# Finding the intersection of a curve from polyfit

This seems simple but I can't quite figure it out. I have a curve calculated from x,y data. Then I have a line. I want to find the x, y values for where the two intersect.

Here is what I've got so far. It's super confusing and doesn't give the correct result. I can look at the graph and find the intersection x value and calculate the correct y value. I'd like to remove this human step.

``````import numpy as np
import matplotlib.pyplot as plt
from pylab import *
from scipy import linalg
import sys
import scipy.interpolate as interpolate
import scipy.optimize as optimize

w = np.array([0.0, 11.11111111111111, 22.22222222222222, 33.333333333333336, 44.44444444444444, 55.55555555555556, 66.66666666666667, 77.77777777777777, 88.88888888888889, 100.0])
v = np.array([0.0, 8.333333333333332, 16.666666666666664, 25.0, 36.11111111111111, 47.22222222222222, 58.333333333333336, 72.22222222222221, 86.11111111111111, 100.0])

z = np.polyfit(w, v, 2)
print (z)
p=np.poly1d(z)
g = np.polyval(z,w)
print (g)
N=100
a=arange(N)
b=(w,v)
b=np.array(b)
c=(w,g)
c=np.array(c)
print(c)
d=-a+99
e=(a,d)
print (e)
p1=interpolate.PiecewisePolynomial(w,v[:,np.newaxis])
p2=interpolate.PiecewisePolynomial(w,d[:,np.newaxis])

def pdiff(x):
return p1(x)-p2(x)

xs=np.r_[w,w]
xs.sort()
x_min=xs.min()
x_max=xs.max()
x_mid=xs[:-1]+np.diff(xs)/2
roots=set()
for val in x_mid:
root,infodict,ier,mesg = optimize.fsolve(pdiff,val,full_output=True)
# ier==1 indicates a root has been found
if ier==1 and x_min<root<x_max:
roots=list(roots)
print(np.column_stack((roots,p1(roots),p2(roots))))

plt.plot(w,v, 'r', a, -a+99, 'b-')
plt.show()
q=input("what is the intersection value? ")
print (p(q))
``````

Any ideas to get this to work?

Thanks

-

I don't think I fully understand what you are trying to do in your code, but what you described in English can be done with

``````from __future__ import division
import numpy as np
import matplotlib.pyplot as plt

w = np.array([0.0, 11.11111111111111, 22.22222222222222, 33.333333333333336,
44.44444444444444, 55.55555555555556, 66.66666666666667,
77.77777777777777, 88.88888888888889, 100.0])
v = np.array([0.0, 8.333333333333332, 16.666666666666664, 25.0,
36.11111111111111, 47.22222222222222, 58.333333333333336,
72.22222222222221, 86.11111111111111, 100.0])

poly_coeff = np.polynomial.polynomial.polyfit(w, v, 2)
poly = np.polynomial.polynomial.Polynomial(poly_coeff)
roots = np.polynomial.polynomial.polyroots(poly_coeff - [99, -1, 0])

x = np.linspace(np.min(roots) - 50, np.max(roots) + 50, num=1000)
plt.plot(x, poly(x), 'r-')
plt.plot(x, 99 - x, 'b-')
for root in roots:
plt.plot(root, 99 - root, 'ro')
``````

-
Fair warning, `np.polynomial.polynomial.polyfit` returns coefficients `[A, B, C]` to `A + Bx + Cx^2 + ...`, which is the opposite order from what `np.polyfit` (what you had originally used, @user2843767) returns: `... + Ax^2 + Bx + C`. Not sure who made that decision, just don't take the first output and use it in `np.poly1d` or np.polyval, unless you use `np.polyfit` as well. – askewchan Oct 7 '13 at 13:04
Fair warning indeed. There is no deprecation warning, and there may never be, but the docs are clear that the way to go for new code is the Polynomial package, not the older poly1d. – Jaime Oct 7 '13 at 14:13
Yes, and fortunately the new(er) package has the more standard ordering as well. Thanks for pointing out that link though, I'll be sure to advise only the polynomial package. – askewchan Oct 7 '13 at 14:16
Sorry for the confusion. Also sorry for the messy code, I'd tried like a dozen things and I think there was a bunch of lingering lines from that. The code I submitted actually works, I just need to not use the same x values for both line, changing xs=np.r_[w,w] to xs=np.r_[w,a] fixes it. But this method is slow. I will try the Polynomial package. Thanks. – user2843767 Oct 7 '13 at 20:42