I think that the following could be a useful approximation, which scales linearly instead of quadratically with the number of points, and is quite easy to implement:

- calculate the center of mass M of the points
- find the point P
_{0} that has the maximum distance to M
- find the point P
_{1} that has the maximum distance to P_{0}
- approximate the maximum diameter with the distance between P
_{0} and P_{1}

This can be generalized by repeating step 3 N times,
and taking the distance between P_{N-1} and P_{N}

Step 1 can be carried out efficiently approximating M as the average of longitudes and latitudes, which is OK when distances are "small" and the poles are sufficiently far away. The other steps could be carried out using the exact distance formula, but they are much faster if the points' coordinates can be approximated as lying on a plane. Once the "distant pair" (hopefully the pair with the maximum distance) has been found, its distance can be re-calculated with the exact formula.

An example of approximation could be the following: if φ(M) and λ(M) are latitude and longitude of the center of mass calculated as Σφ(P)/n and Σλ(P)/n,

- x(P) = (λ(P) - λ(M) + C) cos(φ(P))
- y(P) = φ(P) - φ(M) [ this is only for clarity, it can also simply be y(P) = φ(P) ]

where C is usually 0, but can be ± 360° if the set of points crosses the λ=±180° line. To find the maximum distance you simply have to find

- max((x(P
_{N}) - x(P_{N-1}))^{2} + (y(P_{N}) - y(P_{N-1}))^{2})

(you don't need the square root because it is monotonic)

The same coordinate transformation could be used to repeat step 1 (in the new coordinate system) in order to have a better starting point. I suspect that if some conditions are met, the above steps (without repeating step 3) always lead to the "true distant pair" (my terminology). If I only knew *which* conditions...

**EDIT:**

I hate building on others' solutions, but someone will have to.

Still keeping the above 4 steps, with the optional (but probably beneficial, depending on the typical distribution of points) repetition of step 3,
and following the solution of Spacedman,
doing calculations in 3D overcomes the limitations of closeness and distance from poles:

- x(P) = sin(φ(P))
- y(P) = cos(φ(P)) sin(λ(P))
- z(P) = cos(φ(P)) cos(λ(P))

(the only approximation is that this holds only for a perfect sphere)

The center of mass is given by x(M) = Σx(P)/n, etc.,
and the maximum one has to look for is

- max((x(P
_{N}) - x(P_{N-1}))^{2} + (y(P_{N}) - y(P_{N-1}))^{2} + (z(P_{N}) - z(P_{N-1}))^{2})

So: you first transform spherical to cartesian coordinates, then start from the center of mass, to find, in at least two steps (steps 2 and 3), the farthest point from the preceding point. You could repeat step 3 as long as the distance increases, perhaps with a maximum number of repetitions, but this won't take you away from a local maximum. Starting from the center of mass is not of much help, either, if the points are spread all over the Earth.

**EDIT 2:**

I learned enough R to write down the core of the algorithm (nice language for data analysis!)

For the plane approximation, ignoring the problem around the λ=±180° line:

```
# input: lng, lat (vectors)
rad = pi / 180;
x = (lng - mean(lng)) * cos(lat * rad)
y = (lat - mean(lat))
i = which.max((x - mean(x))^2 + (y )^2)
j = which.max((x - x[i] )^2 + (y - y[i])^2)
# output: i, j (indices)
```

On my PC it takes less than a second to find the indices `i`

and `j`

for 1000000 points.

The following 3D version is a bit slower, but works for any distribution of points (and does not need to be amended when the λ=±180° line is crossed):

```
# input: lng, lat
rad = pi / 180
x = sin(lat * rad)
f = cos(lat * rad)
y = sin(lng * rad) * f
z = cos(lng * rad) * f
i = which.max((x - mean(x))^2 + (y - mean(y))^2 + (z - mean(z))^2)
j = which.max((x - x[i] )^2 + (y - y[i] )^2 + (z - z[i] )^2)
k = which.max((x - x[j] )^2 + (y - y[j] )^2 + (z - z[j] )^2) # optional
# output: j, k (or i, j)
```

The calculation of `k`

can be left out (i.e., the result could be given by `i`

and `j`

), depending on the data and on the requirements. On the other hand, my experiments have shown that calculating a further index is useless.

It should be remembered that, in any case, the distance between the resulting points is an estimate which is a lower bound of the "diameter" of the set, although it very often will be the diameter itself (*how* often depends on the data.)

**EDIT 3:**

Unfortunately the relative error of the plane approximation can, in extreme cases, be as much as 1-1/√3 ≅ 42.3%, which may be unacceptable, even if very rare. The algorithm can be modified in order to have an upper bound of approximately 20%, which I have derived by compass and straight-edge (the analytic solution is cumbersome). The modified algorithm finds a pair of points whith a locally maximal distance, then repeats the same steps, but this time starting from the midpoint of the first pair, possibly finding a different pair:

```
# input: lng, lat
rad = pi / 180
x = (lng - mean(lng)) * cos(lat * rad)
y = (lat - mean(lat))
i.n_1 = 1 # n_1: n-1
x.n_1 = mean(x)
y.n_1 = 0 # = mean(y)
s.n_1 = 0 # s: square of distance
repeat {
s = (x - x.n_1)^2 + (y - y.n_1)^2
i.n = which.max(s)
x.n = x[i.n]
y.n = y[i.n]
s.n = s[i.n]
if (s.n <= s.n_1) break
i.n_1 = i.n
x.n_1 = x.n
y.n_1 = y.n
s.n_1 = s.n
}
i.m_1 = 1
x.m_1 = (x.n + x.n_1) / 2
y.m_1 = (y.n + y.n_1) / 2
s.m_1 = 0
m_ok = TRUE
repeat {
s = (x - x.m_1)^2 + (y - y.m_1)^2
i.m = which.max(s)
if (i.m == i.n || i.m == i.n_1) { m_ok = FALSE; break }
x.m = x[i.m]
y.m = y[i.m]
s.m = s[i.m]
if (s.m <= s.m_1) break
i.m_1 = i.m
x.m_1 = x.m
y.m_1 = y.m
s.m_1 = s.m
}
if (m_ok && s.m > s.n) {
i = i.m
j = i.m_1
} else {
i = i.n
j = i.n_1
}
# output: i, j
```

The 3D algorithm can be modified in a similar way. It is possible (both in the 2D and in the 3D case) to start over once again from the midpoint of the second pair of points (if found). The upper bound in this case is "left as an exercise for the reader" :-).

Comparison of the modified algorithm with the (too) simple algorithm has shown, for normal and for square uniform distributions, a near doubling of processing time, and a reduction of the average error from .6% to .03% (order of magnitude). A further restart from the midpoint results in an a just slightly better average error, but almost equal maximum error.

**EDIT 4:**

I have to study this article yet, but it looks like the 20% I found with compass and straight-edge is in fact 1-1/√(5-2√3) ≅ 19.3%