# Cutting of unused frequencies in specgram matplotlib

I have a signal with sampling rate 16e3, its frequency range is from 125 to 1000 Hz. So if i plot a specgram i get a pretty small colorrange because of all the unused frequencys.

ive tried to fix it with setting ax limits but that does not work.

is there any way to cut off unused frequencys or replace them with NaNs?

Resampling the Data to 2e3 won't work because there are still some not used frequencys below 125 Hz.

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Did you try setting the scale_by_freq argument to False? –  wwii Oct 19 '13 at 17:38
yes, that didn't change anything. –  Masti Tafri Oct 19 '13 at 17:44
I'm just looking through the docs ... maybe use http://matplotlib.org/api/colors_api.html#matplotlib.colors.Normalize with the cmap argument. –  wwii Oct 19 '13 at 17:50
I think that could work if i had static data, unfortunately i have to plot several specgrams. Isnt there some way to just directly edit the plot details? and erasing the unused data? Or to get the highest value to dynamicly set the cmap values? –  Masti Tafri Oct 19 '13 at 18:23

specgram() is doing all the work for you. If you look in axes.py at the specgram function you can see how it works.

``````    <snip>
Pxx, freqs, bins = mlab.specgram(x, NFFT, Fs, detrend,

Z = 10. * np.log10(Pxx)
Z = np.flipud(Z)

if xextent is None: xextent = 0, np.amax(bins)
xmin, xmax = xextent
freqs += Fc
extent = xmin, xmax, freqs[0], freqs[-1]
im = self.imshow(Z, cmap, extent=extent, **kwargs)
self.axis('auto')

return Pxx, freqs, bins, im
``````

You might have to make your own function modeled on this and clip the Pxx data to suit your needs.

``````    Pxx, freqs, bins = mlab.specgram(x, NFFT, Fs, detrend,
# ****************
# create a new limited Pxx and freqs
#
# ****************
Z = 10. * np.log10(Pxx)
Z = np.flipud(Z)
``````

Pxx is a 2d array with a shape of (len(freqs),len(bins)

``````>>> Pxx.shape
(129, 311)
>>> freqs.shape
(129,)
>>> bins.shape
(311,)
>>>
``````

This will limit Pxx and freqs

``````Pxx = Pxx[(freqs >= 125) & (freqs <= 1000)]
freqs = freqs[(freqs >= 125) & (freqs <= 1000)]
``````

Here is a complete solution - my_specgram() - used with the specgram_demo from the gallery.

``````from pylab import *
from matplotlib import *

# 100, 400 and 200 Hz sine 'wave'
dt = 0.0005
t = arange(0.0, 20.0, dt)
s1 = sin(2*pi*100*t)
s2 = 2*sin(2*pi*400*t)
s3 = 2*sin(2*pi*200*t)

# create a transient "chirp"
mask = where(logical_and(t>10, t<12), 1.0, 0.0)

# add some noise into the mix
nse = 0.01*randn(len(t))

x = s1 + s2 + +s3 + nse # the signal
NFFT = 1024       # the length of the windowing segments
Fs = int(1.0/dt)  # the sampling frequency

# modified specgram()
def my_specgram(x, NFFT=256, Fs=2, Fc=0, detrend=mlab.detrend_none,
window=mlab.window_hanning, noverlap=128,
scale_by_freq=None, minfreq = None, maxfreq = None, **kwargs):
"""
call signature::

specgram(x, NFFT=256, Fs=2, Fc=0, detrend=mlab.detrend_none,
window=mlab.window_hanning, noverlap=128,
scale_by_freq=None, minfreq = None, maxfreq = None, **kwargs)

Compute a spectrogram of data in *x*.  Data are split into
*NFFT* length segments and the PSD of each section is
computed.  The windowing function *window* is applied to each
segment, and the amount of overlap of each segment is
specified with *noverlap*.

%(PSD)s

*Fc*: integer
The center frequency of *x* (defaults to 0), which offsets
the y extents of the plot to reflect the frequency range used
when a signal is acquired and then filtered and downsampled to
baseband.

*cmap*:
A :class:`matplotlib.cm.Colormap` instance; if *None* use
default determined by rc

*xextent*:
The image extent along the x-axis. xextent = (xmin,xmax)
The default is (0,max(bins)), where bins is the return
value from :func:`mlab.specgram`

*minfreq, maxfreq*
Limits y-axis. Both required

*kwargs*:

Additional kwargs are passed on to imshow which makes the
specgram image

Return value is (*Pxx*, *freqs*, *bins*, *im*):

- *bins* are the time points the spectrogram is calculated over
- *freqs* is an array of frequencies
- *Pxx* is a len(times) x len(freqs) array of power
- *im* is a :class:`matplotlib.image.AxesImage` instance

Note: If *x* is real (i.e. non-complex), only the positive
spectrum is shown.  If *x* is complex, both positive and
negative parts of the spectrum are shown.  This can be
overridden using the *sides* keyword argument.

**Example:**

.. plot:: mpl_examples/pylab_examples/specgram_demo.py

"""

#####################################
# modified  axes.specgram() to limit
# the frequencies plotted
#####################################

# this will fail if there isn't a current axis in the global scope
ax = gca()
Pxx, freqs, bins = mlab.specgram(x, NFFT, Fs, detrend,

# modified here
#####################################
if minfreq is not None and maxfreq is not None:
Pxx = Pxx[(freqs >= minfreq) & (freqs <= maxfreq)]
freqs = freqs[(freqs >= minfreq) & (freqs <= maxfreq)]
#####################################

Z = 10. * np.log10(Pxx)
Z = np.flipud(Z)

if xextent is None: xextent = 0, np.amax(bins)
xmin, xmax = xextent
freqs += Fc
extent = xmin, xmax, freqs[0], freqs[-1]
im = ax.imshow(Z, cmap, extent=extent, **kwargs)
ax.axis('auto')

return Pxx, freqs, bins, im

# plot
ax1 = subplot(211)
plot(t, x)
subplot(212, sharex=ax1)

# the minfreq and maxfreq args will limit the frequencies
Pxx, freqs, bins, im = my_specgram(x, NFFT=NFFT, Fs=Fs, noverlap=900,
cmap=cm.Accent, minfreq = 180, maxfreq = 220)
show()
close()
``````
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thanks alot. would upvote if i had enough reputation. –  Masti Tafri Oct 19 '13 at 21:01
I added my_specgram() which I think does what you need. –  wwii Oct 19 '13 at 23:16
now you should have enough reputation to give that upvote ;-) –  user7610 Jan 6 at 18:44

specgram() returns (Pxx, freqs, bins, im), where im is AxesImage instance [1]. You could use it to set the limits of your plot:

``````Pxx, freqs, bins, im = plt.specgram(signal, Fs=fs)
im.set_ylim((125,1000))
``````
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