# How do I get a line where the area on each side is equal?

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I need to find a line that splits up the points so that the blue area is equal to the read area. I am doing this to a numpy array that has all of the x and y points in it. I have tried splitting it up and taking the areas of individual parts, but that is proving difficult for how many points I have.

My other idea was put this function on it's side, and integrate that way, and the areas would be equal when the integral is zero, but I can't find a function to let me choose the "x-axis" in that case. Anyone have any advice on how I might go about doing this?

 Original Picture (before the bad color job)

The x-values I am using can be found here and the y-values to go along with those are here

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What format is the data in? (Presumably it's not just a picture...) –  David Robinson Mar 11 at 22:14
it's a numpy array, a rather long, 1D array of floats that I generated from a Gaussian function. –  NightHallow Mar 11 at 22:16
Have you tried bisection search? –  Morgan Wilde Mar 11 at 22:16
Could you show a reproducible example of the array so that we could give it a try? (Otherwise we'll have to generate our own data) –  David Robinson Mar 11 at 22:17
@DavidRobinson I have posted it on pastebin and more info on how to generate it. –  NightHallow Mar 11 at 22:25
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EDIT The code below isn't very good at dealing with generic functions, this other version of `area_difference` is a little more robust. It will still fail if the passed `x0` does not intersect the curve at least twice.

``````def area_difference(x0, x, y) :

transitions = np.where(np.diff(x < x0))[0]

x_ = x[transitions[0]:transitions[-1]]
y_ = y[transitions[0]:transitions[-1]]

return np.sum(np.diff(y_) * (x_[:-1] - x0))
``````

You can get the area if you consider your curve defined as a parametric curve, the index of the array being the parameter. I think the following code is more or less straightforward given that basic idea. I haven't worried too much about getting off-by-one errors right, but any differences should be minor.

``````import numpy as np
import matplotlib.pyplot as plt
import scipy.optimize

x = np.genfromtxt('x.txt')
y = np.genfromtxt('y.txt')

def area_difference(x0, x, y) :

transitions = np.where(np.diff(x < x0))

x_right = x[transitions[0][0]:transitions[0][1]]
y_right = y[transitions[0][0]:transitions[0][1]]

x_left = x[transitions[0][1]:transitions[0][2]]
y_left = y[transitions[0][1]:transitions[0][2]]

return (np.sum(np.diff(y_right) * (x_right[:-1] - x0)) +
np.sum(np.diff(y_left) * (x_left[:-1] - x0)))

x0 = scipy.optimize.fsolve(area_difference, 3, args=(x, y))

plt.plot(x, y, 'b-')
plt.plot([x0, x0], [y.min(), y.max()], 'r-')
plt.show()

>>> x0
array([ 3.4174168])
``````

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You have helped me so much today, but I still have a problem with this. If I decrease the amount of time this function runs for (i.e. the top of this loop will be further to the left), I get IndexErrors that I cannot fix. Or if I use a different function, like a sine wave. Any suggestions there? –  NightHallow Mar 12 at 0:56
@NightHallow I have edited my answer with a more robust version of the `area_difference` function. The key is to have a starting guess for `fsolve` that intersects the curve at least twice. –  Jaime Mar 12 at 1:44