# Common tangent function

I have an interesting problem in Python where I have two functions (arbitrary), and I'd like to find the common tangent between them, and the points on the x-axis where the common tangent touches each function. Ideally there would be a function that gives all the coordinates (imagine a very curvy set of functions with multiple solutions).

So, I have something that works, but it's very crude. What I've done is put each function into a matrix so `M[h,0]` contains the x-values, `M[h,1]` is function1 y values, `M[h,2]` is function2 y values. I then find the derivative and place this in a new matrix `D[h,1]` and `D[h,2]` (span is one less than `M[h,:]`. My idea was to essentially "plot" the slopes on the x-axis, and the intercepts on the y-axis, and search all these points for the closest pair, then give the values.

Two problems here:

1. program doesn't know if the closest pair is a solution or not and

2. it's painfully slow (numb_of_points^2 search). I realize some optimization libraries may help out, but I worry they will hone in on one solution and ignore the rest.

Anyone think of the best way to do this? My "code" is here:

``````def common_tangent(T):
x_points = 600
x_start = 0.0001
x_end = 0.9999
M = zeros(((x_points+1),5) )
for h in range(M.shape[0]):
M[h,0] = x_start + ((x_end-x_start)/x_points)*(h) # populate matrix
""" Some function 1 """
M[h,1] = T*M[h,0]**2 + 56 + log(M[h,0])
""" Some function 2 """
M[h,2] = 5*T*M[h,0]**3 + T*M[h,0]**2 - log(M[h,0])
der1 = ediff1d(M[:,1])*x_points # derivative of the first function
der2 = ediff1d(M[:,2])*x_points # derivative of the second function
D = zeros(((x_points),9) )
for h in range(D.shape[0]):
D[h,0] = (M[h,0]+M[h+1,0])/2 # for the der matric, find the point between
D[h,1] = der1[h] # slope m_1 at this point
D[h,2] = der2[h] # slope m_2 at this point
D[h,3] = (M[h,1]+M[h+1,1])/2# average y_1 here
D[h,4] = (M[h,2]+M[h+1,2])/2# average y_2 here
D[h,5] = D[h,3] - D[h,1]*D[h,0] # y-intercept 1
D[h,6] = D[h,4] - D[h,2]*D[h,0] # y-intercept 2
monitor_distance = 5000 # some starting number
for h in range(D.shape[0]):
for w in range(D.shape[0]):
distance = sqrt( #in "slope intercept space" find distance
(D[w,6] - D[h,5])**2 +
(D[w,2] - D[h,1])**2
)
if distance < monitor_distance: # do until the closest is found
monitor_distance = distance
fraction1 = D[h,0]
fraction2 = D[w,0]
slope_02 = D[w,2]
slope_01 = D[h,1]
intercept_01 = D[h,5]
intercept_02 = D[w,6]
return (fraction1, fraction2)
``````

This has plenty of applications in materials science, in finding the common tangents between multiple Gibb's functions for the calculation of phase diagrams. It'd be nice to get a robust function out there for all to use...

-
So if I understand this correctly, you'd want to find all the solutions to df/dx - dg/dx = 0 for 2 functions f(x) and g(x)? –  Joel Cornett Apr 22 '12 at 17:42
Not exactly. See the image here: i.stack.imgur.com/Nw9My.png (from: stackoverflow.com/questions/8993850/…) I don't think this extends to Python, but something like this. –  user1349763 Apr 22 '12 at 18:27
would f'(x<sub>1</sub>) - g'(x<sub>2</sub>) + f(x<sub>1</sub>) - g(x<sub>2</sub>) = 0 be more accurate? –  Joel Cornett Apr 22 '12 at 18:44