You can find that point by considering first a generic point `(x, y)`

along the line from `(x1, y1)`

to `(x2, y2)`

:

```
x = x1 + t*(x2 - x1)
y = y1 + t*(y2 - y1)
```

and the computing the (squared) distance from this point from `(xp, yp)`

```
E = (x - xp)**2 + (y - yp)**2
```

that substituting the definition of `x`

and `y`

gives

```
E = (x1 + t*(x2 - x1) - xp)**2 +
(y1 + t*(y2 - y1) - yp)**2
```

then to find the minimum of this distance varying `t`

we derive `E`

with respect to `t`

```
dE/dt = 2*(x1 + t*(x2 - x1) - xp)*(x2 - x1) +
2*(y1 + t*(y2 - y1) - yp)*(y2 - y1)
```

that after some computation gives

```
dE/dt = 2*((x1 - xp)*(x2 - x1) + (y1 - yp)*(y2 - y1) +
t*((x2 - x1)**2 + (y1 - y2)**2))
```

looking for when this derivative is zero we get an explicit equation for `t`

```
t = ((xp - x1)*(x2 - x1) + (yp - y1)*(y2 - y1)) /
((x2 - x1)**2 + (y2 - y1)**2)
```

so the final point can be computed using that value for `t`

in the definition of `(x, y)`

.

Using vector notation this is exactly the same formula suggested by Gareth...

```
t = <p - p1, p2 - p1> / <p2 - p1, p2 - p1>
```

where the notation `<a, b>`

represents the dot product operation `ax*bx + ay*by`

.

Note also that the very same formula works in an n-dimensional space.