"""Tools for spectral analysis. """ from __future__ import division, print_function, absolute_import import numpy as np from scipy import fftpack from . import signaltools from .windows import get_window from ._spectral import lombscargle import warnings from scipy._lib.six import string_types __all__ = ['periodogram', 'welch', 'lombscargle', 'csd', 'coherence', 'spectrogram'] def periodogram(x, fs=1.0, window=None, nfft=None, detrend='constant', return_onesided=True, scaling='density', axis=-1): """ Estimate power spectral density using a periodogram. Parameters ---------- x : array_like Time series of measurement values fs : float, optional Sampling frequency of the `x` time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is an array it will be used directly as the window. Defaults to None; equivalent to 'boxcar'. nfft : int, optional Length of the FFT used. If None the length of `x` will be used. detrend : str or function or False, optional Specifies how to detrend `x` prior to computing the spectrum. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it should return a detrended array. If `detrend` is False, no detrending is done. Defaults to 'constant'. return_onesided : bool, optional If True, return a one-sided spectrum for real data. If False return a two-sided spectrum. Note that for complex data, a two-sided spectrum is always returned. scaling : { 'density', 'spectrum' }, optional Selects between computing the power spectral density ('density') where `Pxx` has units of V**2/Hz and computing the power spectrum ('spectrum') where `Pxx` has units of V**2, if `x` is measured in V and fs is measured in Hz. Defaults to 'density' axis : int, optional Axis along which the periodogram is computed; the default is over the last axis (i.e. ``axis=-1``). Returns ------- f : ndarray Array of sample frequencies. Pxx : ndarray Power spectral density or power spectrum of `x`. Notes ----- .. versionadded:: 0.12.0 See Also -------- welch: Estimate power spectral density using Welch's method lombscargle: Lomb-Scargle periodogram for unevenly sampled data Examples -------- >>> from scipy import signal >>> import matplotlib.pyplot as plt >>> np.random.seed(1234) Generate a test signal, a 2 Vrms sine wave at 1234 Hz, corrupted by 0.001 V**2/Hz of white noise sampled at 10 kHz. >>> fs = 10e3 >>> N = 1e5 >>> amp = 2*np.sqrt(2) >>> freq = 1234.0 >>> noise_power = 0.001 * fs / 2 >>> time = np.arange(N) / fs >>> x = amp*np.sin(2*np.pi*freq*time) >>> x += np.random.normal(scale=np.sqrt(noise_power), size=time.shape) Compute and plot the power spectral density. >>> f, Pxx_den = signal.periodogram(x, fs) >>> plt.semilogy(f, Pxx_den) >>> plt.ylim([1e-7, 1e2]) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('PSD [V**2/Hz]') >>> plt.show() If we average the last half of the spectral density, to exclude the peak, we can recover the noise power on the signal. >>> np.mean(Pxx_den[256:]) 0.0018156616014838548 Now compute and plot the power spectrum. >>> f, Pxx_spec = signal.periodogram(x, fs, 'flattop', scaling='spectrum') >>> plt.figure() >>> plt.semilogy(f, np.sqrt(Pxx_spec)) >>> plt.ylim([1e-4, 1e1]) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('Linear spectrum [V RMS]') >>> plt.show() The peak height in the power spectrum is an estimate of the RMS amplitude. >>> np.sqrt(Pxx_spec.max()) 2.0077340678640727 """ x = np.asarray(x) if x.size == 0: return np.empty(x.shape), np.empty(x.shape) if window is None: window = 'boxcar' if nfft is None: nperseg = x.shape[axis] elif nfft == x.shape[axis]: nperseg = nfft elif nfft > x.shape[axis]: nperseg = x.shape[axis] elif nfft < x.shape[axis]: s = [np.s_[:]]*len(x.shape) s[axis] = np.s_[:nfft] x = x[s] nperseg = nfft nfft = None return welch(x, fs, window, nperseg, 0, nfft, detrend, return_onesided, scaling, axis) def welch(x, fs=1.0, window='hann', nperseg=256, noverlap=None, nfft=None, detrend='constant', return_onesided=True, scaling='density', axis=-1): """ Estimate power spectral density using Welch's method. Welch's method [1]_ computes an estimate of the power spectral density by dividing the data into overlapping segments, computing a modified periodogram for each segment and averaging the periodograms. Parameters ---------- x : array_like Time series of measurement values fs : float, optional Sampling frequency of the `x` time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is array_like it will be used directly as the window and its length will be used for nperseg. Defaults to 'hann'. nperseg : int, optional Length of each segment. Defaults to 256. noverlap : int, optional Number of points to overlap between segments. If None, ``noverlap = nperseg // 2``. Defaults to None. nfft : int, optional Length of the FFT used, if a zero padded FFT is desired. If None, the FFT length is `nperseg`. Defaults to None. detrend : str or function or False, optional Specifies how to detrend each segment. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it takes a segment and returns a detrended segment. If `detrend` is False, no detrending is done. Defaults to 'constant'. return_onesided : bool, optional If True, return a one-sided spectrum for real data. If False return a two-sided spectrum. Note that for complex data, a two-sided spectrum is always returned. scaling : { 'density', 'spectrum' }, optional Selects between computing the power spectral density ('density') where `Pxx` has units of V**2/Hz and computing the power spectrum ('spectrum') where `Pxx` has units of V**2, if `x` is measured in V and fs is measured in Hz. Defaults to 'density' axis : int, optional Axis along which the periodogram is computed; the default is over the last axis (i.e. ``axis=-1``). Returns ------- f : ndarray Array of sample frequencies. Pxx : ndarray Power spectral density or power spectrum of x. See Also -------- periodogram: Simple, optionally modified periodogram lombscargle: Lomb-Scargle periodogram for unevenly sampled data Notes ----- An appropriate amount of overlap will depend on the choice of window and on your requirements. For the default 'hann' window an overlap of 50% is a reasonable trade off between accurately estimating the signal power, while not over counting any of the data. Narrower windows may require a larger overlap. If `noverlap` is 0, this method is equivalent to Bartlett's method [2]_. .. versionadded:: 0.12.0 References ---------- .. [1] P. Welch, "The use of the fast Fourier transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms", IEEE Trans. Audio Electroacoust. vol. 15, pp. 70-73, 1967. .. [2] M.S. Bartlett, "Periodogram Analysis and Continuous Spectra", Biometrika, vol. 37, pp. 1-16, 1950. Examples -------- >>> from scipy import signal >>> import matplotlib.pyplot as plt >>> np.random.seed(1234) Generate a test signal, a 2 Vrms sine wave at 1234 Hz, corrupted by 0.001 V**2/Hz of white noise sampled at 10 kHz. >>> fs = 10e3 >>> N = 1e5 >>> amp = 2*np.sqrt(2) >>> freq = 1234.0 >>> noise_power = 0.001 * fs / 2 >>> time = np.arange(N) / fs >>> x = amp*np.sin(2*np.pi*freq*time) >>> x += np.random.normal(scale=np.sqrt(noise_power), size=time.shape) Compute and plot the power spectral density. >>> f, Pxx_den = signal.welch(x, fs, nperseg=1024) >>> plt.semilogy(f, Pxx_den) >>> plt.ylim([0.5e-3, 1]) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('PSD [V**2/Hz]') >>> plt.show() If we average the last half of the spectral density, to exclude the peak, we can recover the noise power on the signal. >>> np.mean(Pxx_den[256:]) 0.0009924865443739191 Now compute and plot the power spectrum. >>> f, Pxx_spec = signal.welch(x, fs, 'flattop', 1024, scaling='spectrum') >>> plt.figure() >>> plt.semilogy(f, np.sqrt(Pxx_spec)) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('Linear spectrum [V RMS]') >>> plt.show() The peak height in the power spectrum is an estimate of the RMS amplitude. >>> np.sqrt(Pxx_spec.max()) 2.0077340678640727 """ freqs, Pxx = csd(x, x, fs, window, nperseg, noverlap, nfft, detrend, return_onesided, scaling, axis) return freqs, Pxx.real def csd(x, y, fs=1.0, window='hann', nperseg=256, noverlap=None, nfft=None, detrend='constant', return_onesided=True, scaling='density', axis=-1): """ Estimate the cross power spectral density, Pxy, using Welch's method. Parameters ---------- x : array_like Time series of measurement values y : array_like Time series of measurement values fs : float, optional Sampling frequency of the `x` and `y` time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is array_like it will be used directly as the window and its length will be used for nperseg. Defaults to 'hann'. nperseg : int, optional Length of each segment. Defaults to 256. noverlap: int, optional Number of points to overlap between segments. If None, ``noverlap = nperseg // 2``. Defaults to None. nfft : int, optional Length of the FFT used, if a zero padded FFT is desired. If None, the FFT length is `nperseg`. Defaults to None. detrend : str or function or False, optional Specifies how to detrend each segment. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it takes a segment and returns a detrended segment. If `detrend` is False, no detrending is done. Defaults to 'constant'. return_onesided : bool, optional If True, return a one-sided spectrum for real data. If False return a two-sided spectrum. Note that for complex data, a two-sided spectrum is always returned. scaling : { 'density', 'spectrum' }, optional Selects between computing the cross spectral density ('density') where `Pxy` has units of V**2/Hz and computing the cross spectrum ('spectrum') where `Pxy` has units of V**2, if `x` and `y` are measured in V and fs is measured in Hz. Defaults to 'density' axis : int, optional Axis along which the CSD is computed for both inputs; the default is over the last axis (i.e. ``axis=-1``). Returns ------- f : ndarray Array of sample frequencies. Pxy : ndarray Cross spectral density or cross power spectrum of x,y. See Also -------- periodogram: Simple, optionally modified periodogram lombscargle: Lomb-Scargle periodogram for unevenly sampled data welch: Power spectral density by Welch's method. [Equivalent to csd(x,x)] coherence: Magnitude squared coherence by Welch's method. Notes -------- By convention, Pxy is computed with the conjugate FFT of X multiplied by the FFT of Y. If the input series differ in length, the shorter series will be zero-padded to match. An appropriate amount of overlap will depend on the choice of window and on your requirements. For the default 'hann' window an overlap of 50\% is a reasonable trade off between accurately estimating the signal power, while not over counting any of the data. Narrower windows may require a larger overlap. .. versionadded:: 0.16.0 References ---------- .. [1] P. Welch, "The use of the fast Fourier transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms", IEEE Trans. Audio Electroacoust. vol. 15, pp. 70-73, 1967. .. [2] Rabiner, Lawrence R., and B. Gold. "Theory and Application of Digital Signal Processing" Prentice-Hall, pp. 414-419, 1975 Examples -------- >>> from scipy import signal >>> import matplotlib.pyplot as plt Generate two test signals with some common features. >>> fs = 10e3 >>> N = 1e5 >>> amp = 20 >>> freq = 1234.0 >>> noise_power = 0.001 * fs / 2 >>> time = np.arange(N) / fs >>> b, a = signal.butter(2, 0.25, 'low') >>> x = np.random.normal(scale=np.sqrt(noise_power), size=time.shape) >>> y = signal.lfilter(b, a, x) >>> x += amp*np.sin(2*np.pi*freq*time) >>> y += np.random.normal(scale=0.1*np.sqrt(noise_power), size=time.shape) Compute and plot the magnitude of the cross spectral density. >>> f, Pxy = signal.csd(x, y, fs, nperseg=1024) >>> plt.semilogy(f, np.abs(Pxy)) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('CSD [V**2/Hz]') >>> plt.show() """ freqs, _, Pxy = _spectral_helper(x, y, fs, window, nperseg, noverlap, nfft, detrend, return_onesided, scaling, axis, mode='psd') # Average over windows. if len(Pxy.shape) >= 2 and Pxy.size > 0: if Pxy.shape[-1] > 1: Pxy = Pxy.mean(axis=-1) else: Pxy = np.reshape(Pxy, Pxy.shape[:-1]) return freqs, Pxy def spectrogram(x, fs=1.0, window=('tukey',.25), nperseg=256, noverlap=None, nfft=None, detrend='constant', return_onesided=True, scaling='density', axis=-1, mode='psd'): """ Compute a spectrogram with consecutive Fourier transforms. Spectrograms can be used as a way of visualizing the change of a nonstationary signal's frequency content over time. Parameters ---------- x : array_like Time series of measurement values fs : float, optional Sampling frequency of the `x` time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is array_like it will be used directly as the window and its length will be used for nperseg. Defaults to a Tukey window with shape parameter of 0.25. nperseg : int, optional Length of each segment. Defaults to 256. noverlap : int, optional Number of points to overlap between segments. If None, ``noverlap = nperseg // 8``. Defaults to None. nfft : int, optional Length of the FFT used, if a zero padded FFT is desired. If None, the FFT length is `nperseg`. Defaults to None. detrend : str or function or False, optional Specifies how to detrend each segment. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it takes a segment and returns a detrended segment. If `detrend` is False, no detrending is done. Defaults to 'constant'. return_onesided : bool, optional If True, return a one-sided spectrum for real data. If False return a two-sided spectrum. Note that for complex data, a two-sided spectrum is always returned. scaling : { 'density', 'spectrum' }, optional Selects between computing the power spectral density ('density') where `Pxx` has units of V**2/Hz and computing the power spectrum ('spectrum') where `Pxx` has units of V**2, if `x` is measured in V and fs is measured in Hz. Defaults to 'density' axis : int, optional Axis along which the spectrogram is computed; the default is over the last axis (i.e. ``axis=-1``). mode : str, optional Defines what kind of return values are expected. Options are ['psd', 'complex', 'magnitude', 'angle', 'phase']. Returns ------- f : ndarray Array of sample frequencies. t : ndarray Array of segment times. Sxx : ndarray Spectrogram of x. By default, the last axis of Sxx corresponds to the segment times. See Also -------- periodogram: Simple, optionally modified periodogram lombscargle: Lomb-Scargle periodogram for unevenly sampled data welch: Power spectral density by Welch's method. csd: Cross spectral density by Welch's method. Notes ----- An appropriate amount of overlap will depend on the choice of window and on your requirements. In contrast to welch's method, where the entire data stream is averaged over, one may wish to use a smaller overlap (or perhaps none at all) when computing a spectrogram, to maintain some statistical independence between individual segments. .. versionadded:: 0.16.0 References ---------- .. [1] Oppenheim, Alan V., Ronald W. Schafer, John R. Buck "Discrete-Time Signal Processing", Prentice Hall, 1999. Examples -------- >>> from scipy import signal >>> import matplotlib.pyplot as plt Generate a test signal, a 2 Vrms sine wave whose frequency linearly changes with time from 1kHz to 2kHz, corrupted by 0.001 V**2/Hz of white noise sampled at 10 kHz. >>> fs = 10e3 >>> N = 1e5 >>> amp = 2 * np.sqrt(2) >>> noise_power = 0.001 * fs / 2 >>> time = np.arange(N) / fs >>> freq = np.linspace(1e3, 2e3, N) >>> x = amp * np.sin(2*np.pi*freq*time) >>> x += np.random.normal(scale=np.sqrt(noise_power), size=time.shape) Compute and plot the spectrogram. >>> f, t, Sxx = signal.spectrogram(x, fs) >>> plt.pcolormesh(t, f, Sxx) >>> plt.ylabel('Frequency [Hz]') >>> plt.xlabel('Time [sec]') >>> plt.show() """ # Less overlap than welch, so samples are more statisically independent if noverlap is None: noverlap = nperseg // 8 freqs, time, Pxy = _spectral_helper(x, x, fs, window, nperseg, noverlap, nfft, detrend, return_onesided, scaling, axis, mode=mode) return freqs, time, Pxy def coherence(x, y, fs=1.0, window='hann', nperseg=256, noverlap=None, nfft=None, detrend='constant', axis=-1): """ Estimate the magnitude squared coherence estimate, Cxy, of discrete-time signals X and Y using Welch's method. Cxy = abs(Pxy)**2/(Pxx*Pyy), where Pxx and Pyy are power spectral density estimates of X and Y, and Pxy is the cross spectral density estimate of X and Y. Parameters ---------- x : array_like Time series of measurement values y : array_like Time series of measurement values fs : float, optional Sampling frequency of the `x` and `y` time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is array_like it will be used directly as the window and its length will be used for nperseg. Defaults to 'hann'. nperseg : int, optional Length of each segment. Defaults to 256. noverlap: int, optional Number of points to overlap between segments. If None, ``noverlap = nperseg // 2``. Defaults to None. nfft : int, optional Length of the FFT used, if a zero padded FFT is desired. If None, the FFT length is `nperseg`. Defaults to None. detrend : str or function or False, optional Specifies how to detrend each segment. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it takes a segment and returns a detrended segment. If `detrend` is False, no detrending is done. Defaults to 'constant'. axis : int, optional Axis along which the coherence is computed for both inputs; the default is over the last axis (i.e. ``axis=-1``). Returns ------- f : ndarray Array of sample frequencies. Cxy : ndarray Magnitude squared coherence of x and y. See Also -------- periodogram: Simple, optionally modified periodogram lombscargle: Lomb-Scargle periodogram for unevenly sampled data welch: Power spectral density by Welch's method. csd: Cross spectral density by Welch's method. Notes -------- An appropriate amount of overlap will depend on the choice of window and on your requirements. For the default 'hann' window an overlap of 50\% is a reasonable trade off between accurately estimating the signal power, while not over counting any of the data. Narrower windows may require a larger overlap. .. versionadded:: 0.16.0 References ---------- .. [1] P. Welch, "The use of the fast Fourier transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms", IEEE Trans. Audio Electroacoust. vol. 15, pp. 70-73, 1967. .. [2] Stoica, Petre, and Randolph Moses, "Spectral Analysis of Signals" Prentice Hall, 2005 Examples -------- >>> from scipy import signal >>> import matplotlib.pyplot as plt Generate two test signals with some common features. >>> fs = 10e3 >>> N = 1e5 >>> amp = 20 >>> freq = 1234.0 >>> noise_power = 0.001 * fs / 2 >>> time = np.arange(N) / fs >>> b, a = signal.butter(2, 0.25, 'low') >>> x = np.random.normal(scale=np.sqrt(noise_power), size=time.shape) >>> y = signal.lfilter(b, a, x) >>> x += amp*np.sin(2*np.pi*freq*time) >>> y += np.random.normal(scale=0.1*np.sqrt(noise_power), size=time.shape) Compute and plot the coherence. >>> f, Cxy = signal.coherence(x, y, fs, nperseg=1024) >>> plt.semilogy(f, Cxy) >>> plt.xlabel('frequency [Hz]') >>> plt.ylabel('Coherence') >>> plt.show() """ freqs, Pxx = welch(x, fs, window, nperseg, noverlap, nfft, detrend, axis=axis) _, Pyy = welch(y, fs, window, nperseg, noverlap, nfft, detrend, axis=axis) _, Pxy = csd(x, y, fs, window, nperseg, noverlap, nfft, detrend, axis=axis) Cxy = np.abs(Pxy)**2 / Pxx / Pyy return freqs, Cxy def _spectral_helper(x, y, fs=1.0, window='hann', nperseg=256, noverlap=None, nfft=None, detrend='constant', return_onesided=True, scaling='spectrum', axis=-1, mode='psd'): """ Calculate various forms of windowed FFTs for PSD, CSD, etc. This is a helper function that implements the commonality between the psd, csd, and spectrogram functions. It is not designed to be called externally. The windows are not averaged over; the result from each window is returned. Parameters --------- x : array_like Array or sequence containing the data to be analyzed. y : array_like Array or sequence containing the data to be analyzed. If this is the same object in memoery as x (i.e. _spectral_helper(x, x, ...)), the extra computations are spared. fs : float, optional Sampling frequency of the time series. Defaults to 1.0. window : str or tuple or array_like, optional Desired window to use. See `get_window` for a list of windows and required parameters. If `window` is array_like it will be used directly as the window and its length will be used for nperseg. Defaults to 'hann'. nperseg : int, optional Length of each segment. Defaults to 256. noverlap : int, optional Number of points to overlap between segments. If None, ``noverlap = nperseg // 2``. Defaults to None. nfft : int, optional Length of the FFT used, if a zero padded FFT is desired. If None, the FFT length is `nperseg`. Defaults to None. detrend : str or function or False, optional Specifies how to detrend each segment. If `detrend` is a string, it is passed as the ``type`` argument to `detrend`. If it is a function, it takes a segment and returns a detrended segment. If `detrend` is False, no detrending is done. Defaults to 'constant'. return_onesided : bool, optional If True, return a one-sided spectrum for real data. If False return a two-sided spectrum. Note that for complex data, a two-sided spectrum is always returned. scaling : { 'density', 'spectrum' }, optional Selects between computing the cross spectral density ('density') where `Pxy` has units of V**2/Hz and computing the cross spectrum ('spectrum') where `Pxy` has units of V**2, if `x` and `y` are measured in V and fs is measured in Hz. Defaults to 'density' axis : int, optional Axis along which the periodogram is computed; the default is over the last axis (i.e. ``axis=-1``). mode : str, optional Defines what kind of return values are expected. Options are ['psd', 'complex', 'magnitude', 'angle', 'phase']. Returns ------- freqs : ndarray Array of sample frequencies. t : ndarray Array of times corresponding to each data segment result : ndarray Array of output data, contents dependant on *mode* kwarg. References ---------- .. [1] Stack Overflow, "Rolling window for 1D arrays in Numpy?", http://stackoverflow.com/a/6811241 .. [2] Stack Overflow, "Using strides for an efficient moving average filter", http://stackoverflow.com/a/4947453 Notes ----- Adapted from matplotlib.mlab .. versionadded:: 0.16.0 """ if mode not in ['psd', 'complex', 'magnitude', 'angle', 'phase']: raise ValueError("Unknown value for mode %s, must be one of: " "'default', 'psd', 'complex', " "'magnitude', 'angle', 'phase'" % mode) # If x and y are the same object we can save ourselves some computation. same_data = y is x if not same_data and mode != 'psd': raise ValueError("x and y must be equal if mode is not 'psd'") axis = int(axis) # Ensure we have np.arrays, get outdtype x = np.asarray(x) if not same_data: y = np.asarray(y) outdtype = np.result_type(x,y,np.complex64) else: outdtype = np.result_type(x,np.complex64) if not same_data: # Check if we can broadcast the outer axes together xouter = list(x.shape) youter = list(y.shape) xouter.pop(axis) youter.pop(axis) try: outershape = np.broadcast(np.empty(xouter), np.empty(youter)).shape except ValueError: raise ValueError('x and y cannot be broadcast together.') if same_data: if x.size == 0: return np.empty(x.shape), np.empty(x.shape), np.empty(x.shape) else: if x.size == 0 or y.size == 0: outshape = outershape + (min([x.shape[axis], y.shape[axis]]),) emptyout = np.rollaxis(np.empty(outshape), -1, axis) return emptyout, emptyout, emptyout if x.ndim > 1: if axis != -1: x = np.rollaxis(x, axis, len(x.shape)) if not same_data and y.ndim > 1: y = np.rollaxis(y, axis, len(y.shape)) # Check if x and y are the same length, zero-pad if neccesary if not same_data: if x.shape[-1] != y.shape[-1]: if x.shape[-1] < y.shape[-1]: pad_shape = list(x.shape) pad_shape[-1] = y.shape[-1] - x.shape[-1] x = np.concatenate((x, np.zeros(pad_shape)), -1) else: pad_shape = list(y.shape) pad_shape[-1] = x.shape[-1] - y.shape[-1] y = np.concatenate((y, np.zeros(pad_shape)), -1) # X and Y are same length now, can test nperseg with either if x.shape[-1] < nperseg: warnings.warn('nperseg = {0:d}, is greater than input length = {1:d}, ' 'using nperseg = {1:d}'.format(nperseg, x.shape[-1])) nperseg = x.shape[-1] nperseg = int(nperseg) if nperseg < 1: raise ValueError('nperseg must be a positive integer') if nfft is None: nfft = nperseg elif nfft < nperseg: raise ValueError('nfft must be greater than or equal to nperseg.') else: nfft = int(nfft) if noverlap is None: noverlap = nperseg//2 elif noverlap >= nperseg: raise ValueError('noverlap must be less than nperseg.') else: noverlap = int(noverlap) # Handle detrending and window functions if not detrend: def detrend_func(d): return d elif not hasattr(detrend, '__call__'): def detrend_func(d): return signaltools.detrend(d, type=detrend, axis=-1) elif axis != -1: # Wrap this function so that it receives a shape that it could # reasonably expect to receive. def detrend_func(d): d = np.rollaxis(d, -1, axis) d = detrend(d) return np.rollaxis(d, axis, len(d.shape)) else: detrend_func = detrend if isinstance(window, string_types) or type(window) is tuple: win = get_window(window, nperseg) else: win = np.asarray(window) if len(win.shape) != 1: raise ValueError('window must be 1-D') if win.shape[0] != nperseg: raise ValueError('window must have length of nperseg') if np.result_type(win,np.complex64) != outdtype: win = win.astype(outdtype) if mode == 'psd': if scaling == 'density': scale = 1.0 / (fs * (win*win).sum()) elif scaling == 'spectrum': scale = 1.0 / win.sum()**2 else: raise ValueError('Unknown scaling: %r' % scaling) else: scale = 1 if return_onesided is True: if np.iscomplexobj(x): sides = 'twosided' else: sides = 'onesided' if not same_data: if np.iscomplexobj(y): sides = 'twosided' else: sides = 'twosided' if sides == 'twosided': num_freqs = nfft elif sides == 'onesided': if nfft % 2: num_freqs = (nfft + 1)//2 else: num_freqs = nfft//2 + 1 # Perform the windowed FFTs result = _fft_helper(x, win, detrend_func, nperseg, noverlap, nfft) result = result[..., :num_freqs] freqs = fftpack.fftfreq(nfft, 1/fs)[:num_freqs] if not same_data: # All the same operations on the y data result_y = _fft_helper(y, win, detrend_func, nperseg, noverlap, nfft) result_y = result_y[..., :num_freqs] result = np.conjugate(result) * result_y elif mode == 'psd': result = np.conjugate(result) * result elif mode == 'magnitude': result = np.absolute(result) elif mode == 'angle' or mode == 'phase': result = np.angle(result) elif mode == 'complex': pass result *= scale if sides == 'onesided': if nfft % 2: result[...,1:] *= 2 else: # Last point is unpaired Nyquist freq point, don't double result[...,1:-1] *= 2 t = np.arange(nperseg/2, x.shape[-1] - nperseg/2 + 1, nperseg - noverlap)/float(fs) if sides != 'twosided' and not nfft % 2: # get the last value correctly, it is negative otherwise freqs[-1] *= -1 # we unwrap the phase here to handle the onesided vs. twosided case if mode == 'phase': result = np.unwrap(result, axis=-1) result = result.astype(outdtype) # All imaginary parts are zero anyways if same_data and mode != 'complex': result = result.real # Output is going to have new last axis for window index if axis != -1: # Specify as positive axis index if axis < 0: axis = len(result.shape)-1-axis # Roll frequency axis back to axis where the data came from result = np.rollaxis(result, -1, axis) else: # Make sure window/time index is last axis result = np.rollaxis(result, -1, -2) return freqs, t, result def _fft_helper(x, win, detrend_func, nperseg, noverlap, nfft): """ Calculate windowed FFT, for internal use by scipy.signal._spectral_helper This is a helper function that does the main FFT calculation for _spectral helper. All input valdiation is performed there, and the data axis is assumed to be the last axis of x. It is not designed to be called externally. The windows are not averaged over; the result from each window is returned. Returns ------- result : ndarray Array of FFT data References ---------- .. [1] Stack Overflow, "Repeat NumPy array without replicating data?", http://stackoverflow.com/a/5568169 Notes ----- Adapted from matplotlib.mlab .. versionadded:: 0.16.0 """ # Created strided array of data segments if nperseg == 1 and noverlap == 0: result = x[..., np.newaxis] else: step = nperseg - noverlap shape = x.shape[:-1]+((x.shape[-1]-noverlap)//step, nperseg) strides = x.strides[:-1]+(step*x.strides[-1], x.strides[-1]) result = np.lib.stride_tricks.as_strided(x, shape=shape, strides=strides) # Detrend each data segment individually result = detrend_func(result) # Apply window by multiplication result = win * result # Perform the fft. Acts on last axis by default. Zero-pads automatically result = fftpack.fft(result, n=nfft) return result