Given the line segment AB, you can find the midpoint, say **M**, using the famous midpoint formula `(A + B)/2`

. Now calculate the vector from **B** to **A**:

**p** = <p.x, p.y> = **A** ‒ **B**

Rotate it about the origin by 90° counter-clockwise to get the perpendicular vector

**n** = <n.x, n.y> = < ‒ p.y, p.x >

Normalise it:

**n** = <n.x, n.y> / ‖n‖ where ‖n‖ = √(n.x² + n.y²) is the Euclidean Norm or length

**C** = L(t) = **M** + t **n**

Using this equation -- parametric form of a line -- you can find any number of points along the perpendicular line (in the direction of **n**). `t`

is the distance of the obtained point, **C**, from **M**. When `t = 0`

, you get **M** back, when `t = 1`

, you get a point 1 unit away from **M** along **n** and so on. This also works for negative values of `t`

, where the points obtained will be on the opposite side of AB i.e. towards the note. Since `t`

can be a decimal number, you can play with it by changing its values to get the desired distance and direction of the obtained point from **M**.

Code, since you said you're not interested in the math jargon ;)

```
vec2d calculate_perp_point(vec2d A, vec2d B, float distance)
{
vec2d M = (A + B) / 2;
vec2d p = A - B;
vec2d n = (-p.y, p.x);
int norm_length = sqrt((n.x * n.x) + (n.y * n.y));
n.x /= norm_length;
n.y /= norm_length;
return (M + (distance * n));
}
```

This is just pseudo code, since I'm not sure of the vector math library you are using for your project.

*Boldface variables above are 2-d vectors; uppercase letters denote points and lowercase ones are vectors with no position*