def remove_frequencies_and_save_to_csv(dtfrm, band_pass, high_pass, low_freq_limit, high_freq_limit, width, delta_t): [row, column] = dtfrm.shape frame = pd.DataFrame() i = 0 while i < column: y = dtfrm.iloc[:, i].tolist() wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( y, delta_t, J=width - 1, wavelet=u'mexicanhat') wave = select_frequencies(wave, width, band_pass, high_pass, delta_t, low_freq_limit, high_freq_limit) xrec = wavelet.icwt(wave, scales, delta_t, wavelet=u'mexicanhat') xrec = normalize(xrec) xrec = pd.Series(xrec) frame = pd.concat([frame, xrec], axis=1, ignore_index=True) i = i + 1 print("Select a folder") path = th.ui.getdir('Select a directory to save the csv file' ) # prompts user to select folder frame.to_csv(path + "/" + "new_dtfrm.csv")
def inverse_cwt(wl, scales=None): # wl: [10, T] mother = wavelet.MexicanHat() dt = 0.005 dj = 1 s0 = dt * 2 J = 9 C_delta = 3.541 if scales is None: scales = np.array([0.01, 0.02, 0.04, 0.08, 0.16, 0.32, 0.64, 1.28, 2.56, 5.12]) icwt_signal = wavelet.icwt(wl, scales, dt, dj, mother) / C_delta return icwt_signal
p = numpy.polyfit(t - t0, dat, 1) dat_notrend = dat - numpy.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset ## Define wavelet parameters mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt(dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std power = (numpy.abs(wave))**2 fft_power = numpy.abs(fft)**2 period = 1 / freqs power /= scales[:, None] signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None]
def wavelet_transform(dat, mother, s0, dj, J, dt, lims=[20, 120], t0=0): """ Plot the continous wavelet transform for a given signal. Make sure to detrend and normalize the data before calling this funcion. This is a function wrapper around the pycwt simple_sample example with some modifications. ---------- Args: dat (Mandatory [array like]): input signal data. mother (Mandatory [str]): the wavelet mother name. s0 (Mandatory [float]): starting scale. dj (Mandatory [float]): number of sub-octaves per octaves. j (Mandatory [float]): powers of two with dj sub-octaves. dt (Mandatory [float]): same frequency in the same unit as the input. lims (Mandatory [list]): Period interval to integrate the local power spectrum. label (Mandatory [str]): the plot y-label. title (Mandatory [str]): the plot title. ---------- Return: No """ # also create a time array in years. N = dat.size t = np.arange(0, N) * dt + t0 # write the following code to detrend and normalize the input data by its # standard deviation. Sometimes detrending is not necessary and simply # removing the mean value is good enough. However, if your dataset has a # well defined trend, such as the Mauna Loa CO\ :sub:`2` dataset available # in the above mentioned website, it is strongly advised to perform # detrending. Here, we fit a one-degree polynomial function and then # subtract it from the # original data. p = np.polyfit(t - t0, dat, 1) dat_notrend = dat - np.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise # the following routines perform the wavelet transform and inverse wavelet # transform using the parameters defined above. Since we have normalized # our input time-series, we multiply the inverse transform by the standard # deviation. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std # calculate the normalized wavelet and Fourier power spectra, as well as # the Fourier equivalent periods for each wavelet scale. power = (np.abs(wave))**2 fft_power = np.abs(fft)**2 period = 1 / freqs # inverse transform but only considering lims idx1 = np.argmin(np.abs(period - LIMS[0])) idx2 = np.argmin(np.abs(period - LIMS[1])) _wave = wave.copy() _wave[0:idx1, :] = 0 igwave = wavelet.icwt(_wave, scales, dt, dj, mother) * std # could stop at this point and plot our results. However we are also # interested in the power spectra significance test. The power is # significant where the ratio ``power / sig95 > 1``. signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = np.ones([1, N]) * signif[:, None] sig95 = power / sig95 # calculate the global wavelet spectrum and determine its # significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) return t, dt, power, period, coi, sig95, iwave, igwave
J = -1 # 7 / dj # Seven powers of two with dj sub-octaves # alpha = 0.0 # Lag-1 autocorrelation for white noise try: alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise except Warning: # When the dataset is too short, or there is a strong trend, ar1 raises a # warning. In this case, we assume a white noise background spectrum. alpha = 1.0 mother = wavelet.Morlet(6) # Morlet mother wavelet with m=6 # The following routines perform the wavelet transform and siginificance # analysis for the chosen data set. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt(dat, ds.dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, ds.dt, dj, mother) # Normalized wavelet and Fourier power spectra power = (numpy.abs(wave)) ** 2 fft_power = numpy.abs(fft) ** 2 period = 1 / freqs # Significance test. Where ratio power/sig95 > 1, power is significant. signif, fft_theor = wavelet.significance(1.0, ds.dt, scales, 0, alpha, significance_level=slevel, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 # Power rectification as of Liu et al. (2007). TODO: confirm if significance # test ratio should be calculated first.
def main(): # Then, we load the dataset and define some data related parameters. In this # case, the first 19 lines of the data file contain meta-data, that we ignore, # since we set them manually (*i.e.* title, units). url = 'http://paos.colorado.edu/research/wavelets/wave_idl/nino3sst.txt' dat = numpy.genfromtxt(url, skip_header=19) title = 'NINO3 Sea Surface Temperature' label = 'NINO3 SST' units = 'degC' t0 = 1871.0 dt = 0.25 # In years #%% # We also create a time array in years. N = dat.size t = numpy.arange(0, N) * dt + t0 #%% # We write the following code to detrend and normalize the input data by its # standard deviation. Sometimes detrending is not necessary and simply # removing the mean value is good enough. However, if your dataset has a well # defined trend, such as the Mauna Loa CO\ :sub:`2` dataset available in the # above mentioned website, it is strongly advised to perform detrending. # Here, we fit a one-degree polynomial function and then subtract it from the # original data. p = numpy.polyfit(t - t0, dat, 1) dat_notrend = dat - numpy.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std ** 2 # Variance dat_norm = dat_notrend / std # Normalized dataset #%% # The next step is to define some parameters of our wavelet analysis. We # select the mother wavelet, in this case the Morlet wavelet with # :math:`\omega_0=6`. mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise #%% # The following routines perform the wavelet transform and inverse wavelet # transform using the parameters defined above. Since we have normalized our # input time-series, we multiply the inverse transform by the standard # deviation. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt(dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std #%% # We calculate the normalized wavelet and Fourier power spectra, as well as # the Fourier equivalent periods for each wavelet scale. power = (numpy.abs(wave)) ** 2 fft_power = numpy.abs(fft) ** 2 period = 1 / freqs #%% # We could stop at this point and plot our results. However we are also # interested in the power spectra significance test. The power is significant # where the ratio ``power / sig95 > 1``. signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 #%% # Then, we calculate the global wavelet spectrum and determine its # significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) #%% # We also calculate the scale average between 2 years and 8 years, and its # significance level. sel = find((period >= 2) & (period < 8)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance(var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) #%% # Finally, we plot our results in four different subplots containing the # (i) original series anomaly and the inverse wavelet transform; (ii) the # wavelet power spectrum (iii) the global wavelet and Fourier spectra ; and # (iv) the range averaged wavelet spectrum. In all sub-plots the significance # levels are either included as dotted lines or as filled contour lines. # Prepare the figure pyplot.close('all') pyplot.ioff() figprops = dict(figsize=(11, 8), dpi=72) fig = pyplot.figure(**figprops) #%% # First sub-plot, the original time series anomaly and inverse wavelet # transform. ax = pyplot.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(t, iwave, '-', linewidth=1, color=[0.5, 0.5, 0.5]) ax.plot(t, dat, 'k', linewidth=1.5) ax.set_title('a) {}'.format(title)) ax.set_ylabel(r'{} [{}]'.format(label, units))
def takewav_makefig(dd,moornum): if moornum==8: dt=1 dat=pd.read_csv(dd,header=12,sep='\s*') date=unique([datetime.datetime(int(dat.ix[ii,0]), int(dat.ix[ii,1]), int(dat.ix[ii,2]), int(dat.ix[ii,3])) for ii in range(len(dat))]) utest=array(dat.ix[:,6]/100) vtest=array(dat.ix[:,7]/100) nomd=int(nanmean(array(dat.ix[:,5]))) dat=utest**2+vtest**2 savetit='M1-'+str(nomd)+'m' else: dataset=xr.open_dataset(dd) date=dataset['TIME'] ke=dataset['UCUR']**2+dataset['VCUR']**2 dat=ke.values.flatten() dt=0.5 nomd=int(dataset.geospatial_vertical_min) savetit=dataset.platform_code[-3:]+'-'+str(nomd)+'m' dat[isnan(dat)]=nanmean(dat) alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise N=len(dat) #in hours t = numpy.arange(0, N) * dt std=dat.std() var=std**2 dat_norm=dat/std # The following routines perform the wavelet transform and inverse wavelet transform using the parameters defined above. Since we have normalized our input time-series, we multiply the inverse transform by the standard deviation. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt(dat_norm,dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std # We calculate the normalized wavelet and Fourier power spectra, as well as the Fourier equivalent periods for each wavelet scale. power = (numpy.abs(wave)) ** 2 fft_power = numpy.abs(fft) ** 2 period = 1 / freqs # Optionally, we could also rectify the power spectrum according to the suggestions proposed by Liu et al. (2007)[2] power /= scales[:, None] # We could stop at this point and plot our results. However we are also interested in the power spectra significance test. The power is significant where the ratio power / sig95 > 1. signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 # Then, we calculate the global wavelet spectrum and determine its significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) # We also calculate the scale average between pmin and pmax, and its significance level. f,dx = pyplot.subplots(6,1,figsize=(12,12),sharex=True) bands=[1,2,8,16,48,128,512] for ii in range(len(bands)-1): pmin=bands[ii] pmax=bands[ii+1] sel = find((period >= pmin) & (period < pmax)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance(var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) dx[ii].axhline(scale_avg_signif, color='C'+str(ii), linestyle='--', linewidth=1.) dx[ii].plot(date, scale_avg, '-', color='C'+str(ii), linewidth=1.5,label='{}--{} hour band'.format(pmin,pmax)) [dx[ii].axvline(dd,color=clist[jj],linewidth=3) for jj,dd in enumerate(dlist)] dx[ii].legend() dx[0].set_title('Scale-averaged power: '+savetit) dx[3].set_ylabel(r'Average variance [{}]'.format(units)) if moornum ==8: dx[0].set_xlim(date[0],date[-1]) else: dx[0].set_xlim(date[0].values,date[-1].values) savefig(figdir+'ScaleSep_'+savetit+'.png',bbox_inches='tight') pmin=2 pmax=24 sel = find((period >= pmin) & (period < pmax)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance(var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) figprops = dict(figsize=(11, 8), dpi=72) fig = pyplot.figure(**figprops) # First sub-plot, the original time series anomaly and inverse wavelet # transform. ax = pyplot.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(date, dat, linewidth=1.5, color=[0.5, 0.5, 0.5]) ax.plot(date, iwave, 'k-', linewidth=1,zorder=100) if moornum ==8: ax.set_xlim(date[0],date[-1]) else: ax.set_xlim(date[0].values,date[-1].values) # ax.set_title('a) {}'.format(title)) ax.set_ylabel(r'{} [{}]'.format(label, units)) # Second sub-plot, the normalized wavelet power spectrum and significance # level contour lines and cone of influece hatched area. Note that period # scale is logarithmic. bx = pyplot.axes([0.1, 0.37, 0.65, 0.28]) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] bx.contourf(t, numpy.log2(period), numpy.log2(power), numpy.log2(levels), extend='both', cmap=pyplot.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, numpy.log2(period), sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.fill(numpy.concatenate([t, t[-1:] + dt, t[-1:] + dt, t[:1] - dt, t[:1] - dt]), numpy.concatenate([numpy.log2(coi), [1e-9], numpy.log2(period[-1:]), numpy.log2(period[-1:]), [1e-9]]), 'k', alpha=0.3, hatch='x') bx.set_title('{} Wavelet Power Spectrum ({})'.format(label, mother.name)) bx.set_ylabel('Period (hours)') # Yticks = 2 ** numpy.arange(numpy.ceil(numpy.log2(period.min())), numpy.ceil(numpy.log2(period.max()))) bx.set_yticks(numpy.log2(Yticks)) bx.set_yticklabels(Yticks) bx.set_xticklabels('') bx.set_xlim(t.min(),t.max()) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. cx = pyplot.axes([0.77, 0.37, 0.2, 0.28], sharey=bx) cx.plot(glbl_signif, numpy.log2(period), 'k--') cx.plot(var * fft_theor, numpy.log2(period), '--', color='#cccccc') cx.plot(var * fft_power, numpy.log2(1./fftfreqs), '-', color='#cccccc', linewidth=1.) cx.plot(var * glbl_power, numpy.log2(period), 'k-', linewidth=1.5) cx.set_title('Global Wavelet Spectrum') cx.set_xlabel(r'Power [({})^2]'.format(units)) cx.set_xlim([0, glbl_power.max() + var]) cx.set_ylim(numpy.log2([period.min(), period.max()])) cx.set_yticks(numpy.log2(Yticks)) cx.set_yticklabels(Yticks) pyplot.setp(cx.get_yticklabels(), visible=False) spowdic={} spowdic['sig']=scale_avg_signif if moornum==8: spowdic['date']=date else: spowdic['date']=date.values spowdic['spow']=scale_avg # Fourth sub-plot, the scale averaged wavelet spectrum. dx = pyplot.axes([0.1, 0.07, 0.65, 0.2], sharex=ax) dx.axhline(scale_avg_signif, color='k', linestyle='--', linewidth=1.) dx.plot(date, scale_avg, 'k-', linewidth=1.5) dx.set_title('{}--{} hour scale-averaged power'.format(pmin,pmax)) # [dx.axvline(dd,color=clist[ii],linewidth=3) for ii,dd in enumerate(dlist)] # dx.set_xlabel('Time (hours)') dx.set_ylabel(r'Average variance [{}]'.format(units)) if moornum ==8: dx.set_xlim(date[0],date[-1]) else: dx.set_xlim(date[0].values,date[-1].values) fig.suptitle(savetit) savefig(figdir+'Wavelet_'+savetit+'.png',bbox_inches='tight') return nomd,spowdic
def inverse(self): return wavelet.icwt(self.coeffs, self.scales, self.feature.dt, self.feature.dj, self.feature.mother) * self.feature.amplitude
def cwt(signal, t, obspy=None): # from __future__ import division import numpy from matplotlib import pyplot import pycwt as wavelet from pycwt.helpers import find signal = signal[10000:11000] t = t[10000:11000] url = 'http://paos.colorado.edu/research/wavelets/wave_idl/nino3sst.txt' dat = numpy.genfromtxt(url, skip_header=19) title = 'DICARDIA' label = 'DICARDIA SST' units = 'degC' t0 = 1871.0 dt = 0.25 # In years N = signal.shape[0] print(N) p = numpy.polyfit(t, signal, 1) dat_notrend = signal - numpy.polyval(p, t) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1( signal) # Lag-1 autocorrelation for red noise wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std power = (numpy.abs(wave))**2 fft_power = numpy.abs(fft)**2 period = 1 / freqs power /= scales[:, None] signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) sel = find((period >= 2) & (period < 8)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance( var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) # Prepare the figure pyplot.close('all') pyplot.ioff() figprops = dict(figsize=(11, 8), dpi=72) fig = pyplot.figure(**figprops) # First sub-plot, the original time series anomaly and inverse wavelet # transform. ax = pyplot.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(t, iwave, '-', linewidth=1, color=[0.5, 0.5, 0.5]) ax.plot(t, signal, 'k', linewidth=1.5) ax.set_title('a) {}'.format(title)) ax.set_ylabel(r'{} [{}]'.format(label, units)) # Second sub-plot, the normalized wavelet power spectrum and significance # level contour lines and cone of influece hatched area. Note that period # scale is logarithmic. bx = pyplot.axes([0.1, 0.37, 0.65, 0.28], sharex=ax) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] bx.contourf(t, numpy.log2(period), numpy.log2(power), numpy.log2(levels), extend='both', cmap=pyplot.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, numpy.log2(period), sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.fill(numpy.concatenate( [t, t[-1:] + dt, t[-1:] + dt, t[:1] - dt, t[:1] - dt]), numpy.concatenate([ numpy.log2(coi), [1e-9], numpy.log2(period[-1:]), numpy.log2(period[-1:]), [1e-9] ]), 'k', alpha=0.3, hatch='x') bx.set_title('b) {} Wavelet Power Spectrum ({})'.format( label, mother.name)) bx.set_ylabel('Period (years)') # Yticks = 2**numpy.arange(numpy.ceil(numpy.log2(period.min())), numpy.ceil(numpy.log2(period.max()))) bx.set_yticks(numpy.log2(Yticks)) bx.set_yticklabels(Yticks) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. cx = pyplot.axes([0.77, 0.37, 0.2, 0.28], sharey=bx) cx.plot(glbl_signif, numpy.log2(period), 'k--') cx.plot(var * fft_theor, numpy.log2(period), '--', color='#cccccc') cx.plot(var * fft_power, numpy.log2(1. / fftfreqs), '-', color='#cccccc', linewidth=1.) cx.plot(var * glbl_power, numpy.log2(period), 'k-', linewidth=1.5) cx.set_title('c) Global Wavelet Spectrum') cx.set_xlabel(r'Power [({})^2]'.format(units)) cx.set_xlim([0, glbl_power.max() + var]) cx.set_ylim(numpy.log2([period.min(), period.max()])) cx.set_yticks(numpy.log2(Yticks)) cx.set_yticklabels(Yticks) pyplot.setp(cx.get_yticklabels(), visible=False) # Fourth sub-plot, the scale averaged wavelet spectrum. dx = pyplot.axes([0.1, 0.07, 0.65, 0.2], sharex=ax) dx.axhline(scale_avg_signif, color='k', linestyle='--', linewidth=1.) dx.plot(t, scale_avg, 'k-', linewidth=1.5) dx.set_title('d) {}--{} year scale-averaged power'.format(2, 8)) dx.set_xlabel('Time (year)') dx.set_ylabel(r'Average variance [{}]'.format(units)) ax.set_xlim([t.min(), t.max()]) pyplot.show()
def wtdtw_dvv(ref, cur, allfreq, para, maxLag, b, direction, dj=1 / 12, s0=-1, J=-1, wvn='morlet', normalize=True): """ Apply dynamic time warping method to continuous wavelet transformation (CWT) of signals for all frequecies in an interest range Parameters -------------- ref: The "Reference" timeseries (numpy.ndarray) cur: The "Current" timeseries (numpy.ndarray) allfreq: a boolen variable to make measurements on all frequency range or not maxLag: max number of points to search forward and backward. b: b-value to limit strain, which is to limit the maximum velocity perturbation. See equation 11 in (Mikesell et al. 2015) direction: direction to accumulate errors (1=forward, -1=backward) dj, s0, J, sig, wvn: common parameters used in 'wavelet.wct' normalize: normalize the wavelet spectrum or not. Default is True RETURNS: ------------------ dvv: estimated dv/v err: error of dv/v estimation Written by Congcong Yuan (30 Jun, 2019) """ # common variables t = para['t'] twin = para['twin'] freq = para['freq'] dt = para['dt'] tmin = np.min(twin) tmax = np.max(twin) fmin = np.min(freq) fmax = np.max(freq) itvec = np.arange( np.int((tmin - t.min()) / dt) + 1, np.int((tmax - t.min()) / dt) + 1) tvec = t[itvec] # apply cwt on two traces cwt1, sj, freq, coi, _, _ = pycwt.cwt(cur, dt, dj, s0, J, wvn) cwt2, sj, freq, coi, _, _ = pycwt.cwt(ref, dt, dj, s0, J, wvn) # extract real values of cwt rcwt1, rcwt2 = np.real(cwt1), np.real(cwt2) # zero out cone of influence and data outside frequency band if (fmax > np.max(freq)) | (fmax <= fmin): raise ValueError('Abort: input frequency out of limits!') else: freq_indin = np.where((freq >= fmin) & (freq <= fmax))[0] # convert wavelet domain back to time domain (~filtering) if not allfreq: # inverse cwt to time domain icwt1 = pycwt.icwt(cwt1[freq_indin], sj[freq_indin], dt, dj, wvn) icwt2 = pycwt.icwt(cwt2[freq_indin], sj[freq_indin], dt, dj, wvn) # assume all time window is used wcwt1, wcwt2 = np.real(icwt1), np.real(icwt2) # Normalizes both signals, if appropriate. if normalize: ncwt1 = (wcwt1 - wcwt1.mean()) / wcwt1.std() ncwt2 = (wcwt2 - wcwt2.mean()) / wcwt2.std() else: ncwt1 = wcwt1 ncwt2 = wcwt2 # run dtw dv, error, dist = dtw_dvv(ncwt2[itvec], ncwt1[itvec], para, maxLag, b, direction) dvv, err = dv, error return dvv, err # directly take advantage of the real-valued parts of wavelet transforms else: # initialize variable nfreq = len(freq_indin) dvv, cc, cdp, err = np.zeros(nfreq,dtype=np.float32), np.zeros(nfreq,dtype=np.float32),\ np.zeros(nfreq,dtype=np.float32),np.zeros(nfreq,dtype=np.float32) # loop through each freq for ii, ifreq in enumerate(freq_indin): # prepare windowed data wcwt1, wcwt2 = rcwt1[ifreq], rcwt2[ifreq] # Normalizes both signals, if appropriate. if normalize: ncwt1 = (wcwt1 - wcwt1.mean()) / wcwt1.std() ncwt2 = (wcwt2 - wcwt2.mean()) / wcwt2.std() else: ncwt1 = wcwt1 ncwt2 = wcwt2 # run dtw dv, error, dist = dtw_dvv(ncwt2[itvec], ncwt1[itvec], para, maxLag, b, direction) dvv[ii], err[ii] = dv, error return freq[freq_indin], dvv, err
def wts_dvv(ref, cur, allfreq, para, dv_range, nbtrial, dj=1 / 12, s0=-1, J=-1, wvn='morlet', normalize=True): """ Apply stretching method to continuous wavelet transformation (CWT) of signals for all frequecies in an interest range Parameters -------------- ref: The complete "Reference" time series (numpy.ndarray) cur: The complete "Current" time series (numpy.ndarray) allfreq: a boolen variable to make measurements on all frequency range or not para: a dict containing freq/time info of the data matrix dv_range: absolute bound for the velocity variation; example: dv=0.03 for [-3,3]% of relative velocity change (float) nbtrial: number of stretching coefficient between dvmin and dvmax, no need to be higher than 100 (float) dj, s0, J, sig, wvn: common parameters used in 'wavelet.wct' normalize: normalize the wavelet spectrum or not. Default is True RETURNS: ------------------ dvv: estimated dv/v err: error of dv/v estimation Written by Congcong Yuan (30 Jun, 2019) """ # common variables t = para['t'] twin = para['twin'] freq = para['freq'] dt = para['dt'] tmin = np.min(twin) tmax = np.max(twin) fmin = np.min(freq) fmax = np.max(freq) itvec = np.arange( np.int((tmin - t.min()) / dt) + 1, np.int((tmax - t.min()) / dt) + 1) tvec = t[itvec] # apply cwt on two traces cwt1, sj, freq, coi, _, _ = pycwt.cwt(cur, dt, dj, s0, J, wvn) cwt2, sj, freq, coi, _, _ = pycwt.cwt(ref, dt, dj, s0, J, wvn) # extract real values of cwt rcwt1, rcwt2 = np.real(cwt1), np.real(cwt2) # zero out data outside frequency band if (fmax > np.max(freq)) | (fmax <= fmin): raise ValueError('Abort: input frequency out of limits!') else: freq_indin = np.where((freq >= fmin) & (freq <= fmax))[0] # convert wavelet domain back to time domain (~filtering) if not allfreq: # inverse cwt to time domain icwt1 = pycwt.icwt(cwt1[freq_indin], sj[freq_indin], dt, dj, wvn) icwt2 = pycwt.icwt(cwt2[freq_indin], sj[freq_indin], dt, dj, wvn) # assume all time window is used wcwt1, wcwt2 = np.real(icwt1), np.real(icwt2) # Normalizes both signals, if appropriate. if normalize: ncwt1 = (wcwt1 - wcwt1.mean()) / wcwt1.std() ncwt2 = (wcwt2 - wcwt2.mean()) / wcwt2.std() else: ncwt1 = wcwt1 ncwt2 = wcwt2 # run stretching dvv, err, cc, cdp = ts_dvv(ncwt2[itvec], ncwt1[itvec], dv_range, nbtrial, para) return dvv, err # directly take advantage of the real-valued parts of wavelet transforms else: # initialize variable nfreq = len(freq_indin) dvv, cc, cdp, err = np.zeros(nfreq,dtype=np.float32), np.zeros(nfreq,dtype=np.float32),\ np.zeros(nfreq,dtype=np.float32),np.zeros(nfreq,dtype=np.float32) # loop through each freq for ii, ifreq in enumerate(freq_indin): # prepare windowed data wcwt1, wcwt2 = rcwt1[ifreq], rcwt2[ifreq] # Normalizes both signals, if appropriate. if normalize: ncwt1 = (wcwt1 - wcwt1.mean()) / wcwt1.std() ncwt2 = (wcwt2 - wcwt2.mean()) / wcwt2.std() else: ncwt1 = wcwt1 ncwt2 = wcwt2 # run stretching dv, error, c1, c2 = ts_dvv(ncwt2[itvec], ncwt1[itvec], dv_range, nbtrial, para) dvv[ii], cc[ii], cdp[ii], err[ii] = dv, c1, c2, error return freq[freq_indin], dvv, err
def plot_wavelet(t, dat, dt, pl, pr, period_pltlim=None, ax=None, ax2=None, stscale=2, siglev=0.95, cmap='viridis', title='', levels=None, label='', units='', tunits='', sav_img=False): import pycwt as wavelet from pycwt.helpers import find import numpy as np import matplotlib.pyplot as plt from copy import copy import numpy.ma as ma t_ = copy(t) t0 = t[0] # print(Time(t[-1:], format='plot_date').iso) # We also create a time array in years. N = dat.size t = np.arange(0, N) * dt + t0 # print(Time(t[-1:], format='plot_date').iso) # We write the following code to detrend and normalize the input data by its # standard deviation. Sometimes detrending is not necessary and simply # removing the mean value is good enough. However, if your dataset has a well # defined trend, such as the Mauna Loa CO\ :sub:`2` dataset available in the # above mentioned website, it is strongly advised to perform detrending. # Here, we fit a one-degree polynomial function and then subtract it from the # original data. p = np.polyfit(t - t0, dat, 1) dat_notrend = dat - np.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset # The next step is to define some parameters of our wavelet analysis. We # select the mother wavelet, in this case the Morlet wavelet with # :math:`\omega_0=6`. mother = wavelet.Morlet(6) s0 = stscale * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = -1 # 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise # The following routines perform the wavelet transform and inverse wavelet # transform using the parameters defined above. Since we have normalized our # input time-series, we multiply the inverse transform by the standard # deviation. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std # We calculate the normalized wavelet and Fourier power spectra, as well as # the Fourier equivalent periods for each wavelet scale. power = (np.abs(wave))**2 fft_power = np.abs(fft)**2 period = 1 / freqs # We could stop at this point and plot our results. However we are also # interested in the power spectra significance test. The power is significant # where the ratio ``power / sig95 > 1``. signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=siglev, wavelet=mother) sig95 = np.ones([1, N]) * signif[:, None] sig95 = power / sig95 # Then, we calculate the global wavelet spectrum and determine its # significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=siglev, dof=dof, wavelet=mother) # We also calculate the scale average between 2 years and 8 years, and its # significance level. sel = find((period >= pl) & (period < pr)) Cdelta = mother.cdelta scale_avg = (scales * np.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance( var, dt, scales, 2, alpha, significance_level=siglev, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) # levels = [0.25, 0.5, 1, 2, 4, 8, 16,32] if levels is None: levels = np.linspace(0.0, 128., 256) # ax.contourf(t, np.log2(period), np.log2(power), np.log2(levels), extend='both', cmap=plt.cm.viridis) im = ax.contourf(t_, np.array(period) * 24 * 60, power, levels, extend='both', cmap=cmap, zorder=-20) # for pathcoll in im.collections: # pathcoll.set_rasterized(True) ax.set_rasterization_zorder(-10) # im = ax.pcolormesh(t_, np.array(period) * 24 * 60, power,vmax=32.,vmin=0, cmap=cmap) # im = ax.contourf(t, np.array(period)*24*60, np.log2(power), np.log2(levels), extend='both', cmap=cmap) extent = [t_.min(), t_.max(), 0, max(period) * 24 * 60] # ax.contour(t, np.log2(period), sig95, [-99, 1], colors='k', linewidths=1, extent=extent) CS = ax.contour(t_, np.array(period) * 24 * 60, sig95 * siglev, [-99, 1.0 * siglev], colors='k', linewidths=1, extent=extent) ax.clabel(CS, inline=1, fmt='%1.3f') ax.fill(np.concatenate( [t_, t_[-1:] + dt, t_[-1:] + dt, t_[:1] - dt, t_[:1] - dt]), np.concatenate([ np.array(coi), [2**(1e-9)], np.array(period[-1:]), np.array(period[-1:]), [2**(1e-9)] ]) * 24 * 60, color='k', alpha=0.75, edgecolor='None', facecolor='k', hatch='x') # ### not Matplotlib does not display hatching when rendering to pdf. Here is a workaround. # ax.fill(np.concatenate([t_, t_[-1:] + dt, t_[-1:] + dt, t_[:1] - dt, t_[:1] - dt]), # np.concatenate( # [np.array(coi), [2 ** (1e-9)], np.array(period[-1:]), np.array(period[-1:]), # [2 ** (1e-9)]]) * 24 * 60, # color='None', alpha=1.0, edgecolor='k', hatch='x') # ax.set_title('b) {} Wavelet Power Spectrum ({})'.format(label, mother.name)) # # ax.set_rasterization_zorder(20) # Yticks = np.arange(np.ceil(np.array(period.min()*24*60)), np.ceil(np.array(period.max()*24*60))) # ax.set_yticks(np.array(Yticks)) # ax.set_yticklabels(Yticks) ax2.plot(glbl_signif, np.array(period) * 24 * 60, 'k--') # ax2.plot(var * fft_theor, np.array(period) * 24 * 60, '--', color='#cccccc') # ax2.plot(var * fft_power, np.array(1. / fftfreqs) * 24 * 60, '-', color='#cccccc', # linewidth=1.) ax2.plot(var * glbl_power, np.array(period) * 24 * 60, 'k-', linewidth=1) mperiod = ma.masked_outside(np.array(period), period_pltlim[0], period_pltlim[1]) mpower = ma.masked_array(var * glbl_power, mask=mperiod.mask) # ax2.set_title('c) Global Wavelet Spectrum') ax2.set_xlabel(r'Power'.format(units)) ax2.set_xlim([0, mpower.compressed().max() + var]) # print(glbl_power) # ax2.set_ylim(np.array([period.min(), period.max()])) # ax2.set_yticks(np.array(Yticks)) # ax2.set_yticklabels(Yticks) plt.setp(ax2.get_yticklabels(), visible=False) if period_pltlim: ax.set_ylim(np.array(period_pltlim) * 24 * 60) else: ax.set_ylim(np.array([period.min(), period.max()]) * 24 * 60) return im
def do_icwt(wave, scales, dt, dj, mother, std): return wavelet.icwt(wave, scales, dt, dj, mother) * std
def do_wavelet_transform(dat, dt): t0 = 0 # dt = 0.25 # In years # We also create a time array in years. N = dat.size t = np.arange(0, N) * dt + t0 ''' We write the following code to detrend and normalize the input data by its standard deviation. Sometimes detrending is not necessary and simply removing the mean value is good enough. However, if your dataset has a well defined trend, such as the Mauna Loa CO\ :sub:`2` dataset available in the above mentioned website, it is strongly advised to perform detrending. Here, we fit a one-degree polynomial function and then subtract it from the original data. ''' p = np.polyfit(t - t0, dat, 1) dat_notrend = dat - np.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset # The next step is to define some parameters of our wavelet analysis. We # select the mother wavelet, in this case the Morlet wavelet with # :math:`\omega_0=6`. mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves sr = pd.Series(dat) alpha = sr.autocorr(lag=1) # Lag-1 autocorrelation for red noise ''' The following routines perform the wavelet transform and inverse wavelet transform using the parameters defined above. Since we have normalized our input time-series, we multiply the inverse transform by the standard deviation. ''' wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std # We calculate the normalized wavelet and Fourier power spectra, as well as # the Fourier equivalent periods for each wavelet scale. power = (np.abs(wave))**2 fft_power = np.abs(fft)**2 period = 1 / freqs ''' We could stop at this point and plot our results. However we are also interested in the power spectra significance test. The power is significant where the ratio ``power / sig95 > 1``. ''' signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = np.ones([1, N]) * signif[:, None] sig95 = power / sig95 # Then, we calculate the global wavelet spectrum and determine its # significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) # We also calculate the scale average between 2 years and 8 years, and its # significance level. sel = find((period >= 2) & (period < 8)) Cdelta = mother.cdelta scale_avg = (scales * np.ones((N, 1))).transpose() # As in Torrence and Compo (1998) equation 24 scale_avg = power / scale_avg scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance( var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) return dat, t, \ period, power, coi, wave, \ scales, dt, dj, mother, sig95, \ glbl_power, glbl_signif, \ scale_avg_signif, scale_avg, \ std, iwave, var, \ fft_theor, fft_power, fftfreqs
def get_graph_from_file(in_filepath, out_folder, out_filename): # Get data # TODO there are differents formats of file # TODO implement differents parsers by parameters of function p1 = numpy.genfromtxt(in_filepath) # TODO fix this shit dat = p1 title = 'NINO3 Sea Surface Temperature' label = 'NINO3 SST' units = 'degC' # Values for calculations # TODO spike about args t0 = 12.0 # start time dt = 0.5 # step of differentiation - in minutes N = dat.size t = numpy.arange(0, N) * dt + t0 p = numpy.polyfit(t - t0, dat, 1) dat_notrend = dat - numpy.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std power = (numpy.abs(wave))**2 fft_power = numpy.abs(fft)**2 period = 1 / freqs power /= scales[:, None] signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) sel = find((period >= 2) & (period < 8)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance( var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) # Prepare the figure pyplot.close('all') #pyplot.ioff() figprops = dict(dpi=144) fig = pyplot.figure(**figprops) # Second sub-plot, the normalized wavelet power spectrum and significance # level contour lines and cone of influece hatched area. Note that period # scale is logarithmic. bx = pyplot.axes([0.1, 0.37, 0.65, 0.28]) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] bx.contourf(t, period, numpy.log2(power), numpy.log2(levels), extend='both', cmap=pyplot.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, period, sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.set_title('{} Wavelet Power Spectrum ({})'.format(label, mother.name)) bx.set_ylabel('Period (minutes)') # #Yticks = 2 ** numpy.arange(numpy.ceil(numpy.log2(period.min())), # numpy.ceil(numpy.log2(period.max()))) #bx.set_yticks(numpy.log2(Yticks)) #bx.set_yticklabels(Yticks) bx.set_ylim([2, 20]) # Save graph to file # TODO implement #pyplot.savefig('{}/{}.png'.format(out_folder, out_filename)) # ---------------------------------------------- # or show the graph pyplot.show()
def parse_frames(image_file, sig=0.95): """ """ cap = cv2.VideoCapture(image_file) if verbose: print("Video successfully loaded") FRAME_COUNT = int(cap.get(cv2.CAP_PROP_FRAME_COUNT)) FPS = cap.get(cv2.CAP_PROP_FPS) if verbose > 1: FRAME_HEIGHT = cap.get(cv2.CAP_PROP_FRAME_HEIGHT) FRAME_WIDTH = cap.get(cv2.CAP_PROP_FRAME_WIDTH) print( "INFO: \n Frame count: ", FRAME_COUNT, "\n", "FPS: ", FPS, " \n", "FRAME_HEIGHT: ", FRAME_HEIGHT, " \n", "FRAME_WIDTH: ", FRAME_WIDTH, " \n", ) directory = os.getcwd( ) + '\\analysis\\{}_{}_{}_{}({})_{}_{}_scaled\\'.format( date, trial_type, name, wavelet, order, per_min, per_max) if not os.path.exists(directory): os.makedirs(directory) made = False frame_idx = 0 idx = 0 dropped = 0 skip = True thresh = None df_wav = pd.DataFrame() df_auc = pd.DataFrame() df_for = pd.DataFrame() df_pow = pd.DataFrame() for i in range(FRAME_COUNT): a, img = cap.read() if a: frame_idx += 1 if made == False: #first we need to manually determine the boundaries and angle res = bg.manual_format(img) #print(res) x, y, w, h, angle = res horizon_begin = x horizon_end = x + w vert_begin = y vert_end = y + h #scale_array = np.zeros((FRAME_COUNT, abs(horizon_begin - horizon_end))) #area_time = np.zeros((FRAME_COUNT)) #df['] print("Now Select the Red dot") red_res = bg.manual_format(img, stop_sign=True) red_x, red_y, red_w, red_h = red_res box_h_begin = red_x box_h_end = red_x + red_w box_v_begin = red_y box_v_end = red_y + red_h made = True #dims = (vert_begin, vert_end, horizon_begin, horizon_end) real_time = i / FPS rows, cols, chs = img.shape M = cv2.getRotationMatrix2D((cols / 2, rows / 2), angle, 1) rot_img = cv2.warpAffine(img, M, (cols, rows)) roi = rot_img[vert_begin:vert_end, horizon_begin:horizon_end, :] red_box = img[box_v_begin:box_v_end, box_h_begin:box_h_end, 2] if thresh == None: thresh = np.mean(red_box) #print(np.mean(red_box)) percent_drop = 1 - (np.mean(red_box) / thresh) print(percent_drop) if percent_drop >= 0.18: #cv2.imshow("Red Image", red_box) #cv2.waitKey(0) skip = False if skip: if verbose >= 1: print('Frame is skipped {} / {}'.format( frame_idx, FRAME_COUNT)) continue if verbose >= 1: print('Processing frame {} / {}'.format( frame_idx, FRAME_COUNT)) idx += 1 begin_code, data_line = extract_frame(roi) #We need to detrend the data before sending it away N = len(data_line) dt = su / N t = np.arange(0, N) * dt t = t - np.mean(t) var, std, dat_norm = detrend(data_line) ################################################################### if wavelet == 'DOG': mother = cwt.DOG(order) elif wavelet == 'Paul': mother = cwt.Paul(order) elif wavelet == 'Morlet': mother = cwt.Morlet(order) elif wavelet == 'MexicanHat': mother = cwt.MexicanHat(order) s0 = 4 * dt try: alpha, _, _ = cwt.ar1(dat_norm) except: alpha = 0.95 wave, scales, freqs, coi, fft, fftfreqs = cwt.cwt( dat_norm, dt, dj, s0, J, mother) iwave = cwt.icwt( wave, scales, dt, dj, mother) * std #This is a reconstruction of the wave power = (np.abs(wave))**2 #This is the power spectra fft_power = np.abs(fft)**2 #This is the fourier power period = 1 / freqs #This is the periods of the wavelet analysis in cm power /= scales[:, None] #This is an option suggested by Liu et. al. #Next we calculate the significance of the power spectra. Significane where power / sig95 > 1 signif, fft_theor = cwt.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = np.ones([1, N]) * signif[:, None] sig95 = power / sig95 #This is the significance of the global wave glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = cwt.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) sel = find((period >= per_min) & (period < per_max)) Cdelta = mother.cdelta scale_avg = (scales * np.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 #scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) #scale_array[i,:] = scale_array[i,:]/np.max(scale_array[i,:]) #data_array[i,:] = data_array[i,:]/np.max(data_array[i,:]) scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = cwt.significance( var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) Yticks = 2**np.arange(np.ceil(np.log2(period.min())), np.ceil(np.log2(period.max()))) plt.close('all') plt.ioff() figprops = dict(figsize=(11, 8), dpi=72) fig = plt.figure(**figprops) wx = plt.axes([0.77, 0.75, 0.2, 0.2]) imz = 0 for idxy in range(0, len(period), 10): wx.plot(t, mother.psi(t / period[idxy]) + imz, linewidth=1.5) imz += 1 wx.xaxis.set_ticklabels([]) #wx.set_ylim([-10,10]) # First sub-plot, the original time series anomaly and inverse wavelet # transform. ax = plt.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(t, data_line - np.mean(data_line), 'k', label="Original Data") ax.plot(t, iwave, '-', linewidth=1, color=[0.5, 0.5, 0.5], label="Reconstructed wave") ax.plot(t, dat_norm, '--k', linewidth=1.5, color=[0.5, 0.5, 0.5], label="Denoised Wave") ax.set_title( 'a) {:10.2f} from beginning of trial.'.format(real_time)) ax.set_ylabel(r'{} [{}]'.format("Amplitude", unit)) ax.legend(loc=1) ax.set_ylim([-200, 200]) #If the non-serrated section, bounds are 200 - # Second sub-plot, the normalized wavelet power spectrum and significance # level contour lines and cone of influece hatched area. Note that period # scale is logarithmic. bx = plt.axes([0.1, 0.37, 0.65, 0.28], sharex=ax) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] cont = bx.contourf(t, np.log2(period), np.log2(power), np.log2(levels), extend='both', cmap=plt.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, np.log2(period), sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.fill(np.concatenate( [t, t[-1:] + dt, t[-1:] + dt, t[:1] - dt, t[:1] - dt]), np.concatenate([ np.log2(coi), [1e-9], np.log2(period[-1:]), np.log2(period[-1:]), [1e-9] ]), 'k', alpha=0.3, hatch='x') bx.set_title( 'b) {} Octaves Wavelet Power Spectrum [{}({})]'.format( octaves, mother.name, order)) bx.set_ylabel('Period (cm)') # Yticks = 2**np.arange(np.ceil(np.log2(period.min())), np.ceil(np.log2(period.max()))) bx.set_yticks(np.log2(Yticks)) bx.set_yticklabels(Yticks) cbar = fig.colorbar(cont, ax=bx) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. cx = plt.axes([0.77, 0.37, 0.2, 0.28], sharey=bx) cx.plot(glbl_signif, np.log2(period), 'k--') cx.plot(var * fft_theor, np.log2(period), '--', color='#cccccc') cx.plot(var * fft_power, np.log2(1. / fftfreqs), '-', color='#cccccc', linewidth=1.) cx.plot(var * glbl_power, np.log2(period), 'k-', linewidth=1.5) cx.set_title('c) Global Wavelet Spectrum') cx.set_xlabel(r'Power [({})^2]'.format(unit)) #cx.set_xlim([0, (var*fft_theor).max()]) plt.xscale('log') cx.set_ylim(np.log2([period.min(), period.max()])) cx.set_yticks(np.log2(Yticks)) cx.set_yticklabels(Yticks) #if sig_array == []: yvals = np.linspace(Yticks.min(), Yticks.max(), len(period)) plt.xscale('linear') plt.setp(cx.get_yticklabels(), visible=False) # Fourth sub-plot, the scale averaged wavelet spectrum. dx = plt.axes([0.1, 0.07, 0.65, 0.2], sharex=ax) dx.axhline(scale_avg_signif, color='k', linestyle='--', linewidth=1.) dx.plot(t, scale_avg, 'k-', linewidth=1.5) dx.set_title('d) {}-{}cm scale-averaged power'.format( per_min, per_max)) dx.set_xlabel('Distance from center(cm)') dx.set_ylabel(r'Average variance [{}]'.format(unit)) #dx.set_ylim([0,500]) ax.set_xlim([t.min(), t.max()]) #plt.savefig(directory+'{}_analysis_frame-{}.png'.format(name, idx), bbox = 'tight') if verbose >= 2: print('*' * int((i / FRAME_COUNT) * 100)) df_wav[real_time] = (pd.Series(dat_norm, index=t)) df_pow[real_time] = (pd.Series(var * glbl_power, index=np.log2(period))) df_for[real_time] = (pd.Series(var * fft_power, index=np.log2(1. / fftfreqs))) df_auc[real_time] = [np.trapz(data_line)] else: print("Frame #{} has dropped".format(i)) dropped += 1 if verbose >= 1: print('All images saved') if verbose >= 1: print("{:10.2f} % of the frames have dropped".format( (dropped / FRAME_COUNT) * 100)) #Plotting and saving tyhe row, cols = df_pow.shape time = np.arange(0, cols) / FPS plt.close('all') plt.ioff() plt.contourf(time, df_pow.index.tolist(), df_pow) plt.contour(time, df_pow.index.tolist(), df_pow) plt.title("Global Power over Time") plt.ylabel("Period[cm]") plt.xlabel("Time") cax = plt.gca() #plt.xscale('log') cax.set_ylim(np.log2([period.min(), period.max()])) cax.set_yticks(np.log2(Yticks)) cax.set_yticklabels(Yticks) plt.savefig(directory + '{}_global_power-{}.png'.format(name, idx), bbox='tight') row, cols = df_for.shape time = np.arange(0, cols) / FPS plt.close('all') plt.ioff() plt.contourf(time, df_for.index.tolist(), df_for) plt.contour(time, df_for.index.tolist(), df_for) plt.title("Fourier Power over Time") plt.ylabel("Period[cm]") plt.xlabel("Time") cax = plt.gca() #plt.xscale('log') cax.set_ylim(np.log2([period.min(), period.max()])) cax.set_yticks(np.log2(Yticks)) cax.set_yticklabels(Yticks) plt.savefig(directory + '{}_fourier_power-{}.png'.format(name, idx), bbox='tight') plt.close('all') plt.ioff() rows, cols = df_auc.shape time = np.arange(0, cols) / FPS plt.plot(time, df_auc.T) plt.xlabel("Time") plt.ylabel("Area under the curve in cm") plt.title("Area under the curve over time") plt.savefig(directory + '{}_area_under_curve-{}.png'.format(name, idx), bbox='tight') df_wav['Mean'] = df_wav.mean(axis=1) df_pow['Mean'] = df_pow.mean(axis=1) df_for['Mean'] = df_for.mean(axis=1) df_auc['Mean'] = df_auc.mean(axis=1) df_wav['Standard Deviation'] = df_wav.std(axis=1) df_pow['Standard Deviation'] = df_pow.std(axis=1) df_for['Standard Deviation'] = df_for.std(axis=1) df_auc['Standard Deviation'] = df_auc.std(axis=1) ##[Writing analysis to excel]############################################## print("Writing files") writer = pd.ExcelWriter(directory + "analysis{}.xlsx".format(trial_name)) df_wav.to_excel(writer, "Raw Waveforms") df_auc.to_excel(writer, "Area Under the Curve") df_for.to_excel(writer, "Fourier Spectra") df_pow.to_excel(writer, "Global Power Spectra") writer.save() ##[Writing means to a single file]######################################### #filename = 'C:\\pyscripts\\wavelet_analysis\\Overall_Analysis.xlsx' #append_data(filename, df_pow['Mean'].values, str(trial_name), Yticks) ##[Plotting mean power and foruier]######################################## plt.close('all') plt.ioff() plt.plot(df_pow['Mean'], df_pow.index.tolist(), label="Global Power") plt.plot(df_for['Mean'], df_for.index.tolist(), label="Fourier Power") plt.title("Global Power averaged over Time") plt.ylabel("Period[cm]") plt.xlabel("Power[cm^2]") cax = plt.gca() #plt.xscale('log') cax.set_ylim(np.log2([period.min(), period.max()])) cax.set_yticks(np.log2(Yticks)) cax.set_yticklabels(Yticks) plt.legend() plt.savefig(directory + '{}_both_{}.png'.format(name, idx), bbox='tight') plt.close('all') plt.ioff() plt.plot(df_pow['Mean'], df_pow.index.tolist(), label="Global Power") plt.title("Global Power averaged over Time") plt.ylabel("Period[cm]") plt.xlabel("Power[cm^2]") cax = plt.gca() #plt.xscale('log') cax.set_ylim(np.log2([period.min(), period.max()])) cax.set_yticks(np.log2(Yticks)) cax.set_yticklabels(Yticks) plt.legend() plt.savefig(directory + '{}_global_power_{}.png'.format(name, idx), bbox='tight') plt.close('all') plt.ioff() plt.plot(df_for['Mean'], df_for.index.tolist(), label="Fourier Power") plt.title("Fourier averaged over Time") plt.ylabel("Period[cm]") plt.xlabel("Power[cm^2]") cax = plt.gca() #plt.xscale('log') cax.set_ylim(np.log2([period.min(), period.max()])) cax.set_yticks(np.log2(Yticks)) cax.set_yticklabels(Yticks) plt.legend() plt.savefig(directory + '{}_fourier_{}.png'.format(name, idx), bbox='tight') cap.release() return directory
def graph_wavelet(data_xs, title, lims, font = 11, params = default_params): a_lims, b_lims, d_lims = lims plt.rcParams.update({'font.size': font}) return_data = {} N = len(data_xs) dt = (2*params['per_pixel'])/N #This is how much cm each pixel equals t = np.arange(0, N) * dt t = t - np.mean(t) t0 = 0 per_min = params['min_per'] per_max = params['max_per'] units = params['units'] sx = params['sx'] octaves = params['octaves'] dj = 1/params['suboctaves'] #suboctaves order = params['order'] var, std, dat_norm = detrend(data_xs) mother = cwt.DOG(order) #This is the Mother Wavelet s0 = sx * dt #This is the starting scale, which in out case is two pixels or 0.04cm/40um\ J = octaves/dj #This is powers of two with dj suboctaves return_data['var'] = var return_data['std'] = std try: alpha, _, _ = cwt.ar1(dat_norm) #This calculates the Lag-1 autocorrelation for red noise except: alpha = 0.95 wave, scales, freqs, coi, fft, fftfreqs = cwt.cwt(dat_norm, dt, dj, s0, J, mother) return_data['scales'] = scales return_data['freqs'] = freqs return_data['fft'] = fft iwave = cwt.icwt(wave, scales, dt, dj, mother) * std power = (np.abs(wave)) ** 2 fft_power = np.abs(fft) ** 2 period = 1 / freqs power /= scales[:, None] #This is an option suggested by Liu et. al. #Next we calculate the significance of the power spectra. Significane where power / sig95 > 1 signif, fft_theor = cwt.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = np.ones([1, N]) * signif[:, None] sig95 = power / sig95 glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = cwt.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) sel = find((period >= per_min) & (period < per_max)) Cdelta = mother.cdelta scale_avg = (scales * np.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = cwt.significance(var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) # Prepare the figure plt.close('all') plt.ioff() figprops = dict(figsize=(11, 11), dpi=72) fig = plt.figure(**figprops) wx = plt.axes([0.77, 0.75, 0.2, 0.2]) imz = 0 for idxy in range(0,len(period), 10): wx.plot(t, mother.psi(t / period[idxy]) + imz, linewidth = 1.5) imz+=1 wx.xaxis.set_ticklabels([]) ax = plt.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(t, data_xs, 'k', linewidth=1.5) ax.plot(t, iwave, '-', linewidth=1, color=[0.5, 0.5, 0.5]) ax.plot(t, dat_norm, '--', linewidth=1.5, color=[0.5, 0.5, 0.5]) if a_lims != None: ax.set_ylim([-a_lims, a_lims]) ax.set_title('a) {}'.format(title)) ax.set_ylabel(r'Displacement [{}]'.format(units)) #ax.set_ylim([-20,20]) bx = plt.axes([0.1, 0.37, 0.65, 0.28], sharex=ax) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] bx.contourf(t, np.log2(period), np.log2(power), np.log2(levels), extend='both', cmap=plt.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, np.log2(period), sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.fill(np.concatenate([t, t[-1:] + dt, t[-1:] + dt, t[:1] - dt, t[:1] - dt]), np.concatenate([np.log2(coi), [1e-9], np.log2(period[-1:]), np.log2(period[-1:]), [1e-9]]), 'k', alpha=0.3, hatch='x') bx.set_title('b) {} Octaves Wavelet Power Spectrum [{}({})]'.format(octaves, mother.name, order)) bx.set_ylabel('Period (cm)') # Yticks = 2 ** np.arange(np.ceil(np.log2(period.min())), np.ceil(np.log2(period.max()))) bx.set_yticks(np.log2(Yticks)) bx.set_yticklabels(Yticks) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. cx = plt.axes([0.77, 0.37, 0.2, 0.28], sharey=bx) cx.plot(glbl_signif, np.log2(period), 'k--') cx.plot(var * fft_theor, np.log2(period), '--', color='#cccccc') cx.plot(var * fft_power, np.log2(1./fftfreqs), '-', color='#cccccc', linewidth=1.) return_data['global_power'] = var * glbl_power return_data['fourier_spectra'] = var * fft_power return_data['per'] = np.log2(period) return_data['amp'] = np.log2(1./fftfreqs) cx.plot(var * glbl_power, np.log2(period), 'k-', linewidth=1.5) cx.set_title('c) Power Spectrum') cx.set_xlabel(r'Power [({})^2]'.format(units)) if b_lims != None: cx.set_xlim([0,b_lims]) #cx.set_xlim([0,max(glbl_power.max(), var*fft_power.max())]) #print(max(glbl_power.max(), var*fft_power.max())) cx.set_ylim(np.log2([period.min(), period.max()])) cx.set_yticks(np.log2(Yticks)) cx.set_yticklabels(Yticks) return_data['yticks'] = Yticks plt.setp(cx.get_yticklabels(), visible=False) # Fourth sub-plot, the scale averaged wavelet spectrum. dx = plt.axes([0.1, 0.07, 0.65, 0.2], sharex=ax) dx.axhline(scale_avg_signif, color='k', linestyle='--', linewidth=1.) dx.plot(t, scale_avg, 'k-', linewidth=1.5) dx.set_title('d) {}--{} cm scale-averaged power'.format(per_min, per_max)) dx.set_xlabel('Displacement (cm)') dx.set_ylabel(r'Average variance [{}]'.format(units)) ax.set_xlim([t.min(), t.max()]) if d_lims != None: dx.set_ylim([0,d_lims]) plt.savefig("C:\pyscripts\wavelet_analysis\Calibrated Images\{}".format(title)) return fig, return_data
def simple_sample(sls): # Then, we load the dataset and define some data related parameters. In this # case, the first 19 lines of the data file contain meta-data, that we ignore, # since we set them manually (*i.e.* title, units). # url = 'http://paos.colorado.edu/research/wavelets/wave_idl/nino3sst.txt' # dat = numpy.genfromtxt(url, skip_header=19) title = 'Sentence Length' label = 'Zhufu Sentence Length' units = 'Characters' t0 = 1 dt = 1 # In years dat = numpy.array(sls) # We also create a time array in years. N = dat.size t = numpy.arange(0, N) * dt + t0 # We write the following code to detrend and normalize the input data by its # standard deviation. Sometimes detrending is not necessary and simply # removing the mean value is good enough. However, if your dataset has a well # defined trend, such as the Mauna Loa CO\ :sub:`2` dataset available in the # above mentioned website, it is strongly advised to perform detrending. # Here, we fit a one-degree polynomial function and then subtract it from the # original data. p = numpy.polyfit(t - t0, dat, 1) dat_notrend = dat - numpy.polyval(p, t - t0) std = dat_notrend.std() # Standard deviation var = std**2 # Variance dat_norm = dat_notrend / std # Normalized dataset # The next step is to define some parameters of our wavelet analysis. We # select the mother wavelet, in this case the Morlet wavelet with # :math:`\omega_0=6`. mother = wavelet.Morlet(6) s0 = 2 * dt # Starting scale, in this case 2 * 0.25 years = 6 months dj = 1 / 12 # Twelve sub-octaves per octaves J = 7 / dj # Seven powers of two with dj sub-octaves alpha, _, _ = wavelet.ar1(dat) # Lag-1 autocorrelation for red noise # The following routines perform the wavelet transform and inverse wavelet # transform using the parameters defined above. Since we have normalized our # input time-series, we multiply the inverse transform by the standard # deviation. wave, scales, freqs, coi, fft, fftfreqs = wavelet.cwt( dat_norm, dt, dj, s0, J, mother) iwave = wavelet.icwt(wave, scales, dt, dj, mother) * std # We calculate the normalized wavelet and Fourier power spectra, as well as # the Fourier equivalent periods for each wavelet scale. power = (numpy.abs(wave))**2 fft_power = numpy.abs(fft)**2 period = 1 / freqs # We could stop at this point and plot our results. However we are also # interested in the power spectra significance test. The power is significant # where the ratio ``power / sig95 > 1``. signif, fft_theor = wavelet.significance(1.0, dt, scales, 0, alpha, significance_level=0.95, wavelet=mother) sig95 = numpy.ones([1, N]) * signif[:, None] sig95 = power / sig95 # Then, we calculate the global wavelet spectrum and determine its # significance level. glbl_power = power.mean(axis=1) dof = N - scales # Correction for padding at edges glbl_signif, tmp = wavelet.significance(var, dt, scales, 1, alpha, significance_level=0.95, dof=dof, wavelet=mother) # We also calculate the scale average between 2 years and 8 years, and its # significance level. sel = find((period >= 2) & (period < 8)) Cdelta = mother.cdelta scale_avg = (scales * numpy.ones((N, 1))).transpose() scale_avg = power / scale_avg # As in Torrence and Compo (1998) equation 24 scale_avg = var * dj * dt / Cdelta * scale_avg[sel, :].sum(axis=0) scale_avg_signif, tmp = wavelet.significance( var, dt, scales, 2, alpha, significance_level=0.95, dof=[scales[sel[0]], scales[sel[-1]]], wavelet=mother) # Finally, we plot our results in four different subplots containing the # (i) original series anomaly and the inverse wavelet transform; (ii) the # wavelet power spectrum (iii) the global wavelet and Fourier spectra ; and # (iv) the range averaged wavelet spectrum. In all sub-plots the significance # levels are either included as dotted lines or as filled contour lines. # Prepare the figure pyplot.close('all') pyplot.ioff() figprops = dict(figsize=(11, 8), dpi=72) fig = pyplot.figure(**figprops) # First sub-plot, the original time series anomaly and inverse wavelet # transform. ax = pyplot.axes([0.1, 0.75, 0.65, 0.2]) ax.plot(t, iwave, '-', linewidth=1, color=[0.5, 0.5, 0.5]) ax.plot(t, dat, 'k', linewidth=1.5) ax.set_title('a) {}'.format(title)) ax.set_ylabel(r'{} [{}]'.format(label, units)) # Second sub-plot, the normalized wavelet power spectrum and significance # level contour lines and cone of influece hatched area. Note that period # scale is logarithmic. bx = pyplot.axes([0.1, 0.37, 0.65, 0.28], sharex=ax) levels = [0.0625, 0.125, 0.25, 0.5, 1, 2, 4, 8, 16] bx.contourf(t, numpy.log2(period), numpy.log2(power), numpy.log2(levels), extend='both', cmap=pyplot.cm.viridis) extent = [t.min(), t.max(), 0, max(period)] bx.contour(t, numpy.log2(period), sig95, [-99, 1], colors='k', linewidths=2, extent=extent) bx.fill(numpy.concatenate( [t, t[-1:] + dt, t[-1:] + dt, t[:1] - dt, t[:1] - dt]), numpy.concatenate([ numpy.log2(coi), [1e-9], numpy.log2(period[-1:]), numpy.log2(period[-1:]), [1e-9] ]), 'k', alpha=0.3, hatch='x') bx.set_title('b) {} Wavelet Power Spectrum ({})'.format( label, mother.name)) bx.set_ylabel('Period (years)') # Yticks = 2**numpy.arange(numpy.ceil(numpy.log2(period.min())), numpy.ceil(numpy.log2(period.max()))) bx.set_yticks(numpy.log2(Yticks)) bx.set_yticklabels(Yticks) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. cx = pyplot.axes([0.77, 0.37, 0.2, 0.28], sharey=bx) cx.plot(glbl_signif, numpy.log2(period), 'k--') cx.plot(var * fft_theor, numpy.log2(period), '--', color='#cccccc') cx.plot(var * fft_power, numpy.log2(1. / fftfreqs), '-', color='#cccccc', linewidth=1.) cx.plot(var * glbl_power, numpy.log2(period), 'k-', linewidth=1.5) cx.set_title('c) Global Wavelet Spectrum') cx.set_xlabel(r'Power [({})^2]'.format(units)) cx.set_xlim([0, glbl_power.max() + var]) cx.set_ylim(numpy.log2([period.min(), period.max()])) cx.set_yticks(numpy.log2(Yticks)) cx.set_yticklabels(Yticks) pyplot.setp(cx.get_yticklabels(), visible=False) # Third sub-plot, the global wavelet and Fourier power spectra and theoretical # noise spectra. Note that period scale is logarithmic. dx = pyplot.axes([0.1, 0.07, 0.65, 0.2]) dx.plot(numpy.log2(fftfreqs), numpy.log2(fft_power), 'k') dx.plot(numpy.log2(freqs), var * fft_theor, '--', color='#cccccc') dx.plot(numpy.log2(1. / fftfreqs), var * fft_power, '-', color='#cccccc', linewidth=1.) dx.plot(fftfreqs, fft_power, 'k-', linewidth=1.5) dx.set_title('d) Global Wavelet Spectrum') dx.set_ylabel(r'Power [({})^2]'.format(units)) dx.set_xlim([0, 2 * fftfreqs.max()]) Yticks = 2**numpy.arange(numpy.ceil(numpy.log2(fft_power.min())), numpy.ceil(numpy.log2(fft_power.max()))) dx.set_ylim(numpy.log2([fft_power.min(), fft_power.max()])) dx.set_yticks(numpy.log2(Yticks)) dx.set_yticklabels(Yticks) pyplot.setp(dx.get_yticklabels(), visible=False) pyplot.show()