I created a method to align the ticks of multiple y- axes (could be more than 2), with possibly different scales in different axes.

Below is an example figure:

There are 3 y- axes, one blue on the left, and a green and a red on the right. The 3 curves are plotted onto the y-axis with the corresponding color. Note that they all have very different order of magnitudes.

**Left plot**: No alignment.
**Mid plot**: Aligned at (approximately) the lower bound of each y axis.
**Right plot**: Aligned at specified values: `0`

for blue, `2.2*1e8`

for red, and `44`

for green. Those are chosen arbitrarily.

What I'm doing is to scale each y array to be within the range of 1-100, then merge all scaled y-values into a single array, from which a new set of ticks is created using `MaxNLocator`

. Then this new set of ticks is scaled back using the corresponding scaling factor to get the new ticks for each axis. If some specific alignment is required, y arrays are shifted before scaling, and shifted back afterwards.

Complete code here (the key function is `alignYaxes()`

):

```
import matplotlib.pyplot as plt
import numpy as np
def make_patch_spines_invisible(ax):
'''Used for creating a 2nd twin-x axis on the right/left
E.g.
fig, ax=plt.subplots()
ax.plot(x, y)
tax1=ax.twinx()
tax1.plot(x, y1)
tax2=ax.twinx()
tax2.spines['right'].set_position(('axes',1.09))
make_patch_spines_invisible(tax2)
tax2.spines['right'].set_visible(True)
tax2.plot(x, y2)
'''
ax.set_frame_on(True)
ax.patch.set_visible(False)
for sp in ax.spines.values():
sp.set_visible(False)
def alignYaxes(axes, align_values=None):
'''Align the ticks of multiple y axes
Args:
axes (list): list of axes objects whose yaxis ticks are to be aligned.
Keyword Args:
align_values (None or list/tuple): if not None, should be a list/tuple
of floats with same length as <axes>. Values in <align_values>
define where the corresponding axes should be aligned up. E.g.
[0, 100, -22.5] means the 0 in axes[0], 100 in axes[1] and -22.5
in axes[2] would be aligned up. If None, align (approximately)
the lowest ticks in all axes.
Returns:
new_ticks (list): a list of new ticks for each axis in <axes>.
A new sets of ticks are computed for each axis in <axes> but with equal
length.
'''
from matplotlib.pyplot import MaxNLocator
nax=len(axes)
ticks=[aii.get_yticks() for aii in axes]
if align_values is None:
aligns=[ticks[ii][0] for ii in range(nax)]
else:
if len(align_values) != nax:
raise Exception("Length of <axes> doesn't equal that of <align_values>.")
aligns=align_values
bounds=[aii.get_ylim() for aii in axes]
# align at some points
ticks_align=[ticks[ii]-aligns[ii] for ii in range(nax)]
# scale the range to 1-100
ranges=[tii[-1]-tii[0] for tii in ticks]
lgs=[-np.log10(rii)+2. for rii in ranges]
igs=[np.floor(ii) for ii in lgs]
log_ticks=[ticks_align[ii]*(10.**igs[ii]) for ii in range(nax)]
# put all axes ticks into a single array, then compute new ticks for all
comb_ticks=np.concatenate(log_ticks)
comb_ticks.sort()
locator=MaxNLocator(nbins='auto', steps=[1, 2, 2.5, 3, 4, 5, 8, 10])
new_ticks=locator.tick_values(comb_ticks[0], comb_ticks[-1])
new_ticks=[new_ticks/10.**igs[ii] for ii in range(nax)]
new_ticks=[new_ticks[ii]+aligns[ii] for ii in range(nax)]
# find the lower bound
idx_l=0
for i in range(len(new_ticks[0])):
if any([new_ticks[jj][i] > bounds[jj][0] for jj in range(nax)]):
idx_l=i-1
break
# find the upper bound
idx_r=0
for i in range(len(new_ticks[0])):
if all([new_ticks[jj][i] > bounds[jj][1] for jj in range(nax)]):
idx_r=i
break
# trim tick lists by bounds
new_ticks=[tii[idx_l:idx_r+1] for tii in new_ticks]
# set ticks for each axis
for axii, tii in zip(axes, new_ticks):
axii.set_yticks(tii)
return new_ticks
def plotLines(x, y1, y2, y3, ax):
ax.plot(x, y1, 'b-')
ax.tick_params('y',colors='b')
tax1=ax.twinx()
tax1.plot(x, y2, 'r-')
tax1.tick_params('y',colors='r')
tax2=ax.twinx()
tax2.spines['right'].set_position(('axes',1.2))
make_patch_spines_invisible(tax2)
tax2.spines['right'].set_visible(True)
tax2.plot(x, y3, 'g-')
tax2.tick_params('y',colors='g')
ax.grid(True, axis='both')
return ax, tax1, tax2
#-------------Main---------------------------------
if __name__=='__main__':
# craft some data to plot
x=np.arange(20)
y1=np.sin(x)
y2=x/1000+np.exp(x)
y3=x+x**2/3.14
figure=plt.figure(figsize=(12,4),dpi=100)
ax1=figure.add_subplot(1, 3, 1)
axes1=plotLines(x, y1, y2, y3, ax1)
ax1.set_title('No alignment')
ax2=figure.add_subplot(1, 3, 2)
axes2=plotLines(x, y1, y2, y3, ax2)
alignYaxes(axes2)
ax2.set_title('Default alignment')
ax3=figure.add_subplot(1, 3, 3)
axes3=plotLines(x, y1, y2, y3, ax3)
alignYaxes(axes3, [0, 2.2*1e8, 44])
ax3.set_title('Specified alignment')
figure.tight_layout()
figure.show()
```

`ax2.set_ylim((10, 20))`

? – farenorth Nov 5 '14 at 13:18