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My question is almost exactly similar to this one. However, I'm not satisfied with the answers, because I want to generate an actual heatmap, without explicitely binning the data.

To be precise, I would like to display the function that is the result of a convolution between the scatter data and a custom kernel, such as 1/x^2.

How should I implement this with matplotlib?

EDIT: Basically, what I have done is this. The result is here. I'd like to keep everything, the axis, the title, the labels and so on. Basically just change the plot to be like I described, while re-implementing as little as possible.

  • 2
    Do you want guidance or the actual code? what have you tried so far? – Trufa Jun 17 '11 at 15:23
  • Have you looked at scipy.stats.gaussian_kde? docs.scipy.org/doc/scipy/reference/generated/… It does exactly what you want. (Though it uses exp(-x) instead of 1/x^2.) You'll need to customize it to use something other than a guassian kernel, but that's not difficult to do. – Joe Kington Jun 18 '11 at 2:18
  • @Trufa: see my edits. – static_rtti Jun 19 '11 at 19:13
  • @Joe Kington: my problem is not really computing the convolution, but rather how to display it into a nice graph. – static_rtti Jun 19 '11 at 19:13
13
+50

Convert your time series data into a numeric format with matplotlib.dats.date2num. Lay down a rectangular grid that spans your x and y ranges and do your convolution on that plot. Make a pseudo-color plot of your convolution and then reformat the x labels to be dates.

The label formatting is a little messy, but reasonably well documented. You just need to replace AutoDateFormatter with DateFormatter and an appropriate formatting string.

You'll need to tweak the constants in the convolution for your data.

import numpy as np
import datetime as dt
import pylab as plt
import matplotlib.dates as dates

t0 = dt.date.today()
t1 = t0+dt.timedelta(days=10)

times = np.linspace(dates.date2num(t0), dates.date2num(t1), 10)
dt = times[-1]-times[0]
price =  100 - (times-times.mean())**2
dp = price.max() - price.min()
volume = np.linspace(1, 100, 10)

tgrid = np.linspace(times.min(), times.max(), 100)
pgrid = np.linspace(70, 110, 100)
tgrid, pgrid = np.meshgrid(tgrid, pgrid)
heat = np.zeros_like(tgrid)

for t,p,v in zip(times, price, volume):
    delt = (t-tgrid)**2
    delp = (p-pgrid)**2
    heat += v/( delt + delp*1.e-2 + 5.e-1 )**2

fig = plt.figure()
ax = fig.add_subplot(111)
ax.pcolormesh(tgrid, pgrid, heat, cmap='gist_heat_r')

plt.scatter(times, price, volume, marker='x')

locator = dates.DayLocator()
ax.xaxis.set_major_locator(locator)
ax.xaxis.set_major_formatter(dates.AutoDateFormatter(locator))
fig.autofmt_xdate()

plt.show()

Script output

  • thanks a lot for your answer! I just have one concern with your answer: how can I keep the nice axis labeling I have in my current version? (see my edits) – static_rtti Jun 19 '11 at 19:12
  • 1
    I would convert your time series data to a numerical representation al la datetime.date.today().toordinal() or matplotlib.dates.date2num(). pcolormesh(). Then figure out how to format the x labels. This last part has me stumped. – matt Jun 20 '11 at 22:25
  • Thanks a lot for your detailed answer! – static_rtti Jun 21 '11 at 8:04

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