To get the perpendicular distance of a point `Q`

to a line defined by two points `P_1`

and `P_2`

calculate this:

```
d = DOT(Q, CROSS(P_1, P_2) )/MAG(P_2 - P_1)
```

where `DOT`

is the dot product, `CROSS`

is the vector cross product, and `MAG`

is the magnitude (`sqrt(X*X+Y*Y+..)`

)

Using Fig 5. You calculate `d_1`

the distance from `sj`

to line (`si->ei`

) and `d_2`

the distance from `ej`

to the same line.

I would establish a coordinate system based on three points, two (`P_1`

, `P_2`

) for a line and the third `Q`

for either the start or the end of the *other* line segment. The three axis of the coordinate system can be defined as such:

```
e = UNIT(P_2 - P_1) // axis along the line from P_1 to P_2
k = UNIT( CROSS(e, Q) ) // axis normal to plane defined by P_1, P_2, Q
n = UNIT( CROSS(k, e) ) // axis normal to line towards Q
```

where `UNIT()`

is function to return a unit vector (with magnitude=1).

Then you can establish all your projected lengths with simple dot products. So considering the line `si-ei`

and the point `sj`

in Fig 5, the lengths are:

```
(l || 1) = DOT(e, sj-si);
(l |_ 1) = DOT(n, sj-si);
ps = si + e * (l || 1) //projected point
```

And with the end of the second segment `ej`

, new coordinate axes (`e`

,`k`

,`n`

) need to be computed

```
(l || 2) = DOT(e, ei-ej);
(l |_ 1) = DOT(n, ej-ei);
pe = ei - e * (l || 1) //projected point
```

Eventually the angle distance is

```
(d th) = ATAN( ((l |_ 2)-(L |_ 1))/MAG(pe-ps) )
```

PS. You might want to post this at **Math.SO** where you can get better answers.