
pad_size2 += [(0, 0)]
|
|
continue
|
|
|
|
if s1[i] > in1_step[i]:
|
|
curnstep1 = math.ceil((s1[i]+1)/in1_step[i])
|
|
if (block_size[i] - overlaps[i])*curnstep1 < shape_final[i]:
|
|
curnstep1 += 1
|
|
|
|
curpad1 = curnstep1*in1_step[i] - s1[i]
|
|
else:
|
|
curnstep1 = 1
|
|
curpad1 = 0
|
|
|
|
if s2[i] > in2_step[i]:
|
|
curnstep2 = math.ceil((s2[i]+1)/in2_step[i])
|
|
if (block_size[i] - overlaps[i])*curnstep2 < shape_final[i]:
|
|
curnstep2 += 1
|
|
|
|
curpad2 = curnstep2*in2_step[i] - s2[i]
|
|
else:
|
|
curnstep2 = 1
|
|
curpad2 = 0
|
|
|
|
nsteps1 += [curnstep1]
|
|
nsteps2 += [curnstep2]
|
|
pad_size1 += [(0, curpad1)]
|
|
pad_size2 += [(0, curpad2)]
|
|
|
|
# Pad the array to a size that can be reshaped to the desired shape
|
|
# if necessary.
|
|
if not all(curpad == (0, 0) for curpad in pad_size1):
|
|
in1 = np.pad(in1, pad_size1, mode='constant', constant_values=0)
|
|
|
|
if not all(curpad == (0, 0) for curpad in pad_size2):
|
|
in2 = np.pad(in2, pad_size2, mode='constant', constant_values=0)
|
|
|
|
# Reshape the overlap-add parts to input block sizes.
|
|
split_axes = [iax+i for i, iax in enumerate(axes)]
|
|
fft_axes = [iax+1 for iax in split_axes]
|
|
|
|
# We need to put each new dimension before the corresponding dimension
|
|
# being reshaped in order to get the data in the right layout at the end.
|
|
reshape_size1 = list(in1_step)
|
|
reshape_size2 = list(in2_step)
|
|
for i, iax in enumerate(split_axes):
|
|
reshape_size1.insert(iax, nsteps1[i])
|
|
reshape_size2.insert(iax, nsteps2[i])
|
|
|
|
in1 = in1.reshape(*reshape_size1)
|
|
in2 = in2.reshape(*reshape_size2)
|
|
|
|
# Do the convolution.
|
|
fft_shape = [block_size[i] for i in axes]
|
|
ret = _freq_domain_conv(in1, in2, fft_axes, fft_shape, calc_fast_len=False)
|
|
|
|
# Do the overlap-add.
|
|
for ax, ax_fft, ax_split in zip(axes, fft_axes, split_axes):
|
|
overlap = overlaps[ax]
|
|
if overlap is None:
|
|
continue
|
|
|
|
ret, overpart = np.split(ret, [-overlap], ax_fft)
|
|
overpart = np.split(overpart, [-1], ax_split)[0]
|
|
|
|
ret_overpart = np.split(ret, [overlap], ax_fft)[0]
|
|
ret_overpart = np.split(ret_overpart, [1], ax_split)[1]
|
|
ret_overpart += overpart
|
|
|
|
# Reshape back to the correct dimensionality.
|
|
shape_ret = [ret.shape[i] if i not in fft_axes else
|
|
ret.shape[i]*ret.shape[i-1]
|
|
for i in range(ret.ndim) if i not in split_axes]
|
|
ret = ret.reshape(*shape_ret)
|
|
|
|
# Slice to the correct size.
|
|
slice_final = tuple([slice(islice) for islice in shape_final])
|
|
ret = ret[slice_final]
|
|
|
|
return _apply_conv_mode(ret, s1, s2, mode, axes)
|
|
|
|
|
|
def _numeric_arrays(arrays, kinds='buifc'):
|
|
"""
|
|
See if a list of arrays are all numeric.
|
|
|
|
Parameters
|
|
----------
|
|
ndarrays : array or list of arrays
|
|
arrays to check if numeric.
|
|
numeric_kinds : string-like
|
|
The dtypes of the arrays to be checked. If the dtype.kind of
|
|
the ndarrays are not in this string the function returns False and
|
|
otherwise returns True.
|
|
"""
|
|
if type(arrays) == np.ndarray:
|
|
return arrays.dtype.kind in kinds
|
|
for array_ in arrays:
|
|
if array_.dtype.kind not in kinds:
|
|
return False
|
|
return True
|
|
|
|
|
|
def _conv_ops(x_shape, h_shape, mode):
|
|
"""
|
|
Find the number of operations required for direct/fft methods of
|
|
convolution. The direct operations were recorded by making a dummy class to
|
|
record the number of operations by overriding ``__mul__`` and ``__add__``.
|
|
The FFT operations rely on the (well-known) computational complexity of the
|
|
FFT (and the implementation of ``_freq_domain_conv``).
|
|
|
|
"""
|
|
if mode == "full":
|
|
out_shape = [n + k - 1 for n, k in zip(x_shape, h_shape)]
|
|
elif mode == "valid":
|
|
out_shape = [abs(n - k) + 1 for n, k in zip(x_shape, h_shape)]
|
|
elif mode == "same":
|
|
out_shape = x_shape
|
|
else:
|
|
raise ValueError("Acceptable mode flags are 'valid',"
|
|
" 'same', or 'full', not mode={}".format(mode))
|
|
|
|
s1, s2 = x_shape, h_shape
|
|
if len(x_shape) == 1:
|
|
s1, s2 = s1[0], s2[0]
|
|
if mode == "full":
|
|
direct_ops = s1 * s2
|
|
elif mode == "valid":
|
|
direct_ops = (s2 - s1 + 1) * s1 if s2 >= s1 else (s1 - s2 + 1) * s2
|
|
elif mode == "same":
|
|
direct_ops = (s1 * s2 if s1 < s2 else
|
|
s1 * s2 - (s2 // 2) * ((s2 + 1) // 2))
|
|
else:
|
|
if mode == "full":
|
|
direct_ops = min(_prod(s1), _prod(s2)) * _prod(out_shape)
|
|
elif mode == "valid":
|
|
direct_ops = min(_prod(s1), _prod(s2)) * _prod(out_shape)
|
|
elif mode == "same":
|
|
direct_ops = _prod(s1) * _prod(s2)
|
|
|
|
full_out_shape = [n + k - 1 for n, k in zip(x_shape, h_shape)]
|
|
N = _prod(full_out_shape)
|
|
fft_ops = 3 * N * np.log(N) # 3 separate FFTs of size full_out_shape
|
|
return fft_ops, direct_ops
|
|
|
|
|
|
def _fftconv_faster(x, h, mode):
|
|
"""
|
|
See if using fftconvolve or convolve is faster.
|
|
|
|
Parameters
|
|
----------
|
|
x : np.ndarray
|
|
Signal
|
|
h : np.ndarray
|
|
Kernel
|
|
mode : str
|
|
Mode passed to convolve
|
|
|
|
Returns
|
|
-------
|
|
fft_faster : bool
|
|
|
|
Notes
|
|
-----
|
|
See docstring of `choose_conv_method` for details on tuning hardware.
|
|
|
|
See pull request 11031 for more detail:
|
|
https://github.com/scipy/scipy/pull/11031.
|
|
|
|
"""
|
|
fft_ops, direct_ops = _conv_ops(x.shape, h.shape, mode)
|
|
offset = -1e-3 if x.ndim == 1 else -1e-4
|
|
constants = {
|
|
"valid": (1.89095737e-9, 2.1364985e-10, offset),
|
|
"full": (1.7649070e-9, 2.1414831e-10, offset),
|
|
"same": (3.2646654e-9, 2.8478277e-10, offset)
|
|
if h.size <= x.size
|
|
else (3.21635404e-9, 1.1773253e-8, -1e-5),
|
|
} if x.ndim == 1 else {
|
|
"valid": (1.85927e-9, 2.11242e-8, offset),
|
|
"full": (1.99817e-9, 1.66174e-8, offset),
|
|
"same": (2.04735e-9, 1.55367e-8, offset),
|
|
}
|
|
O_fft, O_direct, O_offset = constants[mode]
|
|
return O_fft * fft_ops < O_direct * direct_ops + O_offset
|
|
|
|
|
|
def _reverse_and_conj(x):
|
|
"""
|
|
Reverse array `x` in all dimensions and perform the complex conjugate
|
|
"""
|
|
reverse = (slice(None, None, -1),) * x.ndim
|
|
return x[reverse].conj()
|
|
|
|
|
|
def _np_conv_ok(volume, kernel, mode):
|
|
"""
|
|
See if numpy supports convolution of `volume` and `kernel` (i.e. both are
|
|
1D ndarrays and of the appropriate shape). NumPy's 'same' mode uses the
|
|
size of the larger input, while SciPy's uses the size of the first input.
|
|
|
|
Invalid mode strings will return False and be caught by the calling func.
|
|
"""
|
|
if volume.ndim == kernel.ndim == 1:
|
|
if mode in ('full', 'valid'):
|
|
return True
|
|
elif mode == 'same':
|
|
return volume.size >= kernel.size
|
|
else:
|
|
return False
|
|
|
|
|
|
def _timeit_fast(stmt="pass", setup="pass", repeat=3):
|
|
"""
|
|
Returns the time the statement/function took, in seconds.
|
|
|
|
Faster, less precise version of IPython's timeit. `stmt` can be a statement
|
|
written as a string or a callable.
|
|
|
|
Will do only 1 loop (like IPython's timeit) with no repetitions
|
|
(unlike IPython) for very slow functions. For fast functions, only does
|
|
enough loops to take 5 ms, which seems to produce similar results (on
|
|
Windows at least), and avoids doing an extraneous cycle that isn't
|
|
measured.
|
|
|
|
"""
|
|
timer = timeit.Timer(stmt, setup)
|
|
|
|
# determine number of calls per rep so total time for 1 rep >= 5 ms
|
|
x = 0
|
|
for p in range(0, 10):
|
|
number = 10**p
|
|
x = timer.timeit(number) # seconds
|
|
if x >= 5e-3 / 10: # 5 ms for final test, 1/10th that for this one
|
|
break
|
|
if x > 1: # second
|
|
# If it's macroscopic, don't bother with repetitions
|
|
best = x
|
|
else:
|
|
number *= 10
|
|
r = timer.repeat(repeat, number)
|
|
best = min(r)
|
|
|
|
sec = best / number
|
|
return sec
|
|
|
|
|
|
def choose_conv_method(in1, in2, mode='full', measure=False):
|
|
"""
|
|
Find the fastest convolution/correlation method.
|
|
|
|
This primarily exists to be called during the ``method='auto'`` option in
|
|
`convolve` and `correlate`. It can also be used to determine the value of
|
|
``method`` for many different convolutions of the same dtype/shape.
|
|
In addition, it supports timing the convolution to adapt the value of
|
|
``method`` to a particular set of inputs and/or hardware.
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
The first argument passed into the convolution function.
|
|
in2 : array_like
|
|
The second argument passed into the convolution function.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear convolution
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
measure : bool, optional
|
|
If True, run and time the convolution of `in1` and `in2` with both
|
|
methods and return the fastest. If False (default), predict the fastest
|
|
method using precomputed values.
|
|
|
|
Returns
|
|
-------
|
|
method : str
|
|
A string indicating which convolution method is fastest, either
|
|
'direct' or 'fft'
|
|
times : dict, optional
|
|
A dictionary containing the times (in seconds) needed for each method.
|
|
This value is only returned if ``measure=True``.
|
|
|
|
See Also
|
|
--------
|
|
convolve
|
|
correlate
|
|
|
|
Notes
|
|
-----
|
|
Generally, this method is 99% accurate for 2D signals and 85% accurate
|
|
for 1D signals for randomly chosen input sizes. For precision, use
|
|
``measure=True`` to find the fastest method by timing the convolution.
|
|
This can be used to avoid the minimal overhead of finding the fastest
|
|
``method`` later, or to adapt the value of ``method`` to a particular set
|
|
of inputs.
|
|
|
|
Experiments were run on an Amazon EC2 r5a.2xlarge machine to test this
|
|
function. These experiments measured the ratio between the time required
|
|
when using ``method='auto'`` and the time required for the fastest method
|
|
(i.e., ``ratio = time_auto / min(time_fft, time_direct)``). In these
|
|
experiments, we found:
|
|
|
|
* There is a 95% chance of this ratio being less than 1.5 for 1D signals
|
|
and a 99% chance of being less than 2.5 for 2D signals.
|
|
* The ratio was always less than 2.5/5 for 1D/2D signals respectively.
|
|
* This function is most inaccurate for 1D convolutions that take between 1
|
|
and 10 milliseconds with ``method='direct'``. A good proxy for this
|
|
(at least in our experiments) is ``1e6 <= in1.size * in2.size <= 1e7``.
|
|
|
|
The 2D results almost certainly generalize to 3D/4D/etc because the
|
|
implementation is the same (the 1D implementation is different).
|
|
|
|
All the numbers above are specific to the EC2 machine. However, we did find
|
|
that this function generalizes fairly decently across hardware. The speed
|
|
tests were of similar quality (and even slightly better) than the same
|
|
tests performed on the machine to tune this function's numbers (a mid-2014
|
|
15-inch MacBook Pro with 16GB RAM and a 2.5GHz Intel i7 processor).
|
|
|
|
There are cases when `fftconvolve` supports the inputs but this function
|
|
returns `direct` (e.g., to protect against floating point integer
|
|
precision).
|
|
|
|
.. versionadded:: 0.19
|
|
|
|
Examples
|
|
--------
|
|
Estimate the fastest method for a given input:
|
|
|
|
>>> from scipy import signal
|
|
>>> img = np.random.rand(32, 32)
|
|
>>> filter = np.random.rand(8, 8)
|
|
>>> method = signal.choose_conv_method(img, filter, mode='same')
|
|
>>> method
|
|
'fft'
|
|
|
|
This can then be applied to other arrays of the same dtype and shape:
|
|
|
|
>>> img2 = np.random.rand(32, 32)
|
|
>>> filter2 = np.random.rand(8, 8)
|
|
>>> corr2 = signal.correlate(img2, filter2, mode='same', method=method)
|
|
>>> conv2 = signal.convolve(img2, filter2, mode='same', method=method)
|
|
|
|
The output of this function (``method``) works with `correlate` and
|
|
`convolve`.
|
|
|
|
"""
|
|
volume = np.asarray(in1)
|
|
kernel = np.asarray(in2)
|
|
|
|
if measure:
|
|
times = {}
|
|
for method in ['fft', 'direct']:
|
|
times[method] = _timeit_fast(lambda: convolve(volume, kernel,
|
|
mode=mode, method=method))
|
|
|
|
chosen_method = 'fft' if times['fft'] < times['direct'] else 'direct'
|
|
return chosen_method, times
|
|
|
|
# for integer input,
|
|
# catch when more precision required than float provides (representing an
|
|
# integer as float can lose precision in fftconvolve if larger than 2**52)
|
|
if any([_numeric_arrays([x], kinds='ui') for x in [volume, kernel]]):
|
|
max_value = int(np.abs(volume).max()) * int(np.abs(kernel).max())
|
|
max_value *= int(min(volume.size, kernel.size))
|
|
if max_value > 2**np.finfo('float').nmant - 1:
|
|
return 'direct'
|
|
|
|
if _numeric_arrays([volume, kernel], kinds='b'):
|
|
return 'direct'
|
|
|
|
if _numeric_arrays([volume, kernel]):
|
|
if _fftconv_faster(volume, kernel, mode):
|
|
return 'fft'
|
|
|
|
return 'direct'
|
|
|
|
|
|
def convolve(in1, in2, mode='full', method='auto'):
|
|
"""
|
|
Convolve two N-dimensional arrays.
|
|
|
|
Convolve `in1` and `in2`, with the output size determined by the
|
|
`mode` argument.
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
First input.
|
|
in2 : array_like
|
|
Second input. Should have the same number of dimensions as `in1`.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear convolution
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
|
|
must be at least as large as the other in every dimension.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
method : str {'auto', 'direct', 'fft'}, optional
|
|
A string indicating which method to use to calculate the convolution.
|
|
|
|
``direct``
|
|
The convolution is determined directly from sums, the definition of
|
|
convolution.
|
|
``fft``
|
|
The Fourier Transform is used to perform the convolution by calling
|
|
`fftconvolve`.
|
|
``auto``
|
|
Automatically chooses direct or Fourier method based on an estimate
|
|
of which is faster (default). See Notes for more detail.
|
|
|
|
.. versionadded:: 0.19.0
|
|
|
|
Returns
|
|
-------
|
|
convolve : array
|
|
An N-dimensional array containing a subset of the discrete linear
|
|
convolution of `in1` with `in2`.
|
|
|
|
See Also
|
|
--------
|
|
numpy.polymul : performs polynomial multiplication (same operation, but
|
|
also accepts poly1d objects)
|
|
choose_conv_method : chooses the fastest appropriate convolution method
|
|
fftconvolve : Always uses the FFT method.
|
|
oaconvolve : Uses the overlap-add method to do convolution, which is
|
|
generally faster when the input arrays are large and
|
|
significantly different in size.
|
|
|
|
Notes
|
|
-----
|
|
By default, `convolve` and `correlate` use ``method='auto'``, which calls
|
|
`choose_conv_method` to choose the fastest method using pre-computed
|
|
values (`choose_conv_method` can also measure real-world timing with a
|
|
keyword argument). Because `fftconvolve` relies on floating point numbers,
|
|
there are certain constraints that may force `method=direct` (more detail
|
|
in `choose_conv_method` docstring).
|
|
|
|
Examples
|
|
--------
|
|
Smooth a square pulse using a Hann window:
|
|
|
|
>>> from scipy import signal
|
|
>>> sig = np.repeat([0., 1., 0.], 100)
|
|
>>> win = signal.windows.hann(50)
|
|
>>> filtered = signal.convolve(sig, win, mode='same') / sum(win)
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> fig, (ax_orig, ax_win, ax_filt) = plt.subplots(3, 1, sharex=True)
|
|
>>> ax_orig.plot(sig)
|
|
>>> ax_orig.set_title('Original pulse')
|
|
>>> ax_orig.margins(0, 0.1)
|
|
>>> ax_win.plot(win)
|
|
>>> ax_win.set_title('Filter impulse response')
|
|
>>> ax_win.margins(0, 0.1)
|
|
>>> ax_filt.plot(filtered)
|
|
>>> ax_filt.set_title('Filtered signal')
|
|
>>> ax_filt.margins(0, 0.1)
|
|
>>> fig.tight_layout()
|
|
>>> fig.show()
|
|
|
|
"""
|
|
volume = np.asarray(in1)
|
|
kernel = np.asarray(in2)
|
|
|
|
if volume.ndim == kernel.ndim == 0:
|
|
return volume * kernel
|
|
elif volume.ndim != kernel.ndim:
|
|
raise ValueError("volume and kernel should have the same "
|
|
"dimensionality")
|
|
|
|
if _inputs_swap_needed(mode, volume.shape, kernel.shape):
|
|
# Convolution is commutative; order doesn't have any effect on output
|
|
volume, kernel = kernel, volume
|
|
|
|
if method == 'auto':
|
|
method = choose_conv_method(volume, kernel, mode=mode)
|
|
|
|
if method == 'fft':
|
|
out = fftconvolve(volume, kernel, mode=mode)
|
|
result_type = np.result_type(volume, kernel)
|
|
if result_type.kind in {'u', 'i'}:
|
|
out = np.around(out)
|
|
return out.astype(result_type)
|
|
elif method == 'direct':
|
|
# fastpath to faster numpy.convolve for 1d inputs when possible
|
|
if _np_conv_ok(volume, kernel, mode):
|
|
return np.convolve(volume, kernel, mode)
|
|
|
|
return correlate(volume, _reverse_and_conj(kernel), mode, 'direct')
|
|
else:
|
|
raise ValueError("Acceptable method flags are 'auto',"
|
|
" 'direct', or 'fft'.")
|
|
|
|
|
|
def order_filter(a, domain, rank):
|
|
"""
|
|
Perform an order filter on an N-D array.
|
|
|
|
Perform an order filter on the array in. The domain argument acts as a
|
|
mask centered over each pixel. The non-zero elements of domain are
|
|
used to select elements surrounding each input pixel which are placed
|
|
in a list. The list is sorted, and the output for that pixel is the
|
|
element corresponding to rank in the sorted list.
|
|
|
|
Parameters
|
|
----------
|
|
a : ndarray
|
|
The N-dimensional input array.
|
|
domain : array_like
|
|
A mask array with the same number of dimensions as `a`.
|
|
Each dimension should have an odd number of elements.
|
|
rank : int
|
|
A non-negative integer which selects the element from the
|
|
sorted list (0 corresponds to the smallest element, 1 is the
|
|
next smallest element, etc.).
|
|
|
|
Returns
|
|
-------
|
|
out : ndarray
|
|
The results of the order filter in an array with the same
|
|
shape as `a`.
|
|
|
|
Examples
|
|
--------
|
|
>>> from scipy import signal
|
|
>>> x = np.arange(25).reshape(5, 5)
|
|
>>> domain = np.identity(3)
|
|
>>> x
|
|
array([[ 0, 1, 2, 3, 4],
|
|
[ 5, 6, 7, 8, 9],
|
|
[10, 11, 12, 13, 14],
|
|
[15, 16, 17, 18, 19],
|
|
[20, 21, 22, 23, 24]])
|
|
>>> signal.order_filter(x, domain, 0)
|
|
array([[ 0., 0., 0., 0., 0.],
|
|
[ 0., 0., 1., 2., 0.],
|
|
[ 0., 5., 6., 7., 0.],
|
|
[ 0., 10., 11., 12., 0.],
|
|
[ 0., 0., 0., 0., 0.]])
|
|
>>> signal.order_filter(x, domain, 2)
|
|
array([[ 6., 7., 8., 9., 4.],
|
|
[ 11., 12., 13., 14., 9.],
|
|
[ 16., 17., 18., 19., 14.],
|
|
[ 21., 22., 23., 24., 19.],
|
|
[ 20., 21., 22., 23., 24.]])
|
|
|
|
"""
|
|
domain = np.asarray(domain)
|
|
size = domain.shape
|
|
for k in range(len(size)):
|
|
if (size[k] % 2) != 1:
|
|
raise ValueError("Each dimension of domain argument "
|
|
" should have an odd number of elements.")
|
|
return sigtools._order_filterND(a, domain, rank)
|
|
|
|
|
|
def medfilt(volume, kernel_size=None):
|
|
"""
|
|
Perform a median filter on an N-dimensional array.
|
|
|
|
Apply a median filter to the input array using a local window-size
|
|
given by `kernel_size`. The array will automatically be zero-padded.
|
|
|
|
Parameters
|
|
----------
|
|
volume : array_like
|
|
An N-dimensional input array.
|
|
kernel_size : array_like, optional
|
|
A scalar or an N-length list giving the size of the median filter
|
|
window in each dimension. Elements of `kernel_size` should be odd.
|
|
If `kernel_size` is a scalar, then this scalar is used as the size in
|
|
each dimension. Default size is 3 for each dimension.
|
|
|
|
Returns
|
|
-------
|
|
out : ndarray
|
|
An array the same size as input containing the median filtered
|
|
result.
|
|
|
|
Warns
|
|
-----
|
|
UserWarning
|
|
If array size is smaller than kernel size along any dimension
|
|
|
|
See Also
|
|
--------
|
|
scipy.ndimage.median_filter
|
|
|
|
Notes
|
|
-------
|
|
The more general function `scipy.ndimage.median_filter` has a more
|
|
efficient implementation of a median filter and therefore runs much faster.
|
|
"""
|
|
volume = np.atleast_1d(volume)
|
|
if kernel_size is None:
|
|
kernel_size = [3] * volume.ndim
|
|
kernel_size = np.asarray(kernel_size)
|
|
if kernel_size.shape == ():
|
|
kernel_size = np.repeat(kernel_size.item(), volume.ndim)
|
|
|
|
for k in range(volume.ndim):
|
|
if (kernel_size[k] % 2) != 1:
|
|
raise ValueError("Each element of kernel_size should be odd.")
|
|
if any(k > s for k, s in zip(kernel_size, volume.shape)):
|
|
warnings.warn('kernel_size exceeds volume extent: the volume will be '
|
|
'zero-padded.')
|
|
|
|
domain = np.ones(kernel_size)
|
|
|
|
numels = np.prod(kernel_size, axis=0)
|
|
order = numels // 2
|
|
return sigtools._order_filterND(volume, domain, order)
|
|
|
|
|
|
def wiener(im, mysize=None, noise=None):
|
|
"""
|
|
Perform a Wiener filter on an N-dimensional array.
|
|
|
|
Apply a Wiener filter to the N-dimensional array `im`.
|
|
|
|
Parameters
|
|
----------
|
|
im : ndarray
|
|
An N-dimensional array.
|
|
mysize : int or array_like, optional
|
|
A scalar or an N-length list giving the size of the Wiener filter
|
|
window in each dimension. Elements of mysize should be odd.
|
|
If mysize is a scalar, then this scalar is used as the size
|
|
in each dimension.
|
|
noise : float, optional
|
|
The noise-power to use. If None, then noise is estimated as the
|
|
average of the local variance of the input.
|
|
|
|
Returns
|
|
-------
|
|
out : ndarray
|
|
Wiener filtered result with the same shape as `im`.
|
|
|
|
Examples
|
|
--------
|
|
|
|
>>> from scipy.misc import face
|
|
>>> from scipy.signal.signaltools import wiener
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> import numpy as np
|
|
>>> img = np.random.random((40, 40)) #Create a random image
|
|
>>> filtered_img = wiener(img, (5, 5)) #Filter the image
|
|
>>> f, (plot1, plot2) = plt.subplots(1, 2)
|
|
>>> plot1.imshow(img)
|
|
>>> plot2.imshow(filtered_img)
|
|
>>> plt.show()
|
|
|
|
Notes
|
|
-----
|
|
This implementation is similar to wiener2 in Matlab/Octave.
|
|
For more details see [1]_
|
|
|
|
References
|
|
----------
|
|
.. [1] Lim, Jae S., Two-Dimensional Signal and Image Processing,
|
|
Englewood Cliffs, NJ, Prentice Hall, 1990, p. 548.
|
|
|
|
|
|
"""
|
|
im = np.asarray(im)
|
|
if mysize is None:
|
|
mysize = [3] * im.ndim
|
|
mysize = np.asarray(mysize)
|
|
if mysize.shape == ():
|
|
mysize = np.repeat(mysize.item(), im.ndim)
|
|
|
|
# Estimate the local mean
|
|
lMean = correlate(im, np.ones(mysize), 'same') / np.prod(mysize, axis=0)
|
|
|
|
# Estimate the local variance
|
|
lVar = (correlate(im ** 2, np.ones(mysize), 'same') /
|
|
np.prod(mysize, axis=0) - lMean ** 2)
|
|
|
|
# Estimate the noise power if needed.
|
|
if noise is None:
|
|
noise = np.mean(np.ravel(lVar), axis=0)
|
|
|
|
res = (im - lMean)
|
|
res *= (1 - noise / lVar)
|
|
res += lMean
|
|
out = np.where(lVar < noise, lMean, res)
|
|
|
|
return out
|
|
|
|
|
|
def convolve2d(in1, in2, mode='full', boundary='fill', fillvalue=0):
|
|
"""
|
|
Convolve two 2-dimensional arrays.
|
|
|
|
Convolve `in1` and `in2` with output size determined by `mode`, and
|
|
boundary conditions determined by `boundary` and `fillvalue`.
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
First input.
|
|
in2 : array_like
|
|
Second input. Should have the same number of dimensions as `in1`.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear convolution
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
|
|
must be at least as large as the other in every dimension.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
boundary : str {'fill', 'wrap', 'symm'}, optional
|
|
A flag indicating how to handle boundaries:
|
|
|
|
``fill``
|
|
pad input arrays with fillvalue. (default)
|
|
``wrap``
|
|
circular boundary conditions.
|
|
``symm``
|
|
symmetrical boundary conditions.
|
|
|
|
fillvalue : scalar, optional
|
|
Value to fill pad input arrays with. Default is 0.
|
|
|
|
Returns
|
|
-------
|
|
out : ndarray
|
|
A 2-dimensional array containing a subset of the discrete linear
|
|
convolution of `in1` with `in2`.
|
|
|
|
Examples
|
|
--------
|
|
Compute the gradient of an image by 2D convolution with a complex Scharr
|
|
operator. (Horizontal operator is real, vertical is imaginary.) Use
|
|
symmetric boundary condition to avoid creating edges at the image
|
|
boundaries.
|
|
|
|
>>> from scipy import signal
|
|
>>> from scipy import misc
|
|
>>> ascent = misc.ascent()
|
|
>>> scharr = np.array([[ -3-3j, 0-10j, +3 -3j],
|
|
... [-10+0j, 0+ 0j, +10 +0j],
|
|
... [ -3+3j, 0+10j, +3 +3j]]) # Gx + j*Gy
|
|
>>> grad = signal.convolve2d(ascent, scharr, boundary='symm', mode='same')
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> fig, (ax_orig, ax_mag, ax_ang) = plt.subplots(3, 1, figsize=(6, 15))
|
|
>>> ax_orig.imshow(ascent, cmap='gray')
|
|
>>> ax_orig.set_title('Original')
|
|
>>> ax_orig.set_axis_off()
|
|
>>> ax_mag.imshow(np.absolute(grad), cmap='gray')
|
|
>>> ax_mag.set_title('Gradient magnitude')
|
|
>>> ax_mag.set_axis_off()
|
|
>>> ax_ang.imshow(np.angle(grad), cmap='hsv') # hsv is cyclic, like angles
|
|
>>> ax_ang.set_title('Gradient orientation')
|
|
>>> ax_ang.set_axis_off()
|
|
>>> fig.show()
|
|
|
|
"""
|
|
in1 = np.asarray(in1)
|
|
in2 = np.asarray(in2)
|
|
|
|
if not in1.ndim == in2.ndim == 2:
|
|
raise ValueError('convolve2d inputs must both be 2-D arrays')
|
|
|
|
if _inputs_swap_needed(mode, in1.shape, in2.shape):
|
|
in1, in2 = in2, in1
|
|
|
|
val = _valfrommode(mode)
|
|
bval = _bvalfromboundary(boundary)
|
|
out = sigtools._convolve2d(in1, in2, 1, val, bval, fillvalue)
|
|
return out
|
|
|
|
|
|
def correlate2d(in1, in2, mode='full', boundary='fill', fillvalue=0):
|
|
"""
|
|
Cross-correlate two 2-dimensional arrays.
|
|
|
|
Cross correlate `in1` and `in2` with output size determined by `mode`, and
|
|
boundary conditions determined by `boundary` and `fillvalue`.
|
|
|
|
Parameters
|
|
----------
|
|
in1 : array_like
|
|
First input.
|
|
in2 : array_like
|
|
Second input. Should have the same number of dimensions as `in1`.
|
|
mode : str {'full', 'valid', 'same'}, optional
|
|
A string indicating the size of the output:
|
|
|
|
``full``
|
|
The output is the full discrete linear cross-correlation
|
|
of the inputs. (Default)
|
|
``valid``
|
|
The output consists only of those elements that do not
|
|
rely on the zero-padding. In 'valid' mode, either `in1` or `in2`
|
|
must be at least as large as the other in every dimension.
|
|
``same``
|
|
The output is the same size as `in1`, centered
|
|
with respect to the 'full' output.
|
|
boundary : str {'fill', 'wrap', 'symm'}, optional
|
|
A flag indicating how to handle boundaries:
|
|
|
|
``fill``
|
|
pad input arrays with fillvalue. (default)
|
|
``wrap``
|
|
circular boundary conditions.
|
|
``symm``
|
|
symmetrical boundary conditions.
|
|
|
|
fillvalue : scalar, optional
|
|
Value to fill pad input arrays with. Default is 0.
|
|
|
|
Returns
|
|
-------
|
|
correlate2d : ndarray
|
|
A 2-dimensional array containing a subset of the discrete linear
|
|
cross-correlation of `in1` with `in2`.
|
|
|
|
Notes
|
|
-----
|
|
When using "same" mode with even-length inputs, the outputs of `correlate`
|
|
and `correlate2d` differ: There is a 1-index offset between them.
|
|
|
|
Examples
|
|
--------
|
|
Use 2D cross-correlation to find the location of a template in a noisy
|
|
image:
|
|
|
|
>>> from scipy import signal
|
|
>>> from scipy import misc
|
|
>>> face = misc.face(gray=True) - misc.face(gray=True).mean()
|
|
>>> template = np.copy(face[300:365, 670:750]) # right eye
|
|
>>> template -= template.mean()
|
|
>>> face = face + np.random.randn(*face.shape) * 50 # add noise
|
|
>>> corr = signal.correlate2d(face, template, boundary='symm', mode='same')
|
|
>>> y, x = np.unravel_index(np.argmax(corr), corr.shape) # find the match
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> fig, (ax_orig, ax_template, ax_corr) = plt.subplots(3, 1,
|
|
... figsize=(6, 15))
|
|
>>> ax_orig.imshow(face, cmap='gray')
|
|
>>> ax_orig.set_title('Original')
|
|
>>> ax_orig.set_axis_off()
|
|
>>> ax_template.imshow(template, cmap='gray')
|
|
>>> ax_template.set_title('Template')
|
|
>>> ax_template.set_axis_off()
|
|
>>> ax_corr.imshow(corr, cmap='gray')
|
|
>>> ax_corr.set_title('Cross-correlation')
|
|
>>> ax_corr.set_axis_off()
|
|
>>> ax_orig.plot(x, y, 'ro')
|
|
>>> fig.show()
|
|
|
|
"""
|
|
in1 = np.asarray(in1)
|
|
in2 = np.asarray(in2)
|
|
|
|
if not in1.ndim == in2.ndim == 2:
|
|
raise ValueError('correlate2d inputs must both be 2-D arrays')
|
|
|
|
swapped_inputs = _inputs_swap_needed(mode, in1.shape, in2.shape)
|
|
if swapped_inputs:
|
|
in1, in2 = in2, in1
|
|
|
|
val = _valfrommode(mode)
|
|
bval = _bvalfromboundary(boundary)
|
|
out = sigtools._convolve2d(in1, in2.conj(), 0, val, bval, fillvalue)
|
|
|
|
if swapped_inputs:
|
|
out = out[::-1, ::-1]
|
|
|
|
return out
|
|
|
|
|
|
def medfilt2d(input, kernel_size=3):
|
|
"""
|
|
Median filter a 2-dimensional array.
|
|
|
|
Apply a median filter to the `input` array using a local window-size
|
|
given by `kernel_size` (must be odd). The array is zero-padded
|
|
automatically.
|
|
|
|
Parameters
|
|
----------
|
|
input : array_like
|
|
A 2-dimensional input array.
|
|
kernel_size : array_like, optional
|
|
A scalar or a list of length 2, giving the size of the
|
|
median filter window in each dimension. Elements of
|
|
`kernel_size` should be odd. If `kernel_size` is a scalar,
|
|
then this scalar is used as the size in each dimension.
|
|
Default is a kernel of size (3, 3).
|
|
|
|
Returns
|
|
-------
|
|
out : ndarray
|
|
An array the same size as input containing the median filtered
|
|
result.
|
|
|
|
See also
|
|
--------
|
|
scipy.ndimage.median_filter
|
|
|
|
Notes
|
|
-------
|
|
The more general function `scipy.ndimage.median_filter` has a more
|
|
efficient implementation of a median filter and therefore runs much faster.
|
|
"""
|
|
image = np.asarray(input)
|
|
if kernel_size is None:
|
|
kernel_size = [3] * 2
|
|
kernel_size = np.asarray(kernel_size)
|
|
if kernel_size.shape == ():
|
|
kernel_size = np.repeat(kernel_size.item(), 2)
|
|
|
|
for size in kernel_size:
|
|
if (size % 2) != 1:
|
|
raise ValueError("Each element of kernel_size should be odd.")
|
|
|
|
return sigtools._medfilt2d(image, kernel_size)
|
|
|
|
|
|
def lfilter(b, a, x, axis=-1, zi=None):
|
|
"""
|
|
Filter data along one-dimension with an IIR or FIR filter.
|
|
|
|
Filter a data sequence, `x`, using a digital filter. This works for many
|
|
fundamental data types (including Object type). The filter is a direct
|
|
form II transposed implementation of the standard difference equation
|
|
(see Notes).
|
|
|
|
The function `sosfilt` (and filter design using ``output='sos'``) should be
|
|
preferred over `lfilter` for most filtering tasks, as second-order sections
|
|
have fewer numerical problems.
|
|
|
|
Parameters
|
|
----------
|
|
b : array_like
|
|
The numerator coefficient vector in a 1-D sequence.
|
|
a : array_like
|
|
The denominator coefficient vector in a 1-D sequence. If ``a[0]``
|
|
is not 1, then both `a` and `b` are normalized by ``a[0]``.
|
|
x : array_like
|
|
An N-dimensional input array.
|
|
axis : int, optional
|
|
The axis of the input data array along which to apply the
|
|
linear filter. The filter is applied to each subarray along
|
|
this axis. Default is -1.
|
|
zi : array_like, optional
|
|
Initial conditions for the filter delays. It is a vector
|
|
(or array of vectors for an N-dimensional input) of length
|
|
``max(len(a), len(b)) - 1``. If `zi` is None or is not given then
|
|
initial rest is assumed. See `lfiltic` for more information.
|
|
|
|
Returns
|
|
-------
|
|
y : array
|
|
The output of the digital filter.
|
|
zf : array, optional
|
|
If `zi` is None, this is not returned, otherwise, `zf` holds the
|
|
final filter delay values.
|
|
|
|
See Also
|
|
--------
|
|
lfiltic : Construct initial conditions for `lfilter`.
|
|
lfilter_zi : Compute initial state (steady state of step response) for
|
|
`lfilter`.
|
|
filtfilt : A forward-backward filter, to obtain a filter with linear phase.
|
|
savgol_filter : A Savitzky-Golay filter.
|
|
sosfilt: Filter data using cascaded second-order sections.
|
|
sosfiltfilt: A forward-backward filter using second-order sections.
|
|
|
|
Notes
|
|
-----
|
|
The filter function is implemented as a direct II transposed structure.
|
|
This means that the filter implements::
|
|
|
|
a[0]*y[n] = b[0]*x[n] + b[1]*x[n-1] + ... + b[M]*x[n-M]
|
|
- a[1]*y[n-1] - ... - a[N]*y[n-N]
|
|
|
|
where `M` is the degree of the numerator, `N` is the degree of the
|
|
denominator, and `n` is the sample number. It is implemented using
|
|
the following difference equations (assuming M = N)::
|
|
|
|
a[0]*y[n] = b[0] * x[n] + d[0][n-1]
|
|
d[0][n] = b[1] * x[n] - a[1] * y[n] + d[1][n-1]
|
|
d[1][n] = b[2] * x[n] - a[2] * y[n] + d[2][n-1]
|
|
...
|
|
d[N-2][n] = b[N-1]*x[n] - a[N-1]*y[n] + d[N-1][n-1]
|
|
d[N-1][n] = b[N] * x[n] - a[N] * y[n]
|
|
|
|
where `d` are the state variables.
|
|
|
|
The rational transfer function describing this filter in the
|
|
z-transform domain is::
|
|
|
|
-1 -M
|
|
b[0] + b[1]z + ... + b[M] z
|
|
Y(z) = -------------------------------- X(z)
|
|
-1 -N
|
|
a[0] + a[1]z + ... + a[N] z
|
|
|
|
Examples
|
|
--------
|
|
Generate a noisy signal to be filtered:
|
|
|
|
>>> from scipy import signal
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> t = np.linspace(-1, 1, 201)
|
|
>>> x = (np.sin(2*np.pi*0.75*t*(1-t) + 2.1) +
|
|
... 0.1*np.sin(2*np.pi*1.25*t + 1) +
|
|
... 0.18*np.cos(2*np.pi*3.85*t))
|
|
>>> xn = x + np.random.randn(len(t)) * 0.08
|
|
|
|
Create an order 3 lowpass butterworth filter:
|
|
|
|
>>> b, a = signal.butter(3, 0.05)
|
|
|
|
Apply the filter to xn. Use lfilter_zi to choose the initial condition of
|
|
the filter:
|
|
|
|
>>> zi = signal.lfilter_zi(b, a)
|
|
>>> z, _ = signal.lfilter(b, a, xn, zi=zi*xn[0])
|
|
|
|
Apply the filter again, to have a result filtered at an order the same as
|
|
filtfilt:
|
|
|
|
>>> z2, _ = signal.lfilter(b, a, z, zi=zi*z[0])
|
|
|
|
Use filtfilt to apply the filter:
|
|
|
|
>>> y = signal.filtfilt(b, a, xn)
|
|
|
|
Plot the original signal and the various filtered versions:
|
|
|
|
>>> plt.figure
|
|
>>> plt.plot(t, xn, 'b', alpha=0.75)
|
|
>>> plt.plot(t, z, 'r--', t, z2, 'r', t, y, 'k')
|
|
>>> plt.legend(('noisy signal', 'lfilter, once', 'lfilter, twice',
|
|
... 'filtfilt'), loc='best')
|
|
>>> plt.grid(True)
|
|
>>> plt.show()
|
|
|
|
"""
|
|
a = np.atleast_1d(a)
|
|
if len(a) == 1:
|
|
# This path only supports types fdgFDGO to mirror _linear_filter below.
|
|
# Any of b, a, x, or zi can set the dtype, but there is no default
|
|
# casting of other types; instead a NotImplementedError is raised.
|
|
b = np.asarray(b)
|
|
a = np.asarray(a)
|
|
if b.ndim != 1 and a.ndim != 1:
|
|
raise ValueError('object of too small depth for desired array')
|
|
x = _validate_x(x)
|
|
inputs = [b, a, x]
|
|
if zi is not None:
|
|
# _linear_filter does not broadcast zi, but does do expansion of
|
|
# singleton dims.
|
|
zi = np.asarray(zi)
|
|
if zi.ndim != x.ndim:
|
|
raise ValueError('object of too small depth for desired array')
|
|
expected_shape = list(x.shape)
|
|
expected_shape[axis] = b.shape[0] - 1
|
|
expected_shape = tuple(expected_shape)
|
|
# check the trivial case where zi is the right shape first
|
|
if zi.shape != expected_shape:
|
|
strides = zi.ndim * [None]
|
|
if axis < 0:
|
|
axis += zi.ndim
|
|
for k in range(zi.ndim):
|
|
if k == axis and zi.shape[k] == expected_shape[k]:
|
|
strides[k] = zi.strides[k]
|
|
elif k != axis and zi.shape[k] == expected_shape[k]:
|
|
strides[k] = zi.strides[k]
|
|
elif k != axis and zi.shape[k] == 1:
|
|
strides[k] = 0
|
|
else:
|
|
raise ValueError('Unexpected shape for zi: expected '
|
|
'%s, found %s.' %
|
|
(expected_shape, zi.shape))
|
|
zi = np.lib.stride_tricks.as_strided(zi, expected_shape,
|
|
strides)
|
|
inputs.append(zi)
|
|
dtype = np.result_type(*inputs)
|
|
|
|
if dtype.char not in 'fdgFDGO':
|
|
raise NotImplementedError("input type '%s' not supported" % dtype)
|
|
|
|
b = np.array(b, dtype=dtype)
|
|
a = np.array(a, dtype=dtype, copy=False)
|
|
b /= a[0]
|
|
x = np.array(x, dtype=dtype, copy=False)
|
|
|
|
out_full = np.apply_along_axis(lambda y: np.convolve(b, y), axis, x)
|
|
ind = out_full.ndim * [slice(None)]
|
|
if zi is not None:
|
|
ind[axis] = slice(zi.shape[axis])
|
|
out_full[tuple(ind)] += zi
|
|
|
|
ind[axis] = slice(out_full.shape[axis] - len(b) + 1)
|
|
out = out_full[tuple(ind)]
|
|
|
|
if zi is None:
|
|
return out
|
|
else:
|
|
ind[axis] = slice(out_full.shape[axis] - len(b) + 1, None)
|
|
zf = out_full[tuple(ind)]
|
|
return out, zf
|
|
else:
|
|
if zi is None:
|
|
return sigtools._linear_filter(b, a, x, axis)
|
|
else:
|
|
return sigtools._linear_filter(b, a, x, axis, zi)
|
|
|
|
|
|
def lfiltic(b, a, y, x=None):
|
|
"""
|
|
Construct initial conditions for lfilter given input and output vectors.
|
|
|
|
Given a linear filter (b, a) and initial conditions on the output `y`
|
|
and the input `x`, return the initial conditions on the state vector zi
|
|
which is used by `lfilter` to generate the output given the input.
|
|
|
|
Parameters
|
|
----------
|
|
b : array_like
|
|
Linear filter term.
|
|
a : array_like
|
|
Linear filter term.
|
|
y : array_like
|
|
Initial conditions.
|
|
|
|
If ``N = len(a) - 1``, then ``y = {y[-1], y[-2], ..., y[-N]}``.
|
|
|
|
If `y` is too short, it is padded with zeros.
|
|
x : array_like, optional
|
|
Initial conditions.
|
|
|
|
If ``M = len(b) - 1``, then ``x = {x[-1], x[-2], ..., x[-M]}``.
|
|
|
|
If `x` is not given, its initial conditions are assumed zero.
|
|
|
|
If `x` is too short, it is padded with zeros.
|
|
|
|
Returns
|
|
-------
|
|
zi : ndarray
|
|
The state vector ``zi = {z_0[-1], z_1[-1], ..., z_K-1[-1]}``,
|
|
where ``K = max(M, N)``.
|
|
|
|
See Also
|
|
--------
|
|
lfilter, lfilter_zi
|
|
|
|
"""
|
|
N = np.size(a) - 1
|
|
M = np.size(b) - 1
|
|
K = max(M, N)
|
|
y = np.asarray(y)
|
|
|
|
if x is None:
|
|
result_type = np.result_type(np.asarray(b), np.asarray(a), y)
|
|
if result_type.kind in 'bui':
|
|
result_type = np.float64
|
|
x = np.zeros(M, dtype=result_type)
|
|
else:
|
|
x = np.asarray(x)
|
|
|
|
result_type = np.result_type(np.asarray(b), np.asarray(a), y, x)
|
|
if result_type.kind in 'bui':
|
|
result_type = np.float64
|
|
x = x.astype(result_type)
|
|
|
|
L = np.size(x)
|
|
if L < M:
|
|
x = np.r_[x, np.zeros(M - L)]
|
|
|
|
y = y.astype(result_type)
|
|
zi = np.zeros(K, result_type)
|
|
|
|
L = np.size(y)
|
|
if L < N:
|
|
y = np.r_[y, np.zeros(N - L)]
|
|
|
|
for m in range(M):
|
|
zi[m] = np.sum(b[m + 1:] * x[:M - m], axis=0)
|
|
|
|
for m in range(N):
|
|
zi[m] -= np.sum(a[m + 1:] * y[:N - m], axis=0)
|
|
|
|
return zi
|
|
|
|
|
|
def deconvolve(signal, divisor):
|
|
"""Deconvolves ``divisor`` out of ``signal`` using inverse filtering.
|
|
|
|
Returns the quotient and remainder such that
|
|
``signal = convolve(divisor, quotient) + remainder``
|
|
|
|
Parameters
|
|
----------
|
|
signal : array_like
|
|
Signal data, typically a recorded signal
|
|
divisor : array_like
|
|
Divisor data, typically an impulse response or filter that was
|
|
applied to the original signal
|
|
|
|
Returns
|
|
-------
|
|
quotient : ndarray
|
|
Quotient, typically the recovered original signal
|
|
remainder : ndarray
|
|
Remainder
|
|
|
|
Examples
|
|
--------
|
|
Deconvolve a signal that's been filtered:
|
|
|
|
>>> from scipy import signal
|
|
>>> original = [0, 1, 0, 0, 1, 1, 0, 0]
|
|
>>> impulse_response = [2, 1]
|
|
>>> recorded = signal.convolve(impulse_response, original)
|
|
>>> recorded
|
|
array([0, 2, 1, 0, 2, 3, 1, 0, 0])
|
|
>>> recovered, remainder = signal.deconvolve(recorded, impulse_response)
|
|
>>> recovered
|
|
array([ 0., 1., 0., 0., 1., 1., 0., 0.])
|
|
|
|
See Also
|
|
--------
|
|
numpy.polydiv : performs polynomial division (same operation, but
|
|
also accepts poly1d objects)
|
|
|
|
"""
|
|
num = np.atleast_1d(signal)
|
|
den = np.atleast_1d(divisor)
|
|
N = len(num)
|
|
D = len(den)
|
|
if D > N:
|
|
quot = []
|
|
rem = num
|
|
else:
|
|
input = np.zeros(N - D + 1, float)
|
|
input[0] = 1
|
|
quot = lfilter(num, den, input)
|
|
rem = num - convolve(den, quot, mode='full')
|
|
return quot, rem
|
|
|
|
|
|
def hilbert(x, N=None, axis=-1):
|
|
"""
|
|
Compute the analytic signal, using the Hilbert transform.
|
|
|
|
The transformation is done along the last axis by default.
|
|
|
|
Parameters
|
|
----------
|
|
x : array_like
|
|
Signal data. Must be real.
|
|
N : int, optional
|
|
Number of Fourier components. Default: ``x.shape[axis]``
|
|
axis : int, optional
|
|
Axis along which to do the transformation. Default: -1.
|
|
|
|
Returns
|
|
-------
|
|
xa : ndarray
|
|
Analytic signal of `x`, of each 1-D array along `axis`
|
|
|
|
Notes
|
|
-----
|
|
The analytic signal ``x_a(t)`` of signal ``x(t)`` is:
|
|
|
|
.. math:: x_a = F^{-1}(F(x) 2U) = x + i y
|
|
|
|
where `F` is the Fourier transform, `U` the unit step function,
|
|
and `y` the Hilbert transform of `x`. [1]_
|
|
|
|
In other words, the negative half of the frequency spectrum is zeroed
|
|
out, turning the real-valued signal into a complex signal. The Hilbert
|
|
transformed signal can be obtained from ``np.imag(hilbert(x))``, and the
|
|
original signal from ``np.real(hilbert(x))``.
|
|
|
|
Examples
|
|
---------
|
|
In this example we use the Hilbert transform to determine the amplitude
|
|
envelope and instantaneous frequency of an amplitude-modulated signal.
|
|
|
|
>>> import numpy as np
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> from scipy.signal import hilbert, chirp
|
|
|
|
>>> duration = 1.0
|
|
>>> fs = 400.0
|
|
>>> samples = int(fs*duration)
|
|
>>> t = np.arange(samples) / fs
|
|
|
|
We create a chirp of which the frequency increases from 20 Hz to 100 Hz and
|
|
apply an amplitude modulation.
|
|
|
|
>>> signal = chirp(t, 20.0, t[-1], 100.0)
|
|
>>> signal *= (1.0 + 0.5 * np.sin(2.0*np.pi*3.0*t) )
|
|
|
|
The amplitude envelope is given by magnitude of the analytic signal. The
|
|
instantaneous frequency can be obtained by differentiating the
|
|
instantaneous phase in respect to time. The instantaneous phase corresponds
|
|
to the phase angle of the analytic signal.
|
|
|
|
>>> analytic_signal = hilbert(signal)
|
|
>>> amplitude_envelope = np.abs(analytic_signal)
|
|
>>> instantaneous_phase = np.unwrap(np.angle(analytic_signal))
|
|
>>> instantaneous_frequency = (np.diff(instantaneous_phase) /
|
|
... (2.0*np.pi) * fs)
|
|
|
|
>>> fig = plt.figure()
|
|
>>> ax0 = fig.add_subplot(211)
|
|
>>> ax0.plot(t, signal, label='signal')
|
|
>>> ax0.plot(t, amplitude_envelope, label='envelope')
|
|
>>> ax0.set_xlabel("time in seconds")
|
|
>>> ax0.legend()
|
|
>>> ax1 = fig.add_subplot(212)
|
|
>>> ax1.plot(t[1:], instantaneous_frequency)
|
|
>>> ax1.set_xlabel("time in seconds")
|
|
>>> ax1.set_ylim(0.0, 120.0)
|
|
|
|
References
|
|
----------
|
|
.. [1] Wikipedia, "Analytic signal".
|
|
https://en.wikipedia.org/wiki/Analytic_signal
|
|
.. [2] Leon Cohen, "Time-Frequency Analysis", 1995. Chapter 2.
|
|
.. [3] Alan V. Oppenheim, Ronald W. Schafer. Discrete-Time Signal
|
|
Processing, Third Edition, 2009. Chapter 12.
|
|
ISBN 13: 978-1292-02572-8
|
|
|
|
"""
|
|
x = np.asarray(x)
|
|
if np.iscomplexobj(x):
|
|
raise ValueError("x must be real.")
|
|
if N is None:
|
|
N = x.shape[axis]
|
|
if N <= 0:
|
|
raise ValueError("N must be positive.")
|
|
|
|
Xf = sp_fft.fft(x, N, axis=axis)
|
|
h = np.zeros(N)
|
|
if N % 2 == 0:
|
|
h[0] = h[N // 2] = 1
|
|
h[1:N // 2] = 2
|
|
else:
|
|
h[0] = 1
|
|
h[1:(N + 1) // 2] = 2
|
|
|
|
if x.ndim > 1:
|
|
ind = [np.newaxis] * x.ndim
|
|
ind[axis] = slice(None)
|
|
h = h[tuple(ind)]
|
|
x = sp_fft.ifft(Xf * h, axis=axis)
|
|
return x
|
|
|
|
|
|
def hilbert2(x, N=None):
|
|
"""
|
|
Compute the '2-D' analytic signal of `x`
|
|
|
|
Parameters
|
|
----------
|
|
x : array_like
|
|
2-D signal data.
|
|
N : int or tuple of two ints, optional
|
|
Number of Fourier components. Default is ``x.shape``
|
|
|
|
Returns
|
|
-------
|
|
xa : ndarray
|
|
Analytic signal of `x` taken along axes (0,1).
|
|
|
|
References
|
|
----------
|
|
.. [1] Wikipedia, "Analytic signal",
|
|
https://en.wikipedia.org/wiki/Analytic_signal
|
|
|
|
"""
|
|
x = np.atleast_2d(x)
|
|
if x.ndim > 2:
|
|
raise ValueError("x must be 2-D.")
|
|
if np.iscomplexobj(x):
|
|
raise ValueError("x must be real.")
|
|
if N is None:
|
|
N = x.shape
|
|
elif isinstance(N, int):
|
|
if N <= 0:
|
|
raise ValueError("N must be positive.")
|
|
N = (N, N)
|
|
elif len(N) != 2 or np.any(np.asarray(N) <= 0):
|
|
raise ValueError("When given as a tuple, N must hold exactly "
|
|
"two positive integers")
|
|
|
|
Xf = sp_fft.fft2(x, N, axes=(0, 1))
|
|
h1 = np.zeros(N[0], 'd')
|
|
h2 = np.zeros(N[1], 'd')
|
|
for p in range(2):
|
|
h = eval("h%d" % (p + 1))
|
|
N1 = N[p]
|
|
if N1 % 2 == 0:
|
|
h[0] = h[N1 // 2] = 1
|
|
h[1:N1 // 2] = 2
|
|
else:
|
|
h[0] = 1
|
|
h[1:(N1 + 1) // 2] = 2
|
|
exec("h%d = h" % (p + 1), globals(), locals())
|
|
|
|
h = h1[:, np.newaxis] * h2[np.newaxis, :]
|
|
k = x.ndim
|
|
while k > 2:
|
|
h = h[:, np.newaxis]
|
|
k -= 1
|
|
x = sp_fft.ifft2(Xf * h, axes=(0, 1))
|
|
return x
|
|
|
|
|
|
def cmplx_sort(p):
|
|
"""Sort roots based on magnitude.
|
|
|
|
Parameters
|
|
----------
|
|
p : array_like
|
|
The roots to sort, as a 1-D array.
|
|
|
|
Returns
|
|
-------
|
|
p_sorted : ndarray
|
|
Sorted roots.
|
|
indx : ndarray
|
|
Array of indices needed to sort the input `p`.
|
|
|
|
Examples
|
|
--------
|
|
>>> from scipy import signal
|
|
>>> vals = [1, 4, 1+1.j, 3]
|
|
>>> p_sorted, indx = signal.cmplx_sort(vals)
|
|
>>> p_sorted
|
|
array([1.+0.j, 1.+1.j, 3.+0.j, 4.+0.j])
|
|
>>> indx
|
|
array([0, 2, 3, 1])
|
|
"""
|
|
p = np.asarray(p)
|
|
indx = np.argsort(abs(p))
|
|
return np.take(p, indx, 0), indx
|
|
|
|
|
|
def unique_roots(p, tol=1e-3, rtype='min'):
|
|
"""Determine unique roots and their multiplicities from a list of roots.
|
|
|
|
Parameters
|
|
----------
|
|
p : array_like
|
|
The list of roots.
|
|
tol : float, optional
|
|
The tolerance for two roots to be considered equal in terms of
|
|
the distance between them. Default is 1e-3. Refer to Notes about
|
|
the details on roots grouping.
|
|
rtype : {'max', 'maximum', 'min', 'minimum', 'avg', 'mean'}, optional
|
|
How to determine the returned root if multiple roots are within
|
|
`tol` of each other.
|
|
|
|
- 'max', 'maximum': pick the maximum of those roots
|
|
- 'min', 'minimum': pick the minimum of those roots
|
|
- 'avg', 'mean': take the average of those roots
|
|
|
|
When finding minimum or maximum among complex roots they are compared
|
|
first by the real part and then by the imaginary part.
|
|
|
|
Returns
|
|
-------
|
|
unique : ndarray
|
|
The list of unique roots.
|
|
multiplicity : ndarray
|
|
The multiplicity of each root.
|
|
|
|
Notes
|
|
-----
|
|
If we have 3 roots ``a``, ``b`` and ``c``, such that ``a`` is close to
|
|
``b`` and ``b`` is close to ``c`` (distance is less than `tol`), then it
|
|
doesn't necessarily mean that ``a`` is close to ``c``. It means that roots
|
|
grouping is not unique. In this function we use "greedy" grouping going
|
|
through the roots in the order they are given in the input `p`.
|
|
|
|
This utility function is not specific to roots but can be used for any
|
|
sequence of values for which uniqueness and multiplicity has to be
|
|
determined. For a more general routine, see `numpy.unique`.
|
|
|
|
Examples
|
|
--------
|
|
>>> from scipy import signal
|
|
>>> vals = [0, 1.3, 1.31, 2.8, 1.25, 2.2, 10.3]
|
|
>>> uniq, mult = signal.unique_roots(vals, tol=2e-2, rtype='avg')
|
|
|
|
Check which roots have multiplicity larger than 1:
|
|
|
|
>>> uniq[mult > 1]
|
|
array([ 1.305])
|
|
"""
|
|
if rtype in ['max', 'maximum']:
|
|
reduce = np.max
|
|
elif rtype in ['min', 'minimum']:
|
|
reduce = np.min
|
|
elif rtype in ['avg', 'mean']:
|
|
reduce = np.mean
|
|
else:
|
|
raise ValueError("`rtype` must be one of "
|
|
"{'max', 'maximum', 'min', 'minimum', 'avg', 'mean'}")
|
|
|
|
p = np.asarray(p)
|
|
|
|
points = np.empty((len(p), 2))
|
|
points[:, 0] = np.real(p)
|
|
points[:, 1] = np.imag(p)
|
|
tree = cKDTree(points)
|
|
|
|
p_unique = []
|
|
p_multiplicity = []
|
|
used = np.zeros(len(p), dtype=bool)
|
|
for i in range(len(p)):
|
|
if used[i]:
|
|
continue
|
|
|
|
group = tree.query_ball_point(points[i], tol)
|
|
group = [x for x in group if not used[x]]
|
|
|
|
p_unique.append(reduce(p[group]))
|
|
p_multiplicity.append(len(group))
|
|
|
|
used[group] = True
|
|
|
|
return np.asarray(p_unique), np.asarray(p_multiplicity)
|
|
|
|
|
|
def invres(r, p, k, tol=1e-3, rtype='avg'):
|
|
"""Compute b(s) and a(s) from partial fraction expansion.
|
|
|
|
If `M` is the degree of numerator `b` and `N` the degree of denominator
|
|
`a`::
|
|
|
|
b(s) b[0] s**(M) + b[1] s**(M-1) + ... + b[M]
|
|
H(s) = ------ = ------------------------------------------
|
|
a(s) a[0] s**(N) + a[1] s**(N-1) + ... + a[N]
|
|
|
|
then the partial-fraction expansion H(s) is defined as::
|
|
|
|
r[0] r[1] r[-1]
|
|
= -------- + -------- + ... + --------- + k(s)
|
|
(s-p[0]) (s-p[1]) (s-p[-1])
|
|
|
|
If there are any repeated roots (closer together than `tol`), then H(s)
|
|
has terms like::
|
|
|
|
r[i] r[i+1] r[i+n-1]
|
|
-------- + ----------- + ... + -----------
|
|
(s-p[i]) (s-p[i])**2 (s-p[i])**n
|
|
|
|
This function is used for polynomials in positive powers of s or z,
|
|
such as analog filters or digital filters in controls engineering. For
|
|
negative powers of z (typical for digital filters in DSP), use `invresz`.
|
|
|
|
Parameters
|
|
----------
|
|
r : array_like
|
|
Residues corresponding to the poles. For repeated poles, the residues
|
|
must be ordered to correspond to ascending by power fractions.
|
|
p : array_like
|
|
Poles. Equal poles must be adjacent.
|
|
k : array_like
|
|
Coefficients of the direct polynomial term.
|
|
tol : float, optional
|
|
The tolerance for two roots to be considered equal in terms of
|
|
the distance between them. Default is 1e-3. See `unique_roots`
|
|
for further details.
|
|
rtype : {'avg', 'min', 'max'}, optional
|
|
Method for computing a root to represent a group of identical roots.
|
|
Default is 'avg'. See `unique_roots` for further details.
|
|
|
|
Returns
|
|
-------
|
|
b : ndarray
|
|
Numerator polynomial coefficients.
|
|
a : ndarray
|
|
Denominator polynomial coefficients.
|
|
|
|
See Also
|
|
--------
|
|
residue, invresz, unique_roots
|
|
|
|
"""
|
|
r = np.atleast_1d(r)
|
|
p = np.atleast_1d(p)
|
|
k = np.trim_zeros(np.atleast_1d(k), 'f')
|
|
|
|
unique_poles, multiplicity = _group_poles(p, tol, rtype)
|
|
factors, denominator = _compute_factors(unique_poles, multiplicity,
|
|
include_powers=True)
|
|
|
|
if len(k) == 0:
|
|
numerator = 0
|
|
else:
|
|
numerator = np.polymul(k, denominator)
|
|
|
|
for residue, factor in zip(r, factors):
|
|
numerator = np.polyadd(numerator, residue * factor)
|
|
|
|
return numerator, denominator
|
|
|
|
|
|
def _compute_factors(roots, multiplicity, include_powers=False):
|
|
"""Compute the total polynomial divided by factors for each root."""
|
|
current = np.array([1])
|
|
suffixes = [current]
|
|
for pole, mult in zip(roots[-1:0:-1], multiplicity[-1:0:-1]):
|
|
monomial = np.array([1, -pole])
|
|
for _ in range(mult):
|
|
current = np.polymul(current, monomial)
|
|
suffixes.append(current)
|
|
suffixes = suffixes[::-1]
|
|
|
|
factors = []
|
|
current = np.array([1])
|
|
for pole, mult, suffix in zip(roots, multiplicity, suffixes):
|
|
monomial = np.array([1, -pole])
|
|
block = []
|
|
for i in range(mult):
|
|
if i == 0 or include_powers:
|
|
block.append(np.polymul(current, suffix))
|
|
current = np.polymul(current, monomial)
|
|
factors.extend(reversed(block))
|
|
|
|
return factors, current
|
|
|
|
|
|
def _compute_residues(poles, multiplicity, numerator):
|
|
denominator_factors, _ = _compute_factors(poles, multiplicity)
|
|
numerator = numerator.astype(poles.dtype)
|
|
|
|
residues = []
|
|
for pole, mult, factor in zip(poles, multiplicity,
|
|
denominator_factors):
|
|
if mult == 1:
|
|
residues.append(np.polyval(numerator, pole) /
|
|
np.polyval(factor, pole))
|
|
else:
|
|
numer = numerator.copy()
|
|
monomial = np.array([1, -pole])
|
|
factor, d = np.polydiv(factor, monomial)
|
|
|
|
block = []
|
|
for _ in range(mult):
|
|
numer, n = np.polydiv(numer, monomial)
|
|
r = n[0] / d[0]
|
|
numer = np.polysub(numer, r * factor)
|
|
block.append(r)
|
|
|
|
residues.extend(reversed(block))
|
|
|
|
return np.asarray(residues)
|
|
|
|
|
|
def residue(b, a, tol=1e-3, rtype='avg'):
|
|
"""Compute partial-fraction expansion of b(s) / a(s).
|
|
|
|
If `M` is the degree of numerator `b` and `N` the degree of denominator
|
|
`a`::
|
|
|
|
b(s) b[0] s**(M) + b[1] s**(M-1) + ... + b[M]
|
|
H(s) = ------ = ------------------------------------------
|
|
a(s) a[0] s**(N) + a[1] s**(N-1) + ... + a[N]
|
|
|
|
then the partial-fraction expansion H(s) is defined as::
|
|
|
|
r[0] r[1] r[-1]
|
|
= -------- + -------- + ... + --------- + k(s)
|
|
(s-p[0]) (s-p[1]) (s-p[-1])
|
|
|
|
If there are any repeated roots (closer together than `tol`), then H(s)
|
|
has terms like::
|
|
|
|
r[i] r[i+1] r[i+n-1]
|
|
-------- + ----------- + ... + -----------
|
|
(s-p[i]) (s-p[i])**2 (s-p[i])**n
|
|
|
|
This function is used for polynomials in positive powers of s or z,
|
|
such as analog filters or digital filters in controls engineering. For
|
|
negative powers of z (typical for digital filters in DSP), use `residuez`.
|
|
|
|
See Notes for details about the algorithm.
|
|
|
|
Parameters
|
|
----------
|
|
b : array_like
|
|
Numerator polynomial coefficients.
|
|
a : array_like
|
|
Denominator polynomial coefficients.
|
|
tol : float, optional
|
|
The tolerance for two roots to be considered equal in terms of
|
|
the distance between them. Default is 1e-3. See `unique_roots`
|
|
for further details.
|
|
rtype : {'avg', 'min', 'max'}, optional
|
|
Method for computing a root to represent a group of identical roots.
|
|
Default is 'avg'. See `unique_roots` for further details.
|
|
|
|
Returns
|
|
-------
|
|
r : ndarray
|
|
Residues corresponding to the poles. For repeated poles, the residues
|
|
are ordered to correspond to ascending by power fractions.
|
|
p : ndarray
|
|
Poles ordered by magnitude in ascending order.
|
|
k : ndarray
|
|
Coefficients of the direct polynomial term.
|
|
|
|
See Also
|
|
--------
|
|
invres, residuez, numpy.poly, unique_roots
|
|
|
|
Notes
|
|
-----
|
|
The "deflation through subtraction" algorithm is used for
|
|
computations --- method 6 in [1]_.
|
|
|
|
The form of partial fraction expansion depends on poles multiplicity in
|
|
the exact mathematical sense. However there is no way to exactly
|
|
determine multiplicity of roots of a polynomial in numerical computing.
|
|
Thus you should think of the result of `residue` with given `tol` as
|
|
partial fraction expansion computed for the denominator composed of the
|
|
computed poles with empirically determined multiplicity. The choice of
|
|
`tol` can drastically change the result if there are close poles.
|
|
|
|
References
|
|
----------
|
|
.. [1] J. F. Mahoney, B. D. Sivazlian, "Partial fractions expansion: a
|
|
review of computational methodology and efficiency", Journal of
|
|
Computational and Applied Mathematics, Vol. 9, 1983.
|
|
"""
|
|
b = np.asarray(b)
|
|
a = np.asarray(a)
|
|
if (np.issubdtype(b.dtype, np.complexfloating)
|
|
or np.issubdtype(a.dtype, np.complexfloating)):
|
|
b = b.astype(complex)
|
|
a = a.astype(complex)
|
|
else:
|
|
b = b.astype(float)
|
|
a = a.astype(float)
|
|
|
|
b = np.trim_zeros(np.atleast_1d(b), 'f')
|
|
a = np.trim_zeros(np.atleast_1d(a), 'f')
|
|
|
|
if a.size == 0:
|
|
raise ValueError("Denominator `a` is zero.")
|
|
|
|
poles = np.roots(a)
|
|
if b.size == 0:
|
|
return np.zeros(poles.shape), cmplx_sort(poles)[0], np.array([])
|
|
|
|
if len(b) < len(a):
|
|
k = np.empty(0)
|
|
else:
|
|
k, b = np.polydiv(b, a)
|
|
|
|
unique_poles, multiplicity = unique_roots(poles, tol=tol, rtype=rtype)
|
|
unique_poles, order = cmplx_sort(unique_poles)
|
|
multiplicity = multiplicity[order]
|
|
|
|
residues = _compute_residues(unique_poles, multiplicity, b)
|
|
|
|
index = 0
|
|
for pole, mult in zip(unique_poles, multiplicity):
|
|
poles[index:index + mult] = pole
|
|
index += mult
|
|
|
|
return residues / a[0], poles, k
|
|
|
|
|
|
def residuez(b, a, tol=1e-3, rtype='avg'):
|
|
"""Compute partial-fraction expansion of b(z) / a(z).
|
|
|
|
If `M` is the degree of numerator `b` and `N` the degree of denominator
|
|
`a`::
|
|
|
|
b(z) b[0] + b[1] z**(-1) + ... + b[M] z**(-M)
|
|
H(z) = ------ = ------------------------------------------
|
|
a(z) a[0] + a[1] z**(-1) + ... + a[N] z**(-N)
|
|
|
|
then the partial-fraction expansion H(z) is defined as::
|
|
|
|
r[0] r[-1]
|
|
= --------------- + ... + ---------------- + k[0] + k[1]z**(-1) ...
|
|
(1-p[0]z**(-1)) (1-p[-1]z**(-1))
|
|
|
|
If there are any repeated roots (closer than `tol`), then the partial
|
|
fraction expansion has terms like::
|
|
|
|
r[i] r[i+1] r[i+n-1]
|
|
-------------- + ------------------ + ... + ------------------
|
|
(1-p[i]z**(-1)) (1-p[i]z**(-1))**2 (1-p[i]z**(-1))**n
|
|
|
|
This function is used for polynomials in negative powers of z,
|
|
such as digital filters in DSP. For positive powers, use `residue`.
|
|
|
|
See Notes of `residue` for details about the algorithm.
|
|
|
|
Parameters
|
|
----------
|
|
b : array_like
|
|
Numerator polynomial coefficients.
|
|
a : array_like
|
|
Denominator polynomial coefficients.
|
|
tol : float, optional
|
|
The tolerance for two roots to be considered equal in terms of
|
|
the distance between them. Default is 1e-3. See `unique_roots`
|
|
for further details.
|
|
rtype : {'avg', 'min', 'max'}, optional
|
|
Method for computing a root to represent a group of identical roots.
|
|
Default is 'avg'. See `unique_roots` for further details.
|
|
|
|
Returns
|
|
-------
|
|
r : ndarray
|
|
Residues corresponding to the poles. For repeated poles, the residues
|
|
are ordered to correspond to ascending by power fractions.
|
|
p : ndarray
|
|
Poles ordered by magnitude in ascending order.
|
|
k : ndarray
|
|
Coefficients of the direct polynomial term.
|
|
|
|
See Also
|
|
--------
|
|
invresz, residue, unique_roots
|
|
"""
|
|
b = np.asarray(b)
|
|
a = np.asarray(a)
|
|
if (np.issubdtype(b.dtype, np.complexfloating)
|
|
or np.issubdtype(a.dtype, np.complexfloating)):
|
|
b = b.astype(complex)
|
|
a = a.astype(complex)
|
|
else:
|
|
b = b.astype(float)
|
|
a = a.astype(float)
|
|
|
|
b = np.trim_zeros(np.atleast_1d(b), 'b')
|
|
a = np.trim_zeros(np.atleast_1d(a), 'b')
|
|
|
|
if a.size == 0:
|
|
raise ValueError("Denominator `a` is zero.")
|
|
elif a[0] == 0:
|
|
raise ValueError("First coefficient of determinant `a` must be "
|
|
"non-zero.")
|
|
|
|
poles = np.roots(a)
|
|
if b.size == 0:
|
|
return np.zeros(poles.shape), cmplx_sort(poles)[0], np.array([])
|
|
|
|
b_rev = b[::-1]
|
|
a_rev = a[::-1]
|
|
|
|
if len(b_rev) < len(a_rev):
|
|
k_rev = np.empty(0)
|
|
else:
|
|
k_rev, b_rev = np.polydiv(b_rev, a_rev)
|
|
|
|
unique_poles, multiplicity = unique_roots(poles, tol=tol, rtype=rtype)
|
|
unique_poles, order = cmplx_sort(unique_poles)
|
|
multiplicity = multiplicity[order]
|
|
|
|
residues = _compute_residues(1 / unique_poles, multiplicity, b_rev)
|
|
|
|
index = 0
|
|
powers = np.empty(len(residues), dtype=int)
|
|
for pole, mult in zip(unique_poles, multiplicity):
|
|
poles[index:index + mult] = pole
|
|
powers[index:index + mult] = 1 + np.arange(mult)
|
|
index += mult
|
|
|
|
residues *= (-poles) ** powers / a_rev[0]
|
|
|
|
return residues, poles, k_rev[::-1]
|
|
|
|
|
|
def _group_poles(poles, tol, rtype):
|
|
if rtype in ['max', 'maximum']:
|
|
reduce = np.max
|
|
elif rtype in ['min', 'minimum']:
|
|
reduce = np.min
|
|
elif rtype in ['avg', 'mean']:
|
|
reduce = np.mean
|
|
else:
|
|
raise ValueError("`rtype` must be one of "
|
|
"{'max', 'maximum', 'min', 'minimum', 'avg', 'mean'}")
|
|
|
|
unique = []
|
|
multiplicity = []
|
|
|
|
pole = poles[0]
|
|
block = [pole]
|
|
for i in range(1, len(poles)):
|
|
if abs(poles[i] - pole) <= tol:
|
|
block.append(pole)
|
|
else:
|
|
unique.append(reduce(block))
|
|
multiplicity.append(len(block))
|
|
pole = poles[i]
|
|
block = [pole]
|
|
|
|
unique.append(reduce(block))
|
|
multiplicity.append(len(block))
|
|
|
|
return np.asarray(unique), np.asarray(multiplicity)
|
|
|
|
|
|
def invresz(r, p, k, tol=1e-3, rtype='avg'):
|
|
"""Compute b(z) and a(z) from partial fraction expansion.
|
|
|
|
If `M` is the degree of numerator `b` and `N` the degree of denominator
|
|
`a`::
|
|
|
|
b(z) b[0] + b[1] z**(-1) + ... + b[M] z**(-M)
|
|
H(z) = ------ = ------------------------------------------
|
|
a(z) a[0] + a[1] z**(-1) + ... + a[N] z**(-N)
|
|
|
|
then the partial-fraction expansion H(z) is defined as::
|
|
|
|
r[0] r[-1]
|
|
= --------------- + ... + ---------------- + k[0] + k[1]z**(-1) ...
|
|
(1-p[0]z**(-1)) (1-p[-1]z**(-1))
|
|
|
|
If there are any repeated roots (closer than `tol`), then the partial
|
|
fraction expansion has terms like::
|
|
|
|
r[i] r[i+1] r[i+n-1]
|
|
-------------- + ------------------ + ... + ------------------
|
|
(1-p[i]z**(-1)) (1-p[i]z**(-1))**2 (1-p[i]z**(-1))**n
|
|
|
|
This function is used for polynomials in negative powers of z,
|
|
such as digital filters in DSP. For positive powers, use `invres`.
|
|
|
|
Parameters
|
|
----------
|
|
r : array_like
|
|
Residues corresponding to the poles. For repeated poles, the residues
|
|
must be ordered to correspond to ascending by power fractions.
|
|
p : array_like
|
|
Poles. Equal poles must be adjacent.
|
|
k : array_like
|
|
Coefficients of the direct polynomial term.
|
|
tol : float, optional
|
|
The tolerance for two roots to be considered equal in terms of
|
|
the distance between them. Default is 1e-3. See `unique_roots`
|
|
for further details.
|
|
rtype : {'avg', 'min', 'max'}, optional
|
|
Method for computing a root to represent a group of identical roots.
|
|
Default is 'avg'. See `unique_roots` for further details.
|
|
|
|
Returns
|
|
-------
|
|
b : ndarray
|
|
Numerator polynomial coefficients.
|
|
a : ndarray
|
|
Denominator polynomial coefficients.
|
|
|
|
See Also
|
|
--------
|
|
residuez, unique_roots, invres
|
|
|
|
"""
|
|
r = np.atleast_1d(r)
|
|
p = np.atleast_1d(p)
|
|
k = np.trim_zeros(np.atleast_1d(k), 'b')
|
|
|
|
unique_poles, multiplicity = _group_poles(p, tol, rtype)
|
|
factors, denominator = _compute_factors(unique_poles, multiplicity,
|
|
include_powers=True)
|
|
|
|
if len(k) == 0:
|
|
numerator = 0
|
|
else:
|
|
numerator = np.polymul(k[::-1], denominator[::-1])
|
|
|
|
for residue, factor in zip(r, factors):
|
|
numerator = np.polyadd(numerator, residue * factor[::-1])
|
|
|
|
return numerator[::-1], denominator
|
|
|
|
|
|
def resample(x, num, t=None, axis=0, window=None, domain='time'):
|
|
"""
|
|
Resample `x` to `num` samples using Fourier method along the given axis.
|
|
|
|
The resampled signal starts at the same value as `x` but is sampled
|
|
with a spacing of ``len(x) / num * (spacing of x)``. Because a
|
|
Fourier method is used, the signal is assumed to be periodic.
|
|
|
|
Parameters
|
|
----------
|
|
x : array_like
|
|
The data to be resampled.
|
|
num : int
|
|
The number of samples in the resampled signal.
|
|
t : array_like, optional
|
|
If `t` is given, it is assumed to be the equally spaced sample
|
|
positions associated with the signal data in `x`.
|
|
axis : int, optional
|
|
The axis of `x` that is resampled. Default is 0.
|
|
window : array_like, callable, string, float, or tuple, optional
|
|
Specifies the window applied to the signal in the Fourier
|
|
domain. See below for details.
|
|
domain : string, optional
|
|
A string indicating the domain of the input `x`:
|
|
``time`` Consider the input `x` as time-domain (Default),
|
|
``freq`` Consider the input `x` as frequency-domain.
|
|
|
|
Returns
|
|
-------
|
|
resampled_x or (resampled_x, resampled_t)
|
|
Either the resampled array, or, if `t` was given, a tuple
|
|
containing the resampled array and the corresponding resampled
|
|
positions.
|
|
|
|
See Also
|
|
--------
|
|
decimate : Downsample the signal after applying an FIR or IIR filter.
|
|
resample_poly : Resample using polyphase filtering and an FIR filter.
|
|
|
|
Notes
|
|
-----
|
|
The argument `window` controls a Fourier-domain window that tapers
|
|
the Fourier spectrum before zero-padding to alleviate ringing in
|
|
the resampled values for sampled signals you didn't intend to be
|
|
interpreted as band-limited.
|
|
|
|
If `window` is a function, then it is called with a vector of inputs
|
|
indicating the frequency bins (i.e. fftfreq(x.shape[axis]) ).
|
|
|
|
If `window` is an array of the same length as `x.shape[axis]` it is
|
|
assumed to be the window to be applied directly in the Fourier
|
|
domain (with dc and low-frequency first).
|
|
|
|
For any other type of `window`, the function `scipy.signal.get_window`
|
|
is called to generate the window.
|
|
|
|
The first sample of the returned vector is the same as the first
|
|
sample of the input vector. The spacing between samples is changed
|
|
from ``dx`` to ``dx * len(x) / num``.
|
|
|
|
If `t` is not None, then it is used solely to calculate the resampled
|
|
positions `resampled_t`
|
|
|
|
As noted, `resample` uses FFT transformations, which can be very
|
|
slow if the number of input or output samples is large and prime;
|
|
see `scipy.fft.fft`.
|
|
|
|
Examples
|
|
--------
|
|
Note that the end of the resampled data rises to meet the first
|
|
sample of the next cycle:
|
|
|
|
>>> from scipy import signal
|
|
|
|
>>> x = np.linspace(0, 10, 20, endpoint=False)
|
|
>>> y = np.cos(-x**2/6.0)
|
|
>>> f = signal.resample(y, 100)
|
|
>>> xnew = np.linspace(0, 10, 100, endpoint=False)
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> plt.plot(x, y, 'go-', xnew, f, '.-', 10, y[0], 'ro')
|
|
>>> plt.legend(['data', 'resampled'], loc='best')
|
|
>>> plt.show()
|
|
"""
|
|
|
|
if domain not in ('time', 'freq'):
|
|
raise ValueError("Acceptable domain flags are 'time' or"
|
|
" 'freq', not domain={}".format(domain))
|
|
|
|
x = np.asarray(x)
|
|
Nx = x.shape[axis]
|
|
|
|
# Check if we can use faster real FFT
|
|
real_input = np.isrealobj(x)
|
|
|
|
if domain == 'time':
|
|
# Forward transform
|
|
if real_input:
|
|
X = sp_fft.rfft(x, axis=axis)
|
|
else: # Full complex FFT
|
|
X = sp_fft.fft(x, axis=axis)
|
|
else: # domain == 'freq'
|
|
X = x
|
|
|
|
# Apply window to spectrum
|
|
if window is not None:
|
|
if callable(window):
|
|
W = window(sp_fft.fftfreq(Nx))
|
|
elif isinstance(window, np.ndarray):
|
|
if window.shape != (Nx,):
|
|
raise ValueError('window must have the same length as data')
|
|
W = window
|
|
else:
|
|
W = sp_fft.ifftshift(get_window(window, Nx))
|
|
|
|
newshape_W = [1] * x.ndim
|
|
newshape_W[axis] = X.shape[axis]
|
|
if real_input:
|
|
# Fold the window back on itself to mimic complex behavior
|
|
W_real = W.copy()
|
|
W_real[1:] += W_real[-1:0:-1]
|
|
W_real[1:] *= 0.5
|
|
X *= W_real[:newshape_W[axis]].reshape(newshape_W)
|
|
else:
|
|
X *= W.reshape(newshape_W)
|
|
|
|
# Copy each half of the original spectrum to the output spectrum, either
|
|
# truncating high frequences (downsampling) or zero-padding them
|
|
# (upsampling)
|
|
|
|
# Placeholder array for output spectrum
|
|
newshape = list(x.shape)
|
|
if real_input:
|
|
newshape[axis] = num // 2 + 1
|
|
else:
|
|
newshape[axis] = num
|
|
Y = np.zeros(newshape, X.dtype)
|
|
|
|
# Copy positive frequency components (and Nyquist, if present)
|
|
N = min(num, Nx)
|
|
nyq = N // 2 + 1 # Slice index that includes Nyquist if present
|
|
sl = [slice(None)] * x.ndim
|
|
sl[axis] = slice(0, nyq)
|
|
Y[tuple(sl)] = X[tuple(sl)]
|
|
if not real_input:
|
|
# Copy negative frequency components
|
|
if N > 2: # (slice expression doesn't collapse to empty array)
|
|
sl[axis] = slice(nyq - N, None)
|
|
Y[tuple(sl)] = X[tuple(sl)]
|
|
|
|
# Split/join Nyquist component(s) if present
|
|
# So far we have set Y[+N/2]=X[+N/2]
|
|
if N % 2 == 0:
|
|
if num < Nx: # downsampling
|
|
if real_input:
|
|
sl[axis] = slice(N//2, N//2 + 1)
|
|
Y[tuple(sl)] *= 2.
|
|
else:
|
|
# select the component of Y at frequency +N/2,
|
|
# add the component of X at -N/2
|
|
sl[axis] = slice(-N//2, -N//2 + 1)
|
|
Y[tuple(sl)] += X[tuple(sl)]
|
|
elif Nx < num: # upsampling
|
|
# select the component at frequency +N/2 and halve it
|
|
sl[axis] = slice(N//2, N//2 + 1)
|
|
Y[tuple(sl)] *= 0.5
|
|
if not real_input:
|
|
temp = Y[tuple(sl)]
|
|
# set the component at -N/2 equal to the component at +N/2
|
|
sl[axis] = slice(num-N//2, num-N//2 + 1)
|
|
Y[tuple(sl)] = temp
|
|
|
|
# Inverse transform
|
|
if real_input:
|
|
y = sp_fft.irfft(Y, num, axis=axis)
|
|
else:
|
|
y = sp_fft.ifft(Y, axis=axis, overwrite_x=True)
|
|
|
|
y *= (float(num) / float(Nx))
|
|
|
|
if t is None:
|
|
return y
|
|
else:
|
|
new_t = np.arange(0, num) * (t[1] - t[0]) * Nx / float(num) + t[0]
|
|
return y, new_t
|
|
|
|
|
|
def resample_poly(x, up, down, axis=0, window=('kaiser', 5.0),
|
|
padtype='constant', cval=None):
|
|
"""
|
|
Resample `x` along the given axis using polyphase filtering.
|
|
|
|
The signal `x` is upsampled by the factor `up`, a zero-phase low-pass
|
|
FIR filter is applied, and then it is downsampled by the factor `down`.
|
|
The resulting sample rate is ``up / down`` times the original sample
|
|
rate. By default, values beyond the boundary of the signal are assumed
|
|
to be zero during the filtering step.
|
|
|
|
Parameters
|
|
----------
|
|
x : array_like
|
|
The data to be resampled.
|
|
up : int
|
|
The upsampling factor.
|
|
down : int
|
|
The downsampling factor.
|
|
axis : int, optional
|
|
The axis of `x` that is resampled. Default is 0.
|
|
window : string, tuple, or array_like, optional
|
|
Desired window to use to design the low-pass filter, or the FIR filter
|
|
coefficients to employ. See below for details.
|
|
padtype : string, optional
|
|
`constant`, `line`, `mean`, `median`, `maximum`, `minimum` or any of
|
|
the other signal extension modes supported by `scipy.signal.upfirdn`.
|
|
Changes assumptions on values beyond the boundary. If `constant`,
|
|
assumed to be `cval` (default zero). If `line` assumed to continue a
|
|
linear trend defined by the first and last points. `mean`, `median`,
|
|
`maximum` and `minimum` work as in `np.pad` and assume that the values
|
|
beyond the boundary are the mean, median, maximum or minimum
|
|
respectively of the array along the axis.
|
|
|
|
.. versionadded:: 1.4.0
|
|
cval : float, optional
|
|
Value to use if `padtype='constant'`. Default is zero.
|
|
|
|
.. versionadded:: 1.4.0
|
|
|
|
Returns
|
|
-------
|
|
resampled_x : array
|
|
The resampled array.
|
|
|
|
See Also
|
|
--------
|
|
decimate : Downsample the signal after applying an FIR or IIR filter.
|
|
resample : Resample up or down using the FFT method.
|
|
|
|
Notes
|
|
-----
|
|
This polyphase method will likely be faster than the Fourier method
|
|
in `scipy.signal.resample` when the number of samples is large and
|
|
prime, or when the number of samples is large and `up` and `down`
|
|
share a large greatest common denominator. The length of the FIR
|
|
filter used will depend on ``max(up, down) // gcd(up, down)``, and
|
|
the number of operations during polyphase filtering will depend on
|
|
the filter length and `down` (see `scipy.signal.upfirdn` for details).
|
|
|
|
The argument `window` specifies the FIR low-pass filter design.
|
|
|
|
If `window` is an array_like it is assumed to be the FIR filter
|
|
coefficients. Note that the FIR filter is applied after the upsampling
|
|
step, so it should be designed to operate on a signal at a sampling
|
|
frequency higher than the original by a factor of `up//gcd(up, down)`.
|
|
This function's output will be centered with respect to this array, so it
|
|
is best to pass a symmetric filter with an odd number of samples if, as
|
|
is usually the case, a zero-phase filter is desired.
|
|
|
|
For any other type of `window`, the functions `scipy.signal.get_window`
|
|
and `scipy.signal.firwin` are called to generate the appropriate filter
|
|
coefficients.
|
|
|
|
The first sample of the returned vector is the same as the first
|
|
sample of the input vector. The spacing between samples is changed
|
|
from ``dx`` to ``dx * down / float(up)``.
|
|
|
|
Examples
|
|
--------
|
|
By default, the end of the resampled data rises to meet the first
|
|
sample of the next cycle for the FFT method, and gets closer to zero
|
|
for the polyphase method:
|
|
|
|
>>> from scipy import signal
|
|
|
|
>>> x = np.linspace(0, 10, 20, endpoint=False)
|
|
>>> y = np.cos(-x**2/6.0)
|
|
>>> f_fft = signal.resample(y, 100)
|
|
>>> f_poly = signal.resample_poly(y, 100, 20)
|
|
>>> xnew = np.linspace(0, 10, 100, endpoint=False)
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> plt.plot(xnew, f_fft, 'b.-', xnew, f_poly, 'r.-')
|
|
>>> plt.plot(x, y, 'ko-')
|
|
>>> plt.plot(10, y[0], 'bo', 10, 0., 'ro') # boundaries
|
|
>>> plt.legend(['resample', 'resamp_poly', 'data'], loc='best')
|
|
>>> plt.show()
|
|
|
|
This default behaviour can be changed by using the padtype option:
|
|
|
|
>>> import numpy as np
|
|
>>> from scipy import signal
|
|
|
|
>>> N = 5
|
|
>>> x = np.linspace(0, 1, N, endpoint=False)
|
|
>>> y = 2 + x**2 - 1.7*np.sin(x) + .2*np.cos(11*x)
|
|
>>> y2 = 1 + x**3 + 0.1*np.sin(x) + .1*np.cos(11*x)
|
|
>>> Y = np.stack([y, y2], axis=-1)
|
|
>>> up = 4
|
|
>>> xr = np.linspace(0, 1, N*up, endpoint=False)
|
|
|
|
>>> y2 = signal.resample_poly(Y, up, 1, padtype='constant')
|
|
>>> y3 = signal.resample_poly(Y, up, 1, padtype='mean')
|
|
>>> y4 = signal.resample_poly(Y, up, 1, padtype='line')
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> for i in [0,1]:
|
|
... plt.figure()
|
|
... plt.plot(xr, y4[:,i], 'g.', label='line')
|
|
... plt.plot(xr, y3[:,i], 'y.', label='mean')
|
|
... plt.plot(xr, y2[:,i], 'r.', label='constant')
|
|
... plt.plot(x, Y[:,i], 'k-')
|
|
... plt.legend()
|
|
>>> plt.show()
|
|
|
|
"""
|
|
x = np.asarray(x)
|
|
if up != int(up):
|
|
raise ValueError("up must be an integer")
|
|
if down != int(down):
|
|
raise ValueError("down must be an integer")
|
|
up = int(up)
|
|
down = int(down)
|
|
if up < 1 or down < 1:
|
|
raise ValueError('up and down must be >= 1')
|
|
if cval is not None and padtype != 'constant':
|
|
raise ValueError('cval has no effect when padtype is ', padtype)
|
|
|
|
# Determine our up and down factors
|
|
# Use a rational approximation to save computation time on really long
|
|
# signals
|
|
g_ = math.gcd(up, down)
|
|
up //= g_
|
|
down //= g_
|
|
if up == down == 1:
|
|
return x.copy()
|
|
n_in = x.shape[axis]
|
|
n_out = n_in * up
|
|
n_out = n_out // down + bool(n_out % down)
|
|
|
|
if isinstance(window, (list, np.ndarray)):
|
|
window = np.array(window) # use array to force a copy (we modify it)
|
|
if window.ndim > 1:
|
|
raise ValueError('window must be 1-D')
|
|
half_len = (window.size - 1) // 2
|
|
h = window
|
|
else:
|
|
# Design a linear-phase low-pass FIR filter
|
|
max_rate = max(up, down)
|
|
f_c = 1. / max_rate # cutoff of FIR filter (rel. to Nyquist)
|
|
half_len = 10 * max_rate # reasonable cutoff for sinc-like function
|
|
h = firwin(2 * half_len + 1, f_c, window=window)
|
|
h *= up
|
|
|
|
# Zero-pad our filter to put the output samples at the center
|
|
n_pre_pad = (down - half_len % down)
|
|
n_post_pad = 0
|
|
n_pre_remove = (half_len + n_pre_pad) // down
|
|
# We should rarely need to do this given our filter lengths...
|
|
while _output_len(len(h) + n_pre_pad + n_post_pad, n_in,
|
|
up, down) < n_out + n_pre_remove:
|
|
n_post_pad += 1
|
|
h = np.concatenate((np.zeros(n_pre_pad, dtype=h.dtype), h,
|
|
np.zeros(n_post_pad, dtype=h.dtype)))
|
|
n_pre_remove_end = n_pre_remove + n_out
|
|
|
|
# Remove background depending on the padtype option
|
|
funcs = {'mean': np.mean, 'median': np.median,
|
|
'minimum': np.amin, 'maximum': np.amax}
|
|
upfirdn_kwargs = {'mode': 'constant', 'cval': 0}
|
|
if padtype in funcs:
|
|
background_values = funcs[padtype](x, axis=axis, keepdims=True)
|
|
elif padtype in _upfirdn_modes:
|
|
upfirdn_kwargs = {'mode': padtype}
|
|
if padtype == 'constant':
|
|
if cval is None:
|
|
cval = 0
|
|
upfirdn_kwargs['cval'] = cval
|
|
else:
|
|
raise ValueError(
|
|
'padtype must be one of: maximum, mean, median, minimum, ' +
|
|
', '.join(_upfirdn_modes))
|
|
|
|
if padtype in funcs:
|
|
x = x - background_values
|
|
|
|
# filter then remove excess
|
|
y = upfirdn(h, x, up, down, axis=axis, **upfirdn_kwargs)
|
|
keep = [slice(None), ]*x.ndim
|
|
keep[axis] = slice(n_pre_remove, n_pre_remove_end)
|
|
y_keep = y[tuple(keep)]
|
|
|
|
# Add background back
|
|
if padtype in funcs:
|
|
y_keep += background_values
|
|
|
|
return y_keep
|
|
|
|
|
|
def vectorstrength(events, period):
|
|
'''
|
|
Determine the vector strength of the events corresponding to the given
|
|
period.
|
|
|
|
The vector strength is a measure of phase synchrony, how well the
|
|
timing of the events is synchronized to a single period of a periodic
|
|
signal.
|
|
|
|
If multiple periods are used, calculate the vector strength of each.
|
|
This is called the "resonating vector strength".
|
|
|
|
Parameters
|
|
----------
|
|
events : 1D array_like
|
|
An array of time points containing the timing of the events.
|
|
period : float or array_like
|
|
The period of the signal that the events should synchronize to.
|
|
The period is in the same units as `events`. It can also be an array
|
|
of periods, in which case the outputs are arrays of the same length.
|
|
|
|
Returns
|
|
-------
|
|
strength : float or 1D array
|
|
The strength of the synchronization. 1.0 is perfect synchronization
|
|
and 0.0 is no synchronization. If `period` is an array, this is also
|
|
an array with each element containing the vector strength at the
|
|
corresponding period.
|
|
phase : float or array
|
|
The phase that the events are most strongly synchronized to in radians.
|
|
If `period` is an array, this is also an array with each element
|
|
containing the phase for the corresponding period.
|
|
|
|
References
|
|
----------
|
|
van Hemmen, JL, Longtin, A, and Vollmayr, AN. Testing resonating vector
|
|
strength: Auditory system, electric fish, and noise.
|
|
Chaos 21, 047508 (2011);
|
|
:doi:`10.1063/1.3670512`.
|
|
van Hemmen, JL. Vector strength after Goldberg, Brown, and von Mises:
|
|
biological and mathematical perspectives. Biol Cybern.
|
|
2013 Aug;107(4):385-96. :doi:`10.1007/s00422-013-0561-7`.
|
|
van Hemmen, JL and Vollmayr, AN. Resonating vector strength: what happens
|
|
when we vary the "probing" frequency while keeping the spike times
|
|
fixed. Biol Cybern. 2013 Aug;107(4):491-94.
|
|
:doi:`10.1007/s00422-013-0560-8`.
|
|
'''
|
|
events = np.asarray(events)
|
|
period = np.asarray(period)
|
|
if events.ndim > 1:
|
|
raise ValueError('events cannot have dimensions more than 1')
|
|
if period.ndim > 1:
|
|
raise ValueError('period cannot have dimensions more than 1')
|
|
|
|
# we need to know later if period was originally a scalar
|
|
scalarperiod = not period.ndim
|
|
|
|
events = np.atleast_2d(events)
|
|
period = np.atleast_2d(period)
|
|
if (period <= 0).any():
|
|
raise ValueError('periods must be positive')
|
|
|
|
# this converts the times to vectors
|
|
vectors = np.exp(np.dot(2j*np.pi/period.T, events))
|
|
|
|
# the vector strength is just the magnitude of the mean of the vectors
|
|
# the vector phase is the angle of the mean of the vectors
|
|
vectormean = np.mean(vectors, axis=1)
|
|
strength = abs(vectormean)
|
|
phase = np.angle(vectormean)
|
|
|
|
# if the original period was a scalar, return scalars
|
|
if scalarperiod:
|
|
strength = strength[0]
|
|
phase = phase[0]
|
|
return strength, phase
|
|
|
|
|
|
def detrend(data, axis=-1, type='linear', bp=0, overwrite_data=False):
|
|
"""
|
|
Remove linear trend along axis from data.
|
|
|
|
Parameters
|
|
----------
|
|
data : array_like
|
|
The input data.
|
|
axis : int, optional
|
|
The axis along which to detrend the data. By default this is the
|
|
last axis (-1).
|
|
type : {'linear', 'constant'}, optional
|
|
The type of detrending. If ``type == 'linear'`` (default),
|
|
the result of a linear least-squares fit to `data` is subtracted
|
|
from `data`.
|
|
If ``type == 'constant'``, only the mean of `data` is subtracted.
|
|
bp : array_like of ints, optional
|
|
A sequence of break points. If given, an individual linear fit is
|
|
performed for each part of `data` between two break points.
|
|
Break points are specified as indices into `data`. This parameter
|
|
only has an effect when ``type == 'linear'``.
|
|
overwrite_data : bool, optional
|
|
If True, perform in place detrending and avoid a copy. Default is False
|
|
|
|
Returns
|
|
-------
|
|
ret : ndarray
|
|
The detrended input data.
|
|
|
|
Examples
|
|
--------
|
|
>>> from scipy import signal
|
|
>>> randgen = np.random.RandomState(9)
|
|
>>> npoints = 1000
|
|
>>> noise = randgen.randn(npoints)
|
|
>>> x = 3 + 2*np.linspace(0, 1, npoints) + noise
|
|
>>> (signal.detrend(x) - noise).max() < 0.01
|
|
True
|
|
|
|
"""
|
|
if type not in ['linear', 'l', 'constant', 'c']:
|
|
raise ValueError("Trend type must be 'linear' or 'constant'.")
|
|
data = np.asarray(data)
|
|
dtype = data.dtype.char
|
|
if dtype not in 'dfDF':
|
|
dtype = 'd'
|
|
if type in ['constant', 'c']:
|
|
ret = data - np.expand_dims(np.mean(data, axis), axis)
|
|
return ret
|
|
else:
|
|
dshape = data.shape
|
|
N = dshape[axis]
|
|
bp = np.sort(np.unique(np.r_[0, bp, N]))
|
|
if np.any(bp > N):
|
|
raise ValueError("Breakpoints must be less than length "
|
|
"of data along given axis.")
|
|
Nreg = len(bp) - 1
|
|
# Restructure data so that axis is along first dimension and
|
|
# all other dimensions are collapsed into second dimension
|
|
rnk = len(dshape)
|
|
if axis < 0:
|
|
axis = axis + rnk
|
|
newdims = np.r_[axis, 0:axis, axis + 1:rnk]
|
|
newdata = np.reshape(np.transpose(data, tuple(newdims)),
|
|
(N, _prod(dshape) // N))
|
|
if not overwrite_data:
|
|
newdata = newdata.copy() # make sure we have a copy
|
|
if newdata.dtype.char not in 'dfDF':
|
|
newdata = newdata.astype(dtype)
|
|
# Find leastsq fit and remove it for each piece
|
|
for m in range(Nreg):
|
|
Npts = bp[m + 1] - bp[m]
|
|
A = np.ones((Npts, 2), dtype)
|
|
A[:, 0] = np.cast[dtype](np.arange(1, Npts + 1) * 1.0 / Npts)
|
|
sl = slice(bp[m], bp[m + 1])
|
|
coef, resids, rank, s = linalg.lstsq(A, newdata[sl])
|
|
newdata[sl] = newdata[sl] - np.dot(A, coef)
|
|
# Put data back in original shape.
|
|
tdshape = np.take(dshape, newdims, 0)
|
|
ret = np.reshape(newdata, tuple(tdshape))
|
|
vals = list(range(1, rnk))
|
|
olddims = vals[:axis] + [0] + vals[axis:]
|
|
ret = np.transpose(ret, tuple(olddims))
|
|
return ret
|
|
|
|
|
|
def lfilter_zi(b, a):
|
|
"""
|
|
Construct initial conditions for lfilter for step response steady-state.
|
|
|
|
Compute an initial state `zi` for the `lfilter` function that corresponds
|
|
to the steady state of the step response.
|
|
|
|
A typical use of this function is to set the initial state so that the
|
|
output of the filter starts at the same value as the first element of
|
|
the signal to be filtered.
|
|
|
|
Parameters
|
|
----------
|
|
b, a : array_like (1-D)
|
|
The IIR filter coefficients. See `lfilter` for more
|
|
information.
|
|
|
|
Returns
|
|
-------
|
|
zi : 1-D ndarray
|
|
The initial state for the filter.
|
|
|
|
See Also
|
|
--------
|
|
lfilter, lfiltic, filtfilt
|
|
|
|
Notes
|
|
-----
|
|
A linear filter with order m has a state space representation (A, B, C, D),
|
|
for which the output y of the filter can be expressed as::
|
|
|
|
z(n+1) = A*z(n) + B*x(n)
|
|
y(n) = C*z(n) + D*x(n)
|
|
|
|
where z(n) is a vector of length m, A has shape (m, m), B has shape
|
|
(m, 1), C has shape (1, m) and D has shape (1, 1) (assuming x(n) is
|
|
a scalar). lfilter_zi solves::
|
|
|
|
zi = A*zi + B
|
|
|
|
In other words, it finds the initial condition for which the response
|
|
to an input of all ones is a constant.
|
|
|
|
Given the filter coefficients `a` and `b`, the state space matrices
|
|
for the transposed direct form II implementation of the linear filter,
|
|
which is the implementation used by scipy.signal.lfilter, are::
|
|
|
|
A = scipy.linalg.companion(a).T
|
|
B = b[1:] - a[1:]*b[0]
|
|
|
|
assuming `a[0]` is 1.0; if `a[0]` is not 1, `a` and `b` are first
|
|
divided by a[0].
|
|
|
|
Examples
|
|
--------
|
|
The following code creates a lowpass Butterworth filter. Then it
|
|
applies that filter to an array whose values are all 1.0; the
|
|
output is also all 1.0, as expected for a lowpass filter. If the
|
|
`zi` argument of `lfilter` had not been given, the output would have
|
|
shown the transient signal.
|
|
|
|
>>> from numpy import array, ones
|
|
>>> from scipy.signal import lfilter, lfilter_zi, butter
|
|
>>> b, a = butter(5, 0.25)
|
|
>>> zi = lfilter_zi(b, a)
|
|
>>> y, zo = lfilter(b, a, ones(10), zi=zi)
|
|
>>> y
|
|
array([1., 1., 1., 1., 1., 1., 1., 1., 1., 1.])
|
|
|
|
Another example:
|
|
|
|
>>> x = array([0.5, 0.5, 0.5, 0.0, 0.0, 0.0, 0.0])
|
|
>>> y, zf = lfilter(b, a, x, zi=zi*x[0])
|
|
>>> y
|
|
array([ 0.5 , 0.5 , 0.5 , 0.49836039, 0.48610528,
|
|
0.44399389, 0.35505241])
|
|
|
|
Note that the `zi` argument to `lfilter` was computed using
|
|
`lfilter_zi` and scaled by `x[0]`. Then the output `y` has no
|
|
transient until the input drops from 0.5 to 0.0.
|
|
|
|
"""
|
|
|
|
# FIXME: Can this function be replaced with an appropriate
|
|
# use of lfiltic? For example, when b,a = butter(N,Wn),
|
|
# lfiltic(b, a, y=numpy.ones_like(a), x=numpy.ones_like(b)).
|
|
#
|
|
|
|
# We could use scipy.signal.normalize, but it uses warnings in
|
|
# cases where a ValueError is more appropriate, and it allows
|
|
# b to be 2D.
|
|
b = np.atleast_1d(b)
|
|
if b.ndim != 1:
|
|
raise ValueError("Numerator b must be 1-D.")
|
|
a = np.atleast_1d(a)
|
|
if a.ndim != 1:
|
|
raise ValueError("Denominator a must be 1-D.")
|
|
|
|
while len(a) > 1 and a[0] == 0.0:
|
|
a = a[1:]
|
|
if a.size < 1:
|
|
raise ValueError("There must be at least one nonzero `a` coefficient.")
|
|
|
|
if a[0] != 1.0:
|
|
# Normalize the coefficients so a[0] == 1.
|
|
b = b / a[0]
|
|
a = a / a[0]
|
|
|
|
n = max(len(a), len(b))
|
|
|
|
# Pad a or b with zeros so they are the same length.
|
|
if len(a) < n:
|
|
a = np.r_[a, np.zeros(n - len(a))]
|
|
elif len(b) < n:
|
|
b = np.r_[b, np.zeros(n - len(b))]
|
|
|
|
IminusA = np.eye(n - 1, dtype=np.result_type(a, b)) - linalg.companion(a).T
|
|
B = b[1:] - a[1:] * b[0]
|
|
# Solve zi = A*zi + B
|
|
zi = np.linalg.solve(IminusA, B)
|
|
|
|
# For future reference: we could also use the following
|
|
# explicit formulas to solve the linear system:
|
|
#
|
|
# zi = np.zeros(n - 1)
|
|
# zi[0] = B.sum() / IminusA[:,0].sum()
|
|
# asum = 1.0
|
|
# csum = 0.0
|
|
# for k in range(1,n-1):
|
|
# asum += a[k]
|
|
# csum += b[k] - a[k]*b[0]
|
|
# zi[k] = asum*zi[0] - csum
|
|
|
|
return zi
|
|
|
|
|
|
def sosfilt_zi(sos):
|
|
"""
|
|
Construct initial conditions for sosfilt for step response steady-state.
|
|
|
|
Compute an initial state `zi` for the `sosfilt` function that corresponds
|
|
to the steady state of the step response.
|
|
|
|
A typical use of this function is to set the initial state so that the
|
|
output of the filter starts at the same value as the first element of
|
|
the signal to be filtered.
|
|
|
|
Parameters
|
|
----------
|
|
sos : array_like
|
|
Array of second-order filter coefficients, must have shape
|
|
``(n_sections, 6)``. See `sosfilt` for the SOS filter format
|
|
specification.
|
|
|
|
Returns
|
|
-------
|
|
zi : ndarray
|
|
Initial conditions suitable for use with ``sosfilt``, shape
|
|
``(n_sections, 2)``.
|
|
|
|
See Also
|
|
--------
|
|
sosfilt, zpk2sos
|
|
|
|
Notes
|
|
-----
|
|
.. versionadded:: 0.16.0
|
|
|
|
Examples
|
|
--------
|
|
Filter a rectangular pulse that begins at time 0, with and without
|
|
the use of the `zi` argument of `scipy.signal.sosfilt`.
|
|
|
|
>>> from scipy import signal
|
|
>>> import matplotlib.pyplot as plt
|
|
|
|
>>> sos = signal.butter(9, 0.125, output='sos')
|
|
>>> zi = signal.sosfilt_zi(sos)
|
|
>>> x = (np.arange(250) < 100).astype(int)
|
|
>>> f1 = signal.sosfilt(sos, x)
|
|
>>> f2, zo = signal.sosfilt(sos, x, zi=zi)
|
|
|
|
>>> plt.plot(x, 'k--', label='x')
|
|
>>> plt.plot(f1, 'b', alpha=0.5, linewidth=2, label='filtered')
|
|
>>> plt.plot(f2, 'g', alpha=0.25, linewidth=4, label='filtered with zi')
|
|
>>> plt.legend(loc='best')
|
|
>>> plt.show()
|
|
|
|
"""
|
|
sos = np.asarray(sos)
|
|
if sos.ndim != 2 or sos.shape[1] != 6:
|
|
raise ValueError('sos must be shape (n_sections, 6)')
|
|
|
|
if sos.dtype.kind in 'bui':
|
|
sos = sos.astype(np.float64)
|
|
|
|
n_sections = sos.shape[0]
|
|
zi = np.empty((n_sections, 2), dtype=sos.dtype)
|
|
scale = 1.0
|
|
for section in range(n_sections):
|
|
b = sos[section, :3]
|
|
a = sos[section, 3:]
|
|
zi[section] = scale * lfilter_zi(b, a)
|
|
# If H(z) = B(z)/A(z) is this section's transfer function, then
|
|
# b.sum()/a.sum() is H(1), the gain at omega=0. That's the steady
|
|
# state value of this section's step response.
|
|
scale *= b.sum() / a.sum()
|
|
|
|
return zi
|
|
|
|
|
|
def _filtfilt_gust(b, a, x, axis=-1, irlen=None):
|
|
"""Forward-backward IIR filter that uses Gustafsson's method.
|
|
|
|
Apply the IIR filter defined by `(b,a)` to `x` twice, first forward
|
|
then backward, using Gustafsson's initial conditions [1]_.
|
|
|
|
Let ``y_fb`` be the result of filtering first forward and then backward,
|
|
and let ``y_bf`` be the result of filtering first backward then forward.
|
|
Gustafsson's method is to compute initial conditions for the forward
|
|
pass and the backward pass such that ``y_fb == y_bf``.
|
|
|
|
Parameters
|
|
----------
|
|
b : scalar or 1-D ndarray
|
|
Numerator coefficients of the filter.
|
|
a : scalar or 1-D ndarray
|
|
Denominator coefficients of the filter.
|
|
x : ndarray
|
|
Data to be filtered.
|
|
axis : int, optional
|
|
Axis of `x` to be filtered. Default is -1.
|
|
irlen : int or None, optional
|
|
The length of the nonnegligible part of the impulse response.
|
|
If `irlen` is None, or if the length of the signal is less than
|
|
``2 * irlen``, then no part of the impulse response is ignored.
|
|
|
|
Returns
|
|
-------
|
|
y : ndarray
|
|
The filtered data.
|
|
x0 : ndarray
|
|
Initial condition for the forward filter.
|
|
x1 : ndarray
|
|
Initial condition for the backward filter.
|
|
|
|
Notes
|
|
-----
|
|
Typically the return values `x0` and `x1` are not needed by the
|
|
caller. The intended use of these return values is in unit tests.
|
|
|
|
References
|
|
----------
|
|
.. [1] F. Gustaffson. Determining the initial states in forward-backward
|
|
filtering. Transactions on Signal Processing, 46(4):988-992, 1996.
|
|
|
|
"""
|
|
# In the comments, "Gustafsson's paper" and [1] refer to the
|
|
# paper referenced in the docstring.
|
|
|
|
b = np.atleast_1d(b)
|
|
a = np.atleast_1d(a)
|
|
|
|
order = max(len(b), len(a)) - 1
|
|
if order == 0:
|
|
# The filter is just scalar multiplication, with no state.
|
|
scale = (b[0] / a[0])**2
|
|
y = scale * x
|
|
return y, np.array([]), np.array([])
|
|
|
|
if axis != -1 or axis != x.ndim - 1:
|
|
# Move the axis containing the data to the end.
|
|
x = np.swapaxes(x, axis, x.ndim - 1)
|
|
|
|
# n is the number of samples in the data to be filtered.
|
|
n = x.shape[-1]
|
|
|
|
if irlen is None or n <= 2*irlen:
|
|
m = n
|
|
else:
|
|
m = irlen
|
|
|
|
# Create Obs, the observability matrix (called O in the paper).
|
|
# This matrix can be interpreted as the operator that propagates
|
|
# an arbitrary initial state to the output, assuming the input is
|
|
# zero.
|
|
# In Gustafsson's paper, the forward and backward filters are not
|
|
# necessarily the same, so he has both O_f and O_b. We use the same
|
|
# filter in both directions, so we only need O. The same comment
|
|
# applies to S below.
|
|
Obs = np.zeros((m, order))
|
|
zi = np.zeros(order)
|
|
zi[0] = 1
|
|
Obs[:, 0] = lfilter(b, a, np.zeros(m), zi=zi)[0]
|
|
for k in range(1, order):
|
|
Obs[k:, k] = Obs[:-k, 0]
|
|
|
|
# Obsr is O^R (Gustafsson's notation for row-reversed O)
|
|
Obsr = Obs[::-1]
|
|
|
|
# Create S. S is the matrix that applies the filter to the reversed
|
|
# propagated initial conditions. That is,
|
|
# out = S.dot(zi)
|
|
# is the same as
|
|
# tmp, _ = lfilter(b, a, zeros(), zi=zi) # Propagate ICs.
|
|
# out = lfilter(b, a, tmp[::-1]) # Reverse and filter.
|
|
|
|
# Equations (5) & (6) of [1]
|
|
S = lfilter(b, a, Obs[::-1], axis=0)
|
|
|
|
# Sr is S^R (row-reversed S)
|
|
Sr = S[::-1]
|
|
|
|
# M is [(S^R - O), (O^R - S)]
|
|
if m == n:
|
|
M = np.hstack((Sr - Obs, Obsr - S))
|
|
else:
|
|
# Matrix described in section IV of [1].
|
|
M = np.zeros((2*m, 2*order))
|
|
M[:m, :order] = Sr - Obs
|
|
M[m:, order:] = Obsr - S
|
|
|
|
# Naive forward-backward and backward-forward filters.
|
|
# These have large transients because the filters use zero initial
|
|
# conditions.
|
|
y_f = lfilter(b, a, x)
|
|
y_fb = lfilter(b, a, y_f[..., ::-1])[..., ::-1]
|
|
|
|
y_b = lfilter(b, a, x[..., ::-1])[..., ::-1]
|
|
y_bf = lfilter(b, a, y_b)
|
|
|
|
delta_y_bf_fb = y_bf - y_fb
|
|
if m == n:
|
|
delta = delta_y_bf_fb
|
|
else:
|
|
start_m = delta_y_bf_fb[..., :m]
|
|
end_m = delta_y_bf_fb[..., -m:]
|
|
delta = np.concatenate((start_m, end_m), axis=-1)
|
|
|
|
# ic_opt holds the "optimal" initial conditions.
|
|
# The following code computes the result shown in the formula
|
|
# of the paper between equations (6) and (7).
|
|
if delta.ndim == 1:
|
|
ic_opt = linalg.lstsq(M, delta)[0]
|
|
else:
|
|
# Reshape delta so it can be used as an array of multiple
|
|
# right-hand-sides in linalg.lstsq.
|
|
delta2d = delta.reshape(-1, delta.shape[-1]).T
|
|
ic_opt0 = linalg.lstsq(M, delta2d)[0].T
|
|
ic_opt = ic_opt0.reshape(delta.shape[:-1] + (M.shape[-1],))
|
|
|
|
# Now compute the filtered signal using equation (7) of [1].
|
|
# First, form [S^R, O^R] and call it W.
|
|
if m == n:
|
|
W = np.hstack((Sr, Obsr))
|
|
else:
|
|
W = np.zeros((2*m, 2*order))
|
|
W[:m, :order] = Sr
|
|
W[m:, order:] = Obsr
|
|
|
|
# Equation (7) of [1] says
|
|
# Y_fb^opt = Y_fb^0 + W * [x_0^opt; x_{N-1}^opt]
|
|
# `wic` is (almost) the product on the right.
|
|
# W has shape (m, 2*order), and ic_opt has shape (..., 2*order),
|
|
# so we can't use W.dot(ic_opt). Instead, we dot ic_opt with W.T,
|
|
# so wic has shape (..., m).
|
|
wic = ic_opt.dot(W.T)
|
|
|
|
# `wic` is "almost" the product of W and the optimal ICs in equation
|
|
# (7)--if we're using a truncated impulse response (m < n), `wic`
|
|
# contains only the adjustments required for the ends of the signal.
|
|
# Here we form y_opt, taking this into account if necessary.
|
|
y_opt = y_fb
|
|
if m == n:
|
|
y_opt += wic
|
|
else:
|
|
y_opt[..., :m] += wic[..., :m]
|
|
y_opt[..., -m:] += wic[..., -m:]
|
|
|
|
x0 = ic_opt[..., :order]
|
|
x1 = ic_opt[..., -order:]
|
|
if axis != -1 or axis != x.ndim - 1:
|
|
# Restore the data axis to its original position.
|
|
x0 = np.swapaxes(x0, axis, x.ndim - 1)
|
|
x1 = np.swapaxes(x1, axis, x.ndim - 1)
|
|
y_opt = np.swapaxes(y_opt, axis, x.ndim - 1)
|
|
|
|
return y_opt, x0, x1
|
|
|
|
|
|
def filtfilt(b, a, x, axis=-1, padtype='odd', padlen=None, method='pad',
|
|
irlen=None):
|
|
"""
|
|
Apply a digital filter forward and backward to a signal.
|
|
|
|
This function applies a linear digital filter twice, once forward and
|
|
once backwards. The combined filter has zero phase and a filter order
|
|
twice that of the original.
|
|
|
|
The function provides options for handling the edges of the signal.
|
|
|
|
The function `sosfiltfilt` (and filter design using ``output='sos'``)
|
|
should be preferred over `filtfilt` for most filtering tasks, as
|
|
second-order sections have fewer numerical problems.
|
|
|
|
Parameters
|
|
----------
|
|
b : (N,) array_like
|
|
The numerator coefficient vector of the filter.
|
|
a : (N,) array_like
|
|
The denominator coefficient vector of the filter. If ``a[0]``
|
|
is not 1, then both `a` and `b` are normalized by ``a[0]``.
|
|
x : array_like
|
|
The array of data to be filtered.
|
|
axis : int, optional
|
|
The axis of `x` to which the filter is applied.
|
|
Default is -1.
|
|
padtype : str or None, optional
|
|
Must be 'odd', 'even', 'constant', or None. This determines the
|
|
type of extension to use for the padded signal to which the filter
|
|
is applied. If `padtype` is None, no padding is used. The default
|
|
is 'odd'.
|
|
padlen : int or None, optional
|
|
The number of elements by which to extend `x` at both ends of
|
|
`axis` before applying the filter. This value must be less than
|
|
``x.shape[axis] - 1``. ``padlen=0`` implies no padding.
|
|
The default value is ``3 * max(len(a), len(b))``.
|
|
method : str, optional
|
|
Determines the method for handling the edges of the signal, either
|
|
"pad" or "gust". When `method` is "pad", the signal is padded; the
|
|
type of padding is determined by `padtype` and `padlen`, and `irlen`
|
|
is ignored. When `method` is "gust", Gustafsson's method is used,
|
|
and `padtype` and `padlen` are ignored.
|
|
irlen : int or None, optional
|
|
When `method` is "gust", `irlen` specifies the length of the
|
|
impulse response of the filter. If `irlen` is None, no part
|
|
of the impulse response is ignored. For a long signal, specifying
|
|
`irlen` can significantly improve the performance of the filter.
|
|
|
|
Returns
|
|
-------
|
|
y : ndarray
|
|
The filtered output with the same shape as `x`.
|
|
|
|
See Also
|
|
--------
|
|
sosfiltfilt, lfilter_zi, lfilter, lfiltic, savgol_filter, sosfilt
|
|
|
|
Notes
|
|
-----
|
|
When `method` is "pad", the function pads the data along the given axis
|
|
in one of three ways: odd, even or constant. The odd and even extensions
|
|
have the corresponding symmetry about the end point of the data. The
|
|
constant extension extends the data with the values at the end points. On
|
|
both the forward and backward passes, the initial condition of the
|
|
filter is found by using `lfilter_zi` and scaling it by the end point of
|
|
the extended data.
|
|
|
|
When `method` is "gust", Gustafsson's method [1]_ is used. Initial
|
|
conditions are chosen for the forward and backward passes so that the
|
|
forward-backward filter gives the same result as the backward-forward
|
|
filter.
|
|
|
|
The option to use Gustaffson's method was added in scipy version 0.16.0.
|
|
|
|
References
|
|
----------
|
|
.. [1] F. Gustaffson, "Determining the initial states in forward-backward
|
|
filtering", Transactions on Signal Processing, Vol. 46, pp. 988-992,
|
|
1996.
|
|
|
|
Examples
|
|
--------
|
|
The examples will use several functions from `scipy.signal`.
|
|
|
|
>>> from scipy import signal
|
|
>>> import matplotlib.pyplot as plt
|
|
|
|
First we create a one second signal that is the sum of two pure sine
|
|
waves, with frequencies 5 Hz and 250 Hz, sampled at 2000 Hz.
|
|
|
|
>>> t = np.linspace(0, 1.0, 2001)
|
|
>>> xlow = np.sin(2 * np.pi * 5 * t)
|
|
>>> xhigh = np.sin(2 * np.pi * 250 * t)
|
|
>>> x = xlow + xhigh
|
|
|
|
Now create a lowpass Butterworth filter with a cutoff of 0.125 times
|
|
the Nyquist frequency, or 125 Hz, and apply it to ``x`` with `filtfilt`.
|
|
The result should be approximately ``xlow``, with no phase shift.
|
|
|
|
>>> b, a = signal.butter(8, 0.125)
|
|
>>> y = signal.filtfilt(b, a, x, padlen=150)
|
|
>>> np.abs(y - xlow).max()
|
|
9.1086182074789912e-06
|
|
|
|
We get a fairly clean result for this artificial example because
|
|
the odd extension is exact, and with the moderately long padding,
|
|
the filter's transients have dissipated by the time the actual data
|
|
is reached. In general, transient effects at the edges are
|
|
unavoidable.
|
|
|
|
The following example demonstrates the option ``method="gust"``.
|
|
|
|
First, create a filter.
|
|
|
|
>>> b, a = signal.ellip(4, 0.01, 120, 0.125) # Filter to be applied.
|
|
>>> np.random.seed(123456)
|
|
|
|
`sig` is a random input signal to be filtered.
|
|
|
|
>>> n = 60
|
|
>>> sig = np.random.randn(n)**3 + 3*np.random.randn(n).cumsum()
|
|
|
|
Apply `filtfilt` to `sig`, once using the Gustafsson method, and
|
|
once using padding, and plot the results for comparison.
|
|
|
|
>>> fgust = signal.filtfilt(b, a, sig, method="gust")
|
|
>>> fpad = signal.filtfilt(b, a, sig, padlen=50)
|
|
>>> plt.plot(sig, 'k-', label='input')
|
|
>>> plt.plot(fgust, 'b-', linewidth=4, label='gust')
|
|
>>> plt.plot(fpad, 'c-', linewidth=1.5, label='pad')
|
|
>>> plt.legend(loc='best')
|
|
>>> plt.show()
|
|
|
|
The `irlen` argument can be used to improve the performance
|
|
of Gustafsson's method.
|
|
|
|
Estimate the impulse response length of the filter.
|
|
|
|
>>> z, p, k = signal.tf2zpk(b, a)
|
|
>>> eps = 1e-9
|
|
>>> r = np.max(np.abs(p))
|
|
>>> approx_impulse_len = int(np.ceil(np.log(eps) / np.log(r)))
|
|
>>> approx_impulse_len
|
|
137
|
|
|
|
Apply the filter to a longer signal, with and without the `irlen`
|
|
argument. The difference between `y1` and `y2` is small. For long
|
|
signals, using `irlen` gives a significant performance improvement.
|
|
|
|
>>> x = np.random.randn(5000)
|
|
>>> y1 = signal.filtfilt(b, a, x, method='gust')
|
|
>>> y2 = signal.filtfilt(b, a, x, method='gust', irlen=approx_impulse_len)
|
|
>>> print(np.max(np.abs(y1 - y2)))
|
|
1.80056858312e-10
|
|
|
|
"""
|
|
b = np.atleast_1d(b)
|
|
a = np.atleast_1d(a)
|
|
x = np.asarray(x)
|
|
|
|
if method not in ["pad", "gust"]:
|
|
raise ValueError("method must be 'pad' or 'gust'.")
|
|
|
|
if method == "gust":
|
|
y, z1, z2 = _filtfilt_gust(b, a, x, axis=axis, irlen=irlen)
|
|
return y
|
|
|
|
# method == "pad"
|
|
edge, ext = _validate_pad(padtype, padlen, x, axis,
|
|
ntaps=max(len(a), len(b)))
|
|
|
|
# Get the steady state of the filter's step response.
|
|
zi = lfilter_zi(b, a)
|
|
|
|
# Reshape zi and create x0 so that zi*x0 broadcasts
|
|
# to the correct value for the 'zi' keyword argument
|
|
# to lfilter.
|
|
zi_shape = [1] * x.ndim
|
|
zi_shape[axis] = zi.size
|
|
zi = np.reshape(zi, zi_shape)
|
|
x0 = axis_slice(ext, stop=1, axis=axis)
|
|
|
|
# Forward filter.
|
|
(y, zf) = lfilter(b, a, ext, axis=axis, zi=zi * x0)
|
|
|
|
# Backward filter.
|
|
# Create y0 so zi*y0 broadcasts appropriately.
|
|
y0 = axis_slice(y, start=-1, axis=axis)
|
|
(y, zf) = lfilter(b, a, axis_reverse(y, axis=axis), axis=axis, zi=zi * y0)
|
|
|
|
# Reverse y.
|
|
y = axis_reverse(y, axis=axis)
|
|
|
|
if edge > 0:
|
|
# Slice the actual signal from the extended signal.
|
|
y = axis_slice(y, start=edge, stop=-edge, axis=axis)
|
|
|
|
return y
|
|
|
|
|
|
def _validate_pad(padtype, padlen, x, axis, ntaps):
|
|
"""Helper to validate padding for filtfilt"""
|
|
if padtype not in ['even', 'odd', 'constant', None]:
|
|
raise ValueError(("Unknown value '%s' given to padtype. padtype "
|
|
"must be 'even', 'odd', 'constant', or None.") %
|
|
padtype)
|
|
|
|
if padtype is None:
|
|
padlen = 0
|
|
|
|
if padlen is None:
|
|
# Original padding; preserved for backwards compatibility.
|
|
edge = ntaps * 3
|
|
else:
|
|
edge = padlen
|
|
|
|
# x's 'axis' dimension must be bigger than edge.
|
|
if x.shape[axis] <= edge:
|
|
raise ValueError("The length of the input vector x must be greater "
|
|
"than padlen, which is %d." % edge)
|
|
|
|
if padtype is not None and edge > 0:
|
|
# Make an extension of length `edge` at each
|
|
# end of the input array.
|
|
if padtype == 'even':
|
|
ext = even_ext(x, edge, axis=axis)
|
|
elif padtype == 'odd':
|
|
ext = odd_ext(x, edge, axis=axis)
|
|
else:
|
|
ext = const_ext(x, edge, axis=axis)
|
|
else:
|
|
ext = x
|
|
return edge, ext
|
|
|
|
|
|
def _validate_x(x):
|
|
x = np.asarray(x)
|
|
if x.ndim == 0:
|
|
raise ValueError('x must be at least 1-D')
|
|
return x
|
|
|
|
|
|
def sosfilt(sos, x, axis=-1, zi=None):
|
|
"""
|
|
Filter data along one dimension using cascaded second-order sections.
|
|
|
|
Filter a data sequence, `x`, using a digital IIR filter defined by
|
|
`sos`.
|
|
|
|
Parameters
|
|
----------
|
|
sos : array_like
|
|
Array of second-order filter coefficients, must have shape
|
|
``(n_sections, 6)``. Each row corresponds to a second-order
|
|
section, with the first three columns providing the numerator
|
|
coefficients and the last three providing the denominator
|
|
coefficients.
|
|
x : array_like
|
|
An N-dimensional input array.
|
|
axis : int, optional
|
|
The axis of the input data array along which to apply the
|
|
linear filter. The filter is applied to each subarray along
|
|
this axis. Default is -1.
|
|
zi : array_like, optional
|
|
Initial conditions for the cascaded filter delays. It is a (at
|
|
least 2D) vector of shape ``(n_sections, ..., 2, ...)``, where
|
|
``..., 2, ...`` denotes the shape of `x`, but with ``x.shape[axis]``
|
|
replaced by 2. If `zi` is None or is not given then initial rest
|
|
(i.e. all zeros) is assumed.
|
|
Note that these initial conditions are *not* the same as the initial
|
|
conditions given by `lfiltic` or `lfilter_zi`.
|
|
|
|
Returns
|
|
-------
|
|
y : ndarray
|
|
The output of the digital filter.
|
|
zf : ndarray, optional
|
|
If `zi` is None, this is not returned, otherwise, `zf` holds the
|
|
final filter delay values.
|
|
|
|
See Also
|
|
--------
|
|
zpk2sos, sos2zpk, sosfilt_zi, sosfiltfilt, sosfreqz
|
|
|
|
Notes
|
|
-----
|
|
The filter function is implemented as a series of second-order filters
|
|
with direct-form II transposed structure. It is designed to minimize
|
|
numerical precision errors for high-order filters.
|
|
|
|
.. versionadded:: 0.16.0
|
|
|
|
Examples
|
|
--------
|
|
Plot a 13th-order filter's impulse response using both `lfilter` and
|
|
`sosfilt`, showing the instability that results from trying to do a
|
|
13th-order filter in a single stage (the numerical error pushes some poles
|
|
outside of the unit circle):
|
|
|
|
>>> import matplotlib.pyplot as plt
|
|
>>> from scipy import signal
|
|
>>> b, a = signal.ellip(13, 0.009, 80, 0.05, output='ba')
|
|
>>> sos = signal.ellip(13, 0.009, 80, 0.05, output='sos')
|
|
>>> x = signal.unit_impulse(700)
|
|
>>> y_tf = signal.lfilter(b, a, x)
|
|
>>> y_sos = signal.sosfilt(sos, x)
|
|
>>> plt.plot(y_tf, 'r', label='TF')
|
|
>>> plt.plot(y_sos, 'k', label='SOS')
|
|
>>> plt.legend(loc='best')
|
|
>>> plt.show()
|
|
|
|
"""
|
|
x = _validate_x(x)
|
|
sos, n_sections = _validate_sos(sos)
|
|
x_zi_shape = list(x.shape)
|
|
x_zi_shape[axis] = 2
|
|
x_zi_shape = tuple([n_sections] + x_zi_shape)
|
|
inputs = [sos, x]
|
|
if zi is not None:
|
|
inputs.append(np.asarray(zi))
|
|
dtype = np.result_type(*inputs)
|
|
if dtype.char not in 'fdgFDGO':
|
|
raise NotImplementedError("input type '%s' not supported" % dtype)
|
|
if zi is not None:
|
|
zi = np.array(zi, dtype) # make a copy so that we can operate in place
|
|
if zi.shape != x_zi_shape:
|
|
raise ValueError('Invalid zi shape. With axis=%r, an input with '
|
|
'shape %r, and an sos array with %d sections, zi '
|
|
'must have shape %r, got %r.' %
|
|
(axis, x.shape, n_sections, x_zi_shape, zi.shape))
|
|
return_zi = True
|
|
else:
|
|
zi = np.zeros(x_zi_shape, dtype=dtype)
|
|
return_zi = False
|
|
axis = axis % x.ndim # make positive
|
|
x = np.moveaxis(x, axis, -1)
|
|
zi = np.moveaxis(zi, [0, axis + 1], [-2, -1])
|
|
x_shape, zi_shape = x.shape, zi.shape
|
|
x = np.reshape(x, (-1, x.shape[-1]))
|
|
x = np.array(x, dtype, order='C') # make a copy, can modify in place
|
|
zi = np.ascontiguousarray(np.reshape(zi, (-1, n_sections, 2)))
|
|
sos = sos.astype(dtype, copy=False)
|
|
_sosfilt(sos, x, zi)
|
|
x.shape = x_shape
|
|
x = np.moveaxis(x, -1, axis)
|
|
if return_zi:
|
|
zi.shape = zi_shape
|
|
zi = np.moveaxis(zi, [-2, -1], [0, axis + 1])
|
|
out = (x, zi)
|
|
else:
|
|
out = x
|
|
return out
|
|
|
|
|
|
def sosfiltfilt(sos, x, axis=-1, padtype='odd', padlen=None):
|
|
"""
|
|
A forward-backward digital filter using cascaded second-order sections.
|
|
|
|
See `filtfilt` for more complete information about this method.
|
|
|
|
Parameters
|
|
----------
|
|
sos : array_like
|
|
Array of second-order filter coefficients, must have shape
|
|
``(n_sections, 6)``. Each row corresponds to a second-order
|
|
section, with the first three columns providing the numerator
|
|
coefficients and the last three providing the denominator
|
|
coefficients.
|
|
x : array_like
|
|
The array of data to be filtered.
|
|
axis : int, optional
|
|
The axis of `x` to which the filter is applied.
|
|
Default is -1.
|
|
padtype : str or None, optional
|
|
Must be 'odd', 'even', 'constant', or None. This determines the
|
|
type of extension to use for the padded signal to which the filter
|
|
is applied. If `padtype` is None, no padding is used. The default
|
|
is 'odd'.
|
|
padlen : int or None, optional
|
|
The number of elements by which to extend `x` at both ends of
|
|
`axis` before applying the filter. This value must be less than
|
|
``x.shape[axis] - 1``. ``padlen=0`` implies no padding.
|
|
The default value is::
|
|
|
|
3 * (2 * len(sos) + 1 - min((sos[:, 2] == 0).sum(),
|
|
(sos[:, 5] == 0).sum()))
|
|
|
|
The extra subtraction at the end attempts to compensate for poles
|
|
and zeros at the origin (e.g. for odd-order filters) to yield
|
|
equivalent estimates of `padlen` to those of `filtfilt` for
|
|
second-order section filters built with `scipy.signal` functions.
|
|
|
|
Returns
|
|
-------
|
|
y : ndarray
|
|
The filtered output with the same shape as `x`.
|
|
|
|
See Also
|
|
--------
|
|
filtfilt, sosfilt, sosfilt_zi, sosfreqz
|
|
|
|
Notes
|
|
-----
|
|
.. versionadded:: 0.18.0
|
|
|
|
Examples
|
|
--------
|
|
>>> from scipy.signal import sosfiltfilt, butter
|
|
>>> import matplotlib.pyplot as plt
|
|
|
|
Create an interesting signal to filter.
|
|
|
|
>>> n = 201
|
|
>>> t = np.linspace(0, 1, n)
|
|
>>> np.random.seed(123)
|
|
>>> x = 1 + (t < 0.5) - 0.25*t**2 + 0.05*np.random.randn(n)
|
|
|
|
Create a lowpass Butterworth filter, and use it to filter `x`.
|
|
|
|
>>> sos = butter(4, 0.125, output='sos')
|
|
>>> y = sosfiltfilt(sos, x)
|
|
|
|
For comparison, apply an 8th order filter using `sosfilt`. The filter
|
|
is initialized using the mean of the first four values of `x`.
|
|
|
|
>>> from scipy.signal import sosfilt, sosfilt_zi
|
|
>>> sos8 = butter(8, 0.125, output='sos')
|
|
>>> zi = x[:4].mean() * sosfilt_zi(sos8)
|
|
>>> y2, zo = sosfilt(sos8, x, zi=zi)
|
|
|
|
Plot the results. Note that the phase of `y` matches the input, while
|
|
`y2` has a significant phase delay.
|
|
|
|
>>> plt.plot(t, x, alpha=0.5, label='x(t)')
|
|
>>> plt.plot(t, y, label='y(t)')
|
|
>>> plt.plot(t, y2, label='y2(t)')
|
|
>>> plt.legend(framealpha=1, shadow=True)
|
|
>>> plt.grid(alpha=0.25)
|
|
>>> plt.xlabel('t')
|
|
>>> plt.show()
|
|
|
|
"""
|
|
sos, n_sections = _validate_sos(sos)
|
|
x = _validate_x(x)
|
|
|
|
# `method` is "pad"...
|
|
ntaps = 2 * n_sections + 1
|
|
ntaps -= min((sos[:, 2] == 0).sum(), (sos[:, 5] == 0).sum())
|
|
edge, ext = _validate_pad(padtype, padlen, x, axis,
|
|
ntaps=ntaps)
|
|
|
|
# These steps follow the same form as filtfilt with modifications
|
|
zi = sosfilt_zi(sos) # shape (n_sections, 2) --> (n_sections, ..., 2, ...)
|
|
zi_shape = [1] * x.ndim
|
|
zi_shape[axis] = 2
|
|
zi.shape = [n_sections] + zi_shape
|
|
x_0 = axis_slice(ext, stop=1, axis=axis)
|
|
(y, zf) = sosfilt(sos, ext, axis=axis, zi=zi * x_0)
|
|
y_0 = axis_slice(y, start=-1, axis=axis)
|
|
(y, zf) = sosfilt(sos, axis_reverse(y, axis=axis), axis=axis, zi=zi * y_0)
|
|
y = axis_reverse(y, axis=axis)
|
|
if edge > 0:
|
|
y = axis_slice(y, start=edge, stop=-edge, axis=axis)
|
|
return y
|
|
|
|
|
|
def decimate(x, q, n=None, ftype='iir', axis=-1, zero_phase=True):
|
|
"""
|
|
Downsample the signal after applying an anti-aliasing filter.
|
|
|
|
By default, an order 8 Chebyshev type I filter is used. A 30 point FIR
|
|
filter with Hamming window is used if `ftype` is 'fir'.
|
|
|
|
Parameters
|
|
----------
|
|
x : array_like
|
|
The signal to be downsampled, as an N-dimensional array.
|
|
q : int
|
|
The downsampling factor. When using IIR downsampling, it is recommended
|
|
to call `decimate` multiple times for downsampling factors higher than
|
|
13.
|
|
n : int, optional
|
|
The order of the filter (1 less than the length for 'fir'). Defaults to
|
|
8 for 'iir' and 20 times the downsampling factor for 'fir'.
|
|
ftype : str {'iir', 'fir'} or ``dlti`` instance, optional
|
|
If 'iir' or 'fir', specifies the type of lowpass filter. If an instance
|
|
of an `dlti` object, uses that object to filter before downsampling.
|
|
axis : int, optional
|
|
The axis along which to decimate.
|
|
zero_phase : bool, optional
|
|
Prevent phase shift by filtering with `filtfilt` instead of `lfilter`
|
|
when using an IIR filter, and shifting the outputs back by the filter's
|
|
group delay when using an FIR filter. The default value of ``True`` is
|
|
recommended, since a phase shift is generally not desired.
|
|
|
|
.. versionadded:: 0.18.0
|
|
|
|
Returns
|
|
-------
|
|
y : ndarray
|
|
The down-sampled signal.
|
|
|
|
See Also
|
|
--------
|
|
resample : Resample up or down using the FFT method.
|
|
resample_poly : Resample using polyphase filtering and an FIR filter.
|
|
|
|
Notes
|
|
-----
|
|
The ``zero_phase`` keyword was added in 0.18.0.
|
|
The possibility to use instances of ``dlti`` as ``ftype`` was added in
|
|
0.18.0.
|
|
"""
|
|
|
|
x = np.asarray(x)
|
|
q = operator.index(q)
|
|
|
|
if n is not None:
|
|
n = operator.index(n)
|
|
|
|
if ftype == 'fir':
|
|
if n is None:
|
|
half_len = 10 * q # reasonable cutoff for our sinc-like function
|
|
n = 2 * half_len
|
|
b, a = firwin(n+1, 1. / q, window='hamming'), 1.
|
|
elif ftype == 'iir':
|
|
if n is None:
|
|
n = 8
|
|
system = dlti(*cheby1(n, 0.05, 0.8 / q))
|
|
b, a = system.num, system.den
|
|
elif isinstance(ftype, dlti):
|
|
system = ftype._as_tf() # Avoids copying if already in TF form
|
|
b, a = system.num, system.den
|
|
else:
|
|
raise ValueError('invalid ftype')
|
|
|
|
result_type = x.dtype
|
|
if result_type.kind in 'bui':
|
|
result_type = np.float64
|
|
b = np.asarray(b, dtype=result_type)
|
|
a = np.asarray(a, dtype=result_type)
|
|
|
|
sl = [slice(None)] * x.ndim
|
|
a = np.asarray(a)
|
|
|
|
if a.size == 1: # FIR case
|
|
b = b / a
|
|
if zero_phase:
|
|
y = resample_poly(x, 1, q, axis=axis, window=b)
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|
else:
|
|
# upfirdn is generally faster than lfilter by a factor equal to the
|
|
# downsampling factor, since it only calculates the needed outputs
|
|
n_out = x.shape[axis] // q + bool(x.shape[axis] % q)
|
|
y = upfirdn(b, x, up=1, down=q, axis=axis)
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|
sl[axis] = slice(None, n_out, None)
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|
|
|
else: # IIR case
|
|
if zero_phase:
|
|
y = filtfilt(b, a, x, axis=axis)
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|
else:
|
|
y = lfilter(b, a, x, axis=axis)
|
|
sl[axis] = slice(None, None, q)
|
|
|
|
return y[tuple(sl)]
|