I tried @Bill answer and it actually does not work every time and it makes sense. Based on the link in his code.Let's have for example these two line segments **AB** and **CD**.

A=(2,1,5), B=(1,2,5) and C=(2,1,3) and D=(2,1,2)

when you try to get the intersection it might tell you It's the point A (incorrect) or there is no intersection (correct). Depending on the order you put those segments in.

**x = A+(B-A)s**

x = C+(D-C)t

Bill solved for **s** but never solved **t**. And since you want that intersection point to be on both line segments both **s** and **t** have to be from interval **<0,1>**. What actually happens in my example is that only **s** if from that interval and **t** is -2. **A** lies on line defined by **C** and **D**, but not on line segment **CD**.

```
var s = Vector3.Dot(Vector3.Cross(dc, db), Vector3.Cross(da, db)) / Norm2(Vector3.Cross(da, db));
var t = Vector3.Dot(Vector3.Cross(dc, da), Vector3.Cross(da, db)) / Norm2(Vector3.Cross(da, db));
```

where da is B-A, db is D-C and dc is C-A, I just preserved names provided by Bill.

Then as I said you have to check if both **s** and **t** are from **<0,1>** and you can calculate the result. Based on formula above.

```
if ((s >= 0 && s <= 1) && (k >= 0 && k <= 1))
{
Vector3 res = new Vector3(this.A.x + da.x * s, this.A.y + da.y * s, this.A.z + da.z * s);
}
```

Also another problem with Bills answer is when two lines are collinear and there is more than one intersection point. There would be division by zero. You want to avoid that.

`z`

planes. If you project them to the xy planes then they will appear to be intersecting, even though they are not. – Graviton Feb 24 '10 at 1:28`a`

and`b`

must be between 0 and 1 – Graviton Feb 24 '10 at 3:21