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I've two signals, from which I expect that one is responding on the other, but with a certain phase shift.

Now I would like to calculate the coherence or the normalized cross spectral density to estimate if there is any causality between the input and output to find out on which frequencies this coherence appear.

See for example this image (from here) which seems to have high coherence at the frequency 10: enter image description here

Now I know that I can calculate the phase shift of two signals using the cross-correlation, but how can I use the coherence (of frequency 10) to calculate the phase shift?

Code for image:

Compute the coherence of two signals
import numpy as np
import matplotlib.pyplot as plt

# make a little extra space between the subplots

nfft = 256
dt = 0.01
t = np.arange(0, 30, dt)
nse1 = np.random.randn(len(t))                 # white noise 1
nse2 = np.random.randn(len(t))                 # white noise 2
r = np.exp(-t/0.05)

cnse1 = np.convolve(nse1, r, mode='same')*dt   # colored noise 1
cnse2 = np.convolve(nse2, r, mode='same')*dt   # colored noise 2

# two signals with a coherent part and a random part
s1 = 0.01*np.sin(2*np.pi*10*t) + cnse1
s2 = 0.01*np.sin(2*np.pi*10*t) + cnse2

plt.plot(t, s1, 'b-', t, s2, 'g-')
plt.ylabel('s1 and s2')

cxy, f = plt.cohere(s1, s2, nfft, 1./dt)


For what it's worth, I've add an answer, maybe it's right, maybe it's wrong. I'm not sure..

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Is the problem that you don't know how to calculate the phase shift from the coherence, or that your code to do so doesn't work? The former is not an on-topic question here. –  jonrsharpe Feb 8 at 14:23
My problem is that I don't know how to calculate the phase shift from the coherence. It would be very much appreciated in case you can provide me with some hints or advice how to do this (programmatic or mathematical) –  Mattijn Feb 8 at 14:32
I'm not a Python programmer, but I'm pretty sure you can't. According to the documentation at matplotlib.org/api/mlab_api.html, plt.cohere computes the modulus square of the cross-spectral density normalized by the moduli of the signals, which is why it's purely real-valued. If there is a phase shift between two sinusoidal signals with the same frequency, then the cross-correlation between the signal will be oscillatory and have a phase shift associated with it, and that phase shift will remain after being Fourier transformed, but is then destroyed by taking the modulus. –  DumpsterDoofus Feb 8 at 15:37
So assuming that it's just doing the discretized version of the absolute value of the formula at en.wikipedia.org/wiki/Spectral_density#Cross-spectral_density, you won't find the phase shift. Is there some reason why you can't just take the FFT's of the two individual signals and use the phase difference taken from that? –  DumpsterDoofus Feb 8 at 15:38
Just for clarification, when you say "one is responding on the other, but with a certain phase shift", do you mean that you are expecting the two signals to be the same (except for noise), but with a time delay between the two? –  DumpsterDoofus Feb 8 at 15:59

1 Answer 1

up vote 1 down vote accepted

Let me try to answer my own question and maybe one day it might be useful to others or function as a starting point for a (new) discussion:

Firstly calculate the power spectral densities of both the signals,

psd(s1, nfft, 1/dt)

psd(s2, nfft, 1/dt)


resulting in:enter image description here

Secondly calculate the cross-spectral density, which is Fourier transform of the cross-correlation function:

csdxy, fcsd = plt.csd(s1, s2, nfft, 1./dt)
plt.ylabel('CSD (db)')
plt.title('cross spectral density between signal 1 and 2')

Which gives:

enter image description here

Than using the cross-spectral density we can calculate the phase and we can calculate the coherence (which will destroy the phase). Now we can combine the coherence and the peaks that rise above the 95% confidence level

# coherence
cxy, fcoh = cohere(s1, s2, nfft, 1./dt)

# calculate 95% confidence level
edof = (len(s1)/(nfft/2)) * cxy.mean() # equivalent degrees of freedom: (length(timeseries)/windowhalfwidth)*mean_coherence
gamma95 = 1.-(0.05)**(1./(edof-1.))
conf95 = np.where(cxy>gamma95)
print 'gamma95',gamma95, 'edof',edof

# Plot twin plot
fig, ax1 = plt.subplots()
# plot on ax1 the coherence
ax1.plot(fcoh, cxy, 'b-')
ax1.set_xlabel('Frequency (hr-1)')
# Make the y-axis label and tick labels match the line color.
ax1.set_ylabel('Coherence', color='b')
for tl in ax1.get_yticklabels():

# plot on ax2 the phase
ax2 = ax1.twinx()
ax2.plot(fcoh[conf95], phase[conf95], 'r.')
ax2.set_ylabel('Phase (degrees)', color='r')

for tl in ax2.get_yticklabels():

fig.suptitle('Coherence and phase (>95%) between signal 1 and 2', fontsize='12')

result in:

enter image description here

To sum up: the phase of the most coherent peak is ~1 degrees (s1 leads s2) at a 10 min period (assuming dt is a minute measurement) -> (10**-1)/dt

But a specialist signal processing might correct me, because I'm like 60% sure if I've done it right

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