# python/matplotlib - parasite twin axis scaling

Trying to plot a spectrum, ie, velocity versus intensity, with lower x axis = velocity, on the upper twin axis = frequency

The relationship between them (doppler formula) is

``````f = (1-v/c)*f_0
``````

where f is the resulting frequency, v the velocity, c the speed of light, and f_0 the frequency at v=0, ie. the v_lsr.

I have tried to solve it by looking at http://matplotlib.sourceforge.net/examples/axes_grid/parasite_simple2.html , where it is solved by

``````pm_to_kms = 1./206265.*2300*3.085e18/3.15e7/1.e5
aux_trans = matplotlib.transforms.Affine2D().scale(pm_to_kms, 1.)
ax_pm = ax_kms.twin(aux_trans)
ax_pm.set_viewlim_mode("transform")
``````

my problem is, how do I replace the pm_to_kms with my function for frequency?

Anyone know how to solve this?

The solution I ended up using was:

``````ax_hz = ax_kms.twiny()
x_1, x_2 = ax_kms.get_xlim()
# i want the frequency in GHz so, divide by 1e9
ax_hz.set_xlim(calc_frequency(x_1,data.restfreq/1e9),calc_frequency(x_2,data.restfreq/1e9))
``````

This works perfect, and much less complicated solution.

EDIT : Found a very fancy answer. EDIT2 : Changed the transform call according to the comment by @u55

This basically involves defining our own conversion/transform. Because of the excellent AstroPy Units equivalencies, it becomes even easier to understand and more illustrative.

``````from matplotlib import transforms as mtransforms
import astropy.constants as co
import astropy.units as un
import numpy as np
import matplotlib.pyplot as plt
plt.style.use('ggplot')
from mpl_toolkits.axes_grid.parasite_axes import SubplotHost

class Freq2WavelengthTransform(mtransforms.Transform):
input_dims = 1
output_dims = 1
is_separable = False
has_inverse = True

def __init__(self):
mtransforms.Transform.__init__(self)

def transform_non_affine(self, fr):
return (fr*un.GHz).to(un.mm, equivalencies=un.spectral()).value

def inverted(self):
return Wavelength2FreqTransform()

class Wavelength2FreqTransform(Freq2WavelengthTransform):
input_dims = 1
output_dims = 1
is_separable = False
has_inverse = True

def __init__(self):
mtransforms.Transform.__init__(self)

def transform_non_affine(self, wl):
return (wl*un.mm).to(un.GHz, equivalencies=un.spectral()).value

def inverted(self):
return Freq2WavelengthTransform()

aux_trans = mtransforms.BlendedGenericTransform(Wavelength2FreqTransform(), mtransforms.IdentityTransform())

fig = plt.figure(2)

ax_GHz = SubplotHost(fig, 1,1,1)
ax_GHz.set_xlabel("Frequency (GHz)")

xvals = np.arange(199.9, 999.9, 0.1)

# data, noise + Gaussian (spectral) lines
data = np.random.randn(len(xvals))*0.01 + np.exp(-(xvals-300.)**2/100.)*0.5 + np.exp(-(xvals-600.)**2/400.)*0.5

ax_mm = ax_GHz.twin(aux_trans)
ax_mm.set_xlabel('Wavelength (mm)')
ax_mm.set_viewlim_mode("transform")
ax_mm.axis["right"].toggle(ticklabels=False)

ax_GHz.plot(xvals, data)
ax_GHz.set_xlim(200, 1000)

plt.draw()
plt.show()
``````

This now produces the desired results:

• This happened to work correctly, by chance, because the conversion equation between frequency and wavelength (νλ = c) is symmetric with respect to exchange of frequency and wavelength. However, for general transforms, this will give incorrect results. You should replace `Freq2WavelengthTransform()` with `Wavelength2FreqTransform()` in the line: `aux_trans = mtransforms.BlendedGenericTransform(Freq2WavelengthTransform(), mtransforms.IdentityTransform())`.
– u55
Oct 13 '16 at 6:03

Your "linear function" is a "simple scaling law" (with an offset). Just replace the `pm_to_kms` definition with your function.

• well yes... so you mean that I do two transforms, one scaling and one translation? like kms_to_deltafreq = -f0/c deltafreq_to_freq = f0 matplotlib.transforms.Affine2D().scale(kms_to_deltafreq, 1.).translate(deltafreq_to_freq,1) ax_freq = ax_kms.twin(aux_trans) ax_freq.set_viewlim_mode("transform") ?? Jul 2 '10 at 10:56
• So an answer for now exists here : matplotlib.1069221.n5.nabble.com/… if time permits, I will write a proper one here. Feb 17 '15 at 12:57