# Adaptive plotting of a function in python

A simple question: I have a function f(t) that is supposed to have some sharp peak at some point on [0,1]. A natural idea is to use adaptive sampling of this function to get a nice "adaptive" plot. How can I do that in a fast way in Python + matplotlib + numpy + whatever? I can compute f(t) for any t on [0,1].

It seems that Mathematica has this option, does the Python have one?

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What have you tried? –  tcaswell Dec 29 '12 at 18:31
Just a simplest `linspace` solution –  Ivan Oseledets Dec 29 '12 at 18:31

Look what I found: Adaptive sampling of 1D functions, the link from scipy-central.org.

The code is:

``````# License: Creative Commons Zero (almost public domain) http://scpyce.org/cc0

import numpy as np

def sample_function(func, points, tol=0.05, min_points=16, max_level=16,
sample_transform=None):
"""
Sample a 1D function to given tolerance by adaptive subdivision.

The result of sampling is a set of points that, if plotted,
produces a smooth curve with also sharp features of the function
resolved.

Parameters
----------
func : callable
Function func(x) of a single argument. It is assumed to be vectorized.
points : array-like, 1D
Initial points to sample, sorted in ascending order.
These will determine also the bounds of sampling.
tol : float, optional
Tolerance to sample to. The condition is roughly that the total
length of the curve on the (x, y) plane is computed up to this
tolerance.
min_point : int, optional
Minimum number of points to sample.
max_level : int, optional
Maximum subdivision depth.
sample_transform : callable, optional
Function w = g(x, y). The x-samples are generated so that w
is sampled.

Returns
-------
x : ndarray
X-coordinates
y : ndarray
Corresponding values of func(x)

Notes
-----
This routine is useful in computing functions that are expensive
to compute, and have sharp features --- it makes more sense to
adaptively dedicate more sampling points for the sharp features
than the smooth parts.

Examples
--------
>>> def func(x):
...     '''Function with a sharp peak on a smooth background'''
...     a = 0.001
...     return x + a**2/(a**2 + x**2)
...
>>> x, y = sample_function(func, [-1, 1], tol=1e-3)

>>> import matplotlib.pyplot as plt
>>> xx = np.linspace(-1, 1, 12000)
>>> plt.plot(xx, func(xx), '-', x, y[0], '.')
>>> plt.show()

"""
return _sample_function(func, points, values=None, mask=None, depth=0,
tol=tol, min_points=min_points, max_level=max_level,
sample_transform=sample_transform)

def _sample_function(func, points, values=None, mask=None, tol=0.05,
depth=0, min_points=16, max_level=16,
sample_transform=None):
points = np.asarray(points)

if values is None:
values = np.atleast_2d(func(points))

if mask is None:

if depth > max_level:
# recursion limit
return points, values

x_c = .5*(x_a + x_b)
y_c = np.atleast_2d(func(x_c))

x_2 = np.r_[points, x_c]
y_2 = np.r_['-1', values, y_c]
j = np.argsort(x_2)

x_2 = x_2[...,j]
y_2 = y_2[...,j]

# -- Determine the intervals at which refinement is necessary

if len(x_2) < min_points:
mask = np.ones([len(x_2)-1], dtype=bool)
else:
# represent the data as a path in N dimensions (scaled to unit box)
if sample_transform is not None:
y_2_val = sample_transform(x_2, y_2)
else:
y_2_val = y_2

p = np.r_['0',
x_2[None,:],
y_2_val.real.reshape(-1, y_2_val.shape[-1]),
y_2_val.imag.reshape(-1, y_2_val.shape[-1])
]

sz = (p.shape[0]-1)//2

xscale = x_2.ptp(axis=-1)
yscale = abs(y_2_val.ptp(axis=-1)).ravel()

p[0] /= xscale
p[1:sz+1] /= yscale[:,None]
p[sz+1:]  /= yscale[:,None]

# compute the length of each line segment in the path
dp = np.diff(p, axis=-1)
s = np.sqrt((dp**2).sum(axis=0))
s_tot = s.sum()

# compute the angle between consecutive line segments
dp /= s
dcos = np.arccos(np.clip((dp[:,1:] * dp[:,:-1]).sum(axis=0), -1, 1))

# determine where to subdivide: the condition is roughly that
# the total length of the path (in the scaled data) is computed
# to accuracy `tol`
dp_piece = dcos * .5*(s[1:] + s[:-1])
mask = (dp_piece > tol * s_tot)

# -- Refine, if necessary

return _sample_function(func, x_2, y_2, mask, tol=tol, depth=depth+1,
min_points=min_points, max_level=max_level,
sample_transform=sample_transform)
else:
return x_2, y_2
``````
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The one I needed! Thanks –  Ivan Oseledets Dec 29 '12 at 19:41

For plotting purposes, there isn't much need for adaptive sampling. Why not just sample at or above the screen resolution?

``````POINTS=1920

from pylab import *
x = arange(0,1,1.0/POINTS)
y = sin(3.14*x)
plot(x,y)
axes().set_aspect('equal') ## optional aspect-ratio control
show()
``````
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I agree to some extent, but it is always desirable to compute a few of function values to reduce the plotting time. In my case the function is also quite slow (around 10 seconds for one point). –  Ivan Oseledets Jan 1 '13 at 8:02
How to "vectorize" an arbitrary function: stackoverflow.com/questions/8036878/… –  nobar Jun 25 '13 at 21:44