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I'm trying to count given data points inside each ring of ellipse:

enter image description here

The problem is that I have a function to check that: so for each ellipse, to make sure whether a point is in it, three inputs have to be calculated:

def get_focal_point(r1,r2,center_x):
    # f = square root of r1-squared - r2-squared
    focal_dist = sqrt((r1**2) - (r2**2))
    f1_x = center_x - focal_dist
    f2_x = center_x + focal_dist
    return f1_x, f2_x

def get_distance(f1,f2,center_y,t_x,t_y):
    d1 = sqrt(((f1-t_x)**2) + ((center_y - t_y)**2)) 
    d2 = sqrt(((f2-t_x)**2) + ((center_y - t_y)**2))
    return d1,d2

def in_ellipse(major_ax,d1,d2):
    if (d1+d2) <= 2*major_ax:
        return True
    else:
        return False

Right now I'm checking whether or not it's in an ellipse by:

for i in range(len(data.latitude)):
    t_x = data.latitude[i] 
    t_y = data.longitude[i] 
    d1,d2 = get_distance(f1,f2,center_y,t_x,t_y)
    d1_array.append(d1)
    d2_array.append(d2)
    if in_ellipse(major_ax,d1,d2) == True:
        core_count += 1
        # if the point is not in core ellipse 
        # check the next ring up
    else:
        for i in range(loop):
            .....

But I would then have to calculate each pairs of focal points of the outside loops.. is there any more efficient and or clever way to do this?

Thanks so much!

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Am I right that these ellipses have the same proportions and center? If so, you can identify them by eg. r1 and create a function that for each point assigns minimum r1 for which the point is in the ellipsis. Am I right or I just have misunderstood something? –  Tadeck Nov 18 '11 at 19:48
    
Are the ellipses concentric and do they vary in size by a fixed ratio (they look like they do)? If so, you should be able to tell where a point falls with something like dist_to_point / size_per_ellipse. –  g.d.d.c Nov 18 '11 at 20:01
    
Yes, they are concentric! but the dist_to_point/size_per_ellipse would that not only work for circles? –  Florie Nov 18 '11 at 20:30
    
@g.d.d.c: This is similar to what I believe I said, except the distance to point is not what will tell you for sure when it falls - the more important is the pair of " latitude " and " longitude ", as these ellipses are not circles. –  Tadeck Nov 18 '11 at 20:31
    
Exactly! @g.d.d.c's solution will only work for circles in my opinion. –  Tadeck Nov 18 '11 at 20:32
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3 Answers 3

up vote 8 down vote accepted

This may be something similar to what you are doing. I'm just looking to see if f(x,y) = x^2/r1^2 + y^2/r2^2 = 1.

When f(x,y) is larger than 1, the point x,y is outside the ellipse. When it is smaller, then it is inside the ellipse. I loop through each ellipse to find the one when f(x,y) is smaller than 1.

The code also does not take into account an ellipse that is centered off the origin. It's a small change to include this feature.

import matplotlib.pyplot as plt
import matplotlib.patches as patches
import numpy as np

def inWhichEllipse(x,y,rads):
    '''
    With a list of (r1,r2) pairs, rads, return the index of the pair in which
    the point x,y resides. Return None as the index if it is outside all 
    Ellipses.
    '''
    xx = x*x
    yy = y*y

    count = 0
    ithEllipse =0
    while True:
        rx,ry = rads[count]
        ellips = xx/(rx*rx)+yy/(ry*ry)
        if ellips < 1:
            ithEllipse = count
            break
        count+=1
        if count >= len(rads):
            ithEllipse = None
            break

    return ithEllipse

rads = zip(np.arange(.5,10,.5),np.arange(.125,2.5,.25))

fig = plt.figure()
ax = fig.add_subplot(111)
ax.set_xlim(-15,15)
ax.set_ylim(-15,15)

# plot Ellipses
for rx,ry in rads:
    ellipse = patches.Ellipse((0,0),rx*2,ry*2,fc='none',ec='red')    
    ax.add_patch(ellipse)

x=3.0
y=1.0
idx = inWhichEllipse(x,y,rads)
rx,ry = rads[idx]
ellipse = patches.Ellipse((0,0),rx*2,ry*2,fc='none',ec='blue')    
ax.add_patch(ellipse)

if idx != None:
    circle = patches.Circle((x,y),.1)
    ax.add_patch(circle)

plt.show()

This code produces the following figure: enter image description here

Keep in mind, this is just a starting point. For one thing, you can change inWhichEllipse to accept a list of the square of r1 and r2, ie (r1*r1,r2*r2) pairs, and that would cut the computation down even more.

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You complicate things. It is no need to compute focal points and the distances to the focal points etc. according to the geometric definition of ellipse. If you know major and minor axis (you do), just squeeze the whole question a bit (so that both are 1.0, for example, by dividing x-centerx and y-centery by xaxis and yaxis) and then the question whether the point is inside ellipse is simply

xnormalized**2 + ynormalized**2 <= 1

P.S.: In general, good advice in this field: no sqrt if you can do the same thing by not actually compute a distance but staying comfortably in the realm of its square.

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+1 I think @herby expressed this much better than I did. The problem can be simplified considerably. –  Raymond Hettinger Nov 18 '11 at 21:00
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Here are a few ideas for you:

  • You've got the right idea moving the code for computing the foci outside of the loop.
  • The distance calculations can be sped-up by removing the square roots. In other words, we know a < b implies sqrt(a) < sqrt(b) so there is no need to calculate the square root.
  • If the ellipses are concentric and the major axis is parallel to the x-axis, you can simplify the ellipse problem to a circle problem by rescaling the x value.

Also, here's one minor coding nit. There is no need for an if-statement to return True or False. Instead, you can return the conditional expression itself:

def in_ellipse(major_ax,d1,d2):
    return (d1+d2) <= 2*major_ax:
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Thank you so much that's very helpful. Though the major axis is not always the x-axis...I will be doing this in a loop for many sets of data so the major axis is not necessarily the x-axis. –  Florie Nov 18 '11 at 20:32
    
If the axis goes through the original, you can still rotate and scale the ellipse problem into a circle problem using a single complex number multiply. Also, if the x,y are represented as a complex number the distance calculation simplifies to abs(p). –  Raymond Hettinger Nov 18 '11 at 20:38
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