Given:

At time 0, the target is at point A and the interceptor is at point B. At some point in the future, they will intersect at point C.

line segment *a* is opposite point A, and likewise for *b* and B, and *c* and C.

We know the positions of A and B. We can derive the angle CAB from the target's heading. We know that the ratio of the lengths of line segments *a* and *b* equals (interceptor.speed/target.speed).

First, find angle CAB.

Let vector B^ be equal to the target's velocity.

Let vector C^ be equal to (interceptor.position.x - target.position.x, interceptor.position.y - target.position.y).

Determine the angle between them using the dot product formula.

```
B dot C = ||B|| * ||C|| * cos(angle)
cos(angle) = (B dot C) / (||B|| * ||C||)
angle = arccos((B dot C) / (||B|| * ||C||))
```

...Where "dot" is the dot product, and ||B|| is the scalar magnitude of vector B. `angle`

is angle CAB.

Now we'll find angle ABC.

Using the law of sines, we know that `sin(ABC) / b == sin(CAB) / a`

.
Rearrange the equation into `ABC = arcsin( sin(CAB) * (b/a) )`

.

We found CAB in the last step, and we know that b/a is target.speed/interceptor.speed, so plug those values in and find ABC.

Now that you know two angles and two points, you should be able to derive the position of C. Angle ACB is equal to 180 - (CAB + ABC) if you're using degrees, or Pi - (CAB + ABC) if you're using radians. Use the sine law to determine the lengths of sides b and c. Now you can find T using `T = b / target.speed`

, and C using `C = target.position + (target.velocity * T)`

.

My C# is a little rusty, so here is a sample Python implementation instead. Let's plug in your sample values, and the result is:

```
Collision pos: Point(163.065368246, 57.2261472985)
Time: 8.61307364926
Angle A: 113.198590514
Angle B: 29.6680851288
Angle C: 37.1333243575
a: 86.1307364926
b: 46.3828210973
c: 56.5685424949
```

The position and time are the same as the ones found by gdir, so I'm pretty confident that both our approaches work.

Edit: MikeT: the C# version

```
public static double Dot(Vector a, Vector b)
{
return a.X * b.X + a.Y * b.Y;
}
public static double Magnitude(Vector vec)
{
return Math.Sqrt(vec.X * vec.X + vec.Y * vec.Y);
}
public static double AngleBetween(Vector b, Vector c)
{
return Math.Acos(Dot(b, c) / (Magnitude(b) * Magnitude(c)));
}
public static Vector? Find_collision_point(Point target_pos, Vector target_vel, Point interceptor_pos, double interceptor_speed)
{
var k = Magnitude(target_vel) / interceptor_speed;
var distance_to_target = Magnitude(interceptor_pos - target_pos);
var b_hat = target_vel;
var c_hat = interceptor_pos - target_pos;
var CAB = AngleBetween(b_hat, c_hat);
var ABC = Math.Asin(Math.Sin(CAB) * k);
var ACB = (Math.PI) - (CAB + ABC);
var j = distance_to_target / Math.Sin(ACB);
var a = j * Math.Sin(CAB);
var b = j * Math.Sin(ABC);
var time_to_collision = b / Magnitude(target_vel);
var collision_pos = target_pos + (target_vel * time_to_collision);
return interceptor_pos - collision_pos;
}
```

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