How to perform non-linear optimization with scipy/numpy or sympy?

I am trying to find the optimal solution to the follow system of equations in Python:

``````(x-x1)^2 + (y-y1)^2 - r1^2 = 0
(x-x2)^2 + (y-y2)^2 - r2^2 = 0
(x-x3)^2 + (y-y3)^2 - r3^2 = 0
``````

Given the values a point(x,y) and a radius (r):

``````x1, y1, r1 = (0, 0, 0.88)
x2, y2, r2 = (2, 0, 1)
x3, y3, r3 = (0, 2, 0.75)
``````

What is the best way to find the optimal solution for the point (x,y) Using the above example it would be:
~ (1, 1)

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You have undefined variables (x and y) in the function `eqs`. Can you include the actual code that you are using? – Warren Weckesser Oct 17 '12 at 19:50
I'm trying to optimize the values of x and y for the system of equations. – drbunsen Oct 17 '12 at 19:57
I was using this example: stackoverflow.com/questions/8739227/… – drbunsen Oct 17 '12 at 19:58
fsolve is for numerical root finding, not optimization, i.e. it will seek to find values of the input such that the output of the function is zero. The example you are pointing to is not applicable here. Also, I do not grasp what optimal values x and y is supposed to mean in the context of three equations. (From what your code says, the computer will neither.) Be clear on what you try to achieve. – ilmiacs Oct 17 '12 at 20:25
Thanks for the comments and sorry for being unclear. I've rephrased the question, which is now hopefully more clear. – drbunsen Oct 17 '12 at 20:35

If I understand your question correctly, I think this is what you're after:

``````from scipy.optimize import minimize
import numpy as np

def f(coord,x,y,r):
return np.sum( ((coord[0] - x)**2) + ((coord[1] - y)**2) - (r**2) )

x = np.array([0,   2,  0])
y = np.array([0,   0,  2])
r = np.array([.88, 1, .75])

# initial (bad) guess at (x,y) values
initial_guess = np.array([100,100])

res = minimize(f,initial_guess,args = [x,y,r])
``````

Which yields:

``````>>> print res.x
[ 0.66666666  0.66666666]
``````

You might also try the least squares method which expects an objective function that returns a vector. It wants to minimize the sum of the squares of this vector. Using least squares, your objective function would look like this:

``````def f2(coord,args):
x,y,r = args
# notice that we're returning a vector of dimension 3
return ((coord[0]-x)**2) + ((coord[1] - y)**2) - (r**2)
``````

And you'd minimize it like so:

``````from scipy.optimize import leastsq
res = leastsq(f2,initial_guess,args = [x,y,r])
``````

Which yields:

``````>>> print res[0]
>>> [ 0.77961518  0.85811473]
``````

This is basically the same as using `minimize` and re-writing the original objective function as:

``````def f(coord,x,y,r):
vec = ((coord[0]-x)**2) + ((coord[1] - y)**2) - (r**2)
# return the sum of the squares of the vector
return np.sum(vec**2)
``````

This yields:

``````>>> print res.x
>>> [ 0.77958326  0.8580965 ]
``````

Note that `args` are handled a bit differently with `leastsq`, and that the data structures returned by the two functions are also different. See the documentation for `scipy.optimize.minimize` and `scipy.optimize.leastsq` for more details.

See the `scipy.optimize` documentation for more optimization options.

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The result you found doesn't satisfy any of the equations... – Roland Smith Oct 17 '12 at 21:34
This is precisely what I was looking for! Thanks for your help and patients trying to understand what I was trying to do. – drbunsen Oct 17 '12 at 22:05
Glad to hear it! You might also play with using the l2 norm instead of the sum for your cost function, i.e., use `np.linalg.norm` in place of `np.sum`, and see how that affects your results. – John Vinyard Oct 17 '12 at 22:59
Could leastsq also be used here? What is the difference between minimize() and leastsq()? – drbunsen Oct 18 '12 at 13:28
The main difference that's relevant here is that `minimize` expects a scalar-valued function, and `leastsq` expects a vector-valued function. `leastsq` wants to minimize the sum of the squares of the vector returned by the objective function, so it's almost like using the l2 norm with `minimize`. In fact, I get answers that are almost identical using `leastsq` and the l2 norm with `minimize`: ~`[.78,.86]` – John Vinyard Oct 18 '12 at 13:53

These equations can be seen as describing all the points on the circumference of three circles in 2D space. The solution would be the points where the circles intercept.

The sum of their radii of the circles is smaller than the distances between their centres, so the circles don't overlap. I've plotted the circles to scale below:

There are no points that satisfy this system of equations.

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Correct, but I want the optimal solution, if an exact solution does not exist. – drbunsen Oct 17 '12 at 22:04
What do you mean by an optimal solution, in this case, where no solution exists? – Roland Smith Oct 17 '12 at 22:05
I mean, I want a solution that minimizes the error. – drbunsen Oct 17 '12 at 22:06