**EDIT** The original code I wrote does not work properly, so I have removed it. But following the same idea, explained below, if you spend some time thinking at it, there is no need for Cramer's rule, and the code can be streamlined quite a bit as follows :

```
def distance(v1, v2, u) :
u = np.array(u, ndmin=2)
v = np.vstack((v1, v2))
vv = np.dot(v, v.T) # shape (2, 2)
uv = np.dot(u, v.T) # shape (n ,2)
ab = np.dot(np.linalg.inv(vv), uv.T) # shape(2, n)
w = u - np.dot(ab.T, v)
return np.sqrt(np.sum(w**2, axis=1)) # shape (n,)
```

To make sure it works properly, I have packed Dave's code into a function as `distance_3d`

and tried the following:

```
>>> d, n = 3, 1000
>>> v1, v2, u = np.random.rand(d), np.random.rand(d), np.random.rand(n, d)
>>> np.testing.assert_almost_equal(distance_3d(v1, v2, u), distance(v1, v2, u))
```

But of course it now works for any `d`

:

```
>>> d, n = 1000, 3
>>> v1, v2, u = np.random.rand(d), np.random.rand(d), np.random.rand(n, d)
>>> distance(v1, v2, u)
array([ 10.57891286, 10.89765779, 10.75935644])
```

You have to decompose your vector, lets call it `u`

, in the sum of two vectors, `u = v + w`

, `v`

is in the plane, and so can be decomposed as `v = a * v1 + b * v2`

, while `w`

is perpendicular to the plane, and thus `np.dot(w, v1) = np.dot(w, v2) = 0`

.

If you write `u = a * v1 + b * v2 + w`

and take the dot product of this expression with `v1`

and `v2`

, you get two equations with two unknowns:

```
np.dot(u, v1) = a * np.dot(v1, v1) + b * np.dot(v2, v1)
np.dot(u, v2) = a * np.dot(v1, v2) + b * np.dot(v2, v2)
```

Since it is only a 2x2 system, we can solve it using Cramer's rule as:

```
uv1 = np.dot(u, v1)
uv2 = np.dot(u, v2)
v11 = np.dot(v1, v2)
v22 = np.dot(v2, v2)
v12 = np.dot(v1, v2)
v21 = np.dot(v2, v1)
det = v11 * v22 - v21 * v12
a = (uv1 * v22 - v21 * uv2) / det
b = (v11 * uv2 - uv1 * v12) / det
```

From here, you can get:

```
w = u - v = u - a * v1 - b * v2
```

and the distance to the plane is the modulus of `w`

.

`np.vectorize`

is never very fast, as its docstring points out. – Fred Foo Feb 1 '13 at 14:55