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I have a bunch of cross plots with two sets of data and have been looking for a matploltib way of highlighting their plotted regions with smoothed polygon outlines.

At the moment i just use Adobe Illustrator and amend saved plot, but this is not ideal. Example:enter image description here

I'd be grateful for any pointers/links to examples.


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See matplotlib.org/users/path_tutorial.html There might be a friendlier way, but that way works. –  tcaswell Jul 9 '13 at 18:35

1 Answer 1

up vote 4 down vote accepted

Here, you have an example. I was written the main ideas, but obviously, you could do it better.

A short explanations:

1) You need to compute the convex-hull (http://en.wikipedia.org/wiki/Convex_hull)

2) With the hull, you could scale it to keep all your data inside.

3) You must to interpolate the resulting curve.

The first part was done in http://wiki.scipy.org/Cookbook/Finding_Convex_Hull. The second one is trivial. The third one is very general, and you could perform any method, there are a lot of different ways to do the same. I took the @Jaime's approach (numpy/scipy: smooth spline representation of an arbitrary contour, f(length) --> x,y), which I think it's a very good method.

I hope it help you...

#Taken from http://wiki.scipy.org/Cookbook/Finding_Convex_Hull

import numpy as n, pylab as p, time

def _angle_to_point(point, centre):
    '''calculate angle in 2-D between points and x axis'''
    delta = point - centre
    res = n.arctan(delta[1] / delta[0])
    if delta[0] < 0:
        res += n.pi
    return res

def _draw_triangle(p1, p2, p3, **kwargs):
    tmp = n.vstack((p1,p2,p3))
    x,y = [x[0] for x in zip(tmp.transpose())]
    p.fill(x,y, **kwargs)

def area_of_triangle(p1, p2, p3):
    '''calculate area of any triangle given co-ordinates of the corners'''
    return n.linalg.norm(n.cross((p2 - p1), (p3 - p1)))/2.

def convex_hull(points, graphic=False, smidgen=0.0075):
    Calculate subset of points that make a convex hull around points
    Recursively eliminates points that lie inside two neighbouring points until only convex hull is remaining.

    points : ndarray (2 x m)
    array of points for which to find hull
    graphic : bool
    use pylab to show progress?
    smidgen : float
    offset for graphic number labels - useful values depend on your data range

    hull_points : ndarray (2 x n)
    convex hull surrounding points

    if graphic:
        p.plot(points[0], points[1], 'ro')
    n_pts = points.shape[1]
    assert(n_pts > 5)
    centre = points.mean(1)
    if graphic: p.plot((centre[0],),(centre[1],),'bo')
    angles = n.apply_along_axis(_angle_to_point, 0, points, centre)
    pts_ord = points[:,angles.argsort()]
    if graphic:
        for i in xrange(n_pts):
            p.text(pts_ord[0,i] + smidgen, pts_ord[1,i] + smidgen, \
                   '%d' % i)
    pts = [x[0] for x in zip(pts_ord.transpose())]
    prev_pts = len(pts) + 1
    k = 0
    while prev_pts > n_pts:
        prev_pts = n_pts
        n_pts = len(pts)
        if graphic: p.gca().patches = []
        i = -2
        while i < (n_pts - 2):
            Aij = area_of_triangle(centre, pts[i],     pts[(i + 1) % n_pts])
            Ajk = area_of_triangle(centre, pts[(i + 1) % n_pts], \
                                   pts[(i + 2) % n_pts])
            Aik = area_of_triangle(centre, pts[i],     pts[(i + 2) % n_pts])
            if graphic:
                _draw_triangle(centre, pts[i], pts[(i + 1) % n_pts], \
                               facecolor='blue', alpha = 0.2)
                _draw_triangle(centre, pts[(i + 1) % n_pts], \
                               pts[(i + 2) % n_pts], \
                               facecolor='green', alpha = 0.2)
                _draw_triangle(centre, pts[i], pts[(i + 2) % n_pts], \
                               facecolor='red', alpha = 0.2)
            if Aij + Ajk < Aik:
                if graphic: p.plot((pts[i + 1][0],),(pts[i + 1][1],),'go')
                del pts[i+1]
            i += 1
            n_pts = len(pts)
        k += 1
    return n.asarray(pts)

if __name__ == "__main__":

    import scipy.interpolate as interpolate

#    fig = p.figure(figsize=(10,10))

    theta = 2*n.pi*n.random.rand(1000)
    r = n.random.rand(1000)**0.5
    x,y = r*p.cos(theta),r*p.sin(theta)

    points = n.ndarray((2,len(x)))
    points[0,:],points[1,:] = x,y

    scale = 1.03
    hull_pts = scale*convex_hull(points)


    x,y = [],[]
    convex = scale*hull_pts
    for point in convex:

    x,y = n.array(x),n.array(y)

#Taken from http://stackoverflow.com/questions/14344099/numpy-scipy-smooth-spline-representation-of-an-arbitrary-contour-flength
    nt = n.linspace(0, 1, 100)
    t = n.zeros(x.shape)
    t[1:] = n.sqrt((x[1:] - x[:-1])**2 + (y[1:] - y[:-1])**2)
    t = n.cumsum(t)
    t /= t[-1]
    x2 = interpolate.spline(t, x, nt)
    y2 = interpolate.spline(t, y, nt)
    p.plot(x2, y2,'r--',linewidth=2)


enter image description here

There are some useful papers, eg.:


Also, you could try with: http://resources.arcgis.com/en/help/main/10.1/index.html#//007000000013000000

I don't know nothing about arcgis, but it looks fine.

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