I can get you started on the math.
I'm not sure how quadratic Bezier is defined, but it must be equivalent
to:

```
(x(t), y(t)) = (a_x + b_x t + c_x t^2, a_y + b_y t + c_y t^2),
```

where `0 < t < 1`

. The a, b, c's are the 6 constants that define the curve.

You want the distance to (X, Y):

```
sqrt( (X - x(t))^2 + (Y - y(t))^2 )
```

Since you want to find `t`

that minimizes the above quantity, you take its
first derivative relative to `t`

and set that equal to 0.
This gives you (dropping the sqrt and a factor of 2):

```
0 = (a_x - X + b_x t + c_x t^2) (b_x + 2 c-x t) + (a_y - Y + b_y t + c_y t^2) ( b_y + 2 c_y t)
```

which is a cubic equation in `t`

. The analytical solution is known and you can find it on the web; you will probably need to do a bit of algebra to get the coefficients of the powers of `t`

together (i.e. 0 = a + b t + c t^2 + d t^3). You could also solve this equation numerically instead, using for example Newton-Raphson.

Note however that if none of the 3 solutions might be in your range `0 < t < 1`

. In that case just compute the values of the distance to (X, Y) (the first equation) at `t = 0`

and `t = 1`

and take the smallest distance of the two.

**EDIT**:

actually, when you solve the first derivative = 0, the solutions you get can be maximum distances as well as minimum. So you should compute the distance (first equation) for the solutions you get (at most 3 values of `t`

), as well as the distances at `t=0`

and `t=1`

and pick the actual minimum of all those values.