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,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:
program doesn't know if the closest pair is a solution or not and
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): 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): 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): for w in range(D.shape): 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...