So I found a work around but it's a bit of a fudge. This is what it looks like.
Here's the code:
fig, ax = plt.subplots()
fig.canvas.set_window_title("Frame-to-frame pump-to-probe")
plt.xlabel(r'$t/ps$')
plt.ylabel(r'%')
min = 0
for i in range(len(ftf_PtmPlist)):
if ftf_PtmPlist[i] < min:
min = ftf_PtmPlist[i]
if ftf_PtmPlist[i] < 0:
ftf_PtmPlist[i] = 2*ftf_PtmPlist[i]/10.0
for i in range(len(ftf_PttPlist)):
if ftf_PttPlist[i] < min:
min = ftf_PttPlist[i]
if ftf_PttPlist[i] < 0:
ftf_PttPlist[i] = 2*ftf_PttPlist[i]/10.0
lables = [0,20,40,60,80,100]
ymin = int(20*math.floor(min/100.0))
for y in range(ymin,-19,20):
lables.append(y)
lables = sorted(lables)
for i in range(-ymin/20):
lables[i] = str(int(lables[i]*10/2.0))
ax.set_yticklabels(lables)
plt.plot(timelist,ftf_PtmPlist,'magenta', label='pump to main probe efficiency')
plt.plot(timelist,ftf_PttPlist,'teal', label='pump to total probe efficiency')
plt.plot(timelist,p_deplist,'orange', label='pump energy depletion')
plt.gca().set_ylim(top=105)
plt.gca().set_xlim(left=-1.0)
plt.legend(bbox_to_anchor=(0.55, 0.17), loc=2, borderaxespad=0., prop={'size':10})
First I scale all values less than 0 by a factor of 0.2 for the two list which have the possibility for negative values while simultaneously looking for the most negative value overall. I then use this value to find what the most negative tick label should be (given the scaling I'm using) and create a list of new tick labels so the negative values display as the values they had before I scaled them down.
I know it's a bit sloppy but it does the job!
log
scale is the only way I can think of!this graph
in your OP and also to add a minimal example of the code you are currently using to plot your graph.