# The point that minimizes the sum of euclidean distances to a set of n points

I have a set of points `W={(x1, y1), (x2, y2),..., (xn, yn)}` on the 2D plane. Can you find an algorithm that takes these points as the input and returns a point `(x, y)` on the 2D plane which has the minimum sum of distances from the points in `W`? In other words, if

`di = Euclidean_distance((x, y), (xi, yi))`

I want to minimize:

`d1 + d2 + ... + dn`

• At the risk of embarrassing myself with some not-thought-trough guess: Isn't that just the center of gravity? – Marco13 Jul 30 at 17:46
• What search terms did you use that failed to find the known solutions? – Prune Jul 30 at 17:53
• You are looking for a geometric median. – user58697 Jul 30 at 18:50
• @Marco13: the center of gravity minimizes the sum of squared distances. – Yves Daoust Jul 30 at 20:08

The Problem

You're looking for the geometric median.

An Easy Solution

There is no closed-form solution to this problem, so iterative or probabilistic methods are used. The easiest way to find this is probably with Weiszfeld's algorithm:

We can implement this in Python as follows:

``````import numpy as np
from numpy.linalg import norm as npnorm
c_pt_old = np.random.rand(2)
c_pt_new = np.array([0,0])

while npnorm(c_pt_old-c_pt_new)>1e-6:
num   = 0
denom = 0
for i in range(POINT_NUM):
dist   = npnorm(c_pt_new-pts[i,:])
num   += pts[i,:]/dist
denom += 1/dist
c_pt_old = c_pt_new
c_pt_new = num/denom

print(c_pt_new)
``````

There's a chance that Weiszfeld's algorithm won't converge, so it might be best to run it several times from different starting points.

A General Solution

You can also find this using second-order cone programming (SOCP). In addition to solving your specific problem, this general formulation then allows you to easily add constraints and weightings, such as variable uncertainty in the location of each data point.

To do so, you create a number of indicator variables representing the distance between the proposed center point and the data points.

You then minimize the sum of the indicator variables. The result follows

``````import cvxpy as cp
import numpy as np
import matplotlib.pyplot as plt

#Generate random test data
POINT_NUM = 100
pts       = np.random.rand(POINT_NUM,2)

c_pt      = cp.Variable(2)           #The center point we wish to locate
distances = cp.Variable(POINT_NUM)   #Distance from the center point to each data point

#Generate constraints. These are used to hold distances.
constraints = []
for i in range(POINT_NUM):
constraints.append( cp.norm(c_pt-pts[i,:])<=distances[i] )

objective = cp.Minimize(cp.sum(distances))

problem = cp.Problem(objective,constraints)

optimal_value = problem.solve()

print("Optimal value = {0}".format(optimal_value))
print("Optimal location = {0}".format(c_pt.value))

plt.scatter(x=pts[:,0], y=pts[:,1], s=1)
plt.scatter(c_pt.value[0], c_pt.value[1], s=10)
plt.show()
``````

SOCPs are available in a number of solvers including CPLEX, Elemental, ECOS, ECOS_BB, GUROBI, MOSEK, CVXOPT, and SCS.

I've tested and the two approaches give the same answers to within tolerance.

Weiszfeld, E. (1937). "Sur le point pour lequel la somme des distances de n points donnes est minimum". Tohoku Mathematical Journal. 43: 355–386.

• @MohsenKiskani: I've also updated my answer to include an easier solution which doesn't rely on SOCP. – Richard Jul 30 at 19:40

A third method would be to use a compact nonlinear programming formulation. An unconstrained NLP model would be:

``````  min sum(i,  ||x-p(i)|| )
``````

This has just 2 variables (the coordinates of `x`).

There is a very good initial point available. Let `p(i,c)` be the coordinates of the data points. Then the mean is

``````  m(c) = sum(i, p(i,c)) / n
``````

where `n` is the number of data points. This point is often very close to the optimal value of `x`. So we can use `m` as an excellent initial point for `x`.

Some limited experiments indicate this approach is quite faster than a cone programming formulation for large `n`.

• Try to avoid putting critical information in links. (Awesome blog, though!) – Richard Aug 9 at 16:04