For a very simple `orbit`

camera, like most `3rd person`

adventure games, you will need 4 things:

- The position of the target
- The distance from the target
- The azimuthal angle
- The polar angle

(If you want your camera to be always relative to the target in orientation, you need to provide the target's orientation as well, in this case I will simply use the world orientation)

See Spherical coordinate systems for a reference.

You should map your azimuthal angle on your horizontal control (and make it loop around when you reach `2 * PI`

) and your polar angle should be mapped on your vertical control (or inverted if the player selects that option and make it clamped between `-PI`

and `PI`

- watch out for calculations based on the world `Up`

vector if you go parallel to it (`-PI`

or `PI`

)

The distance can be fixed or driven by a spline, for this case we will assume a fixed distance.

So, to compute your position you start with `WorldForward`

, which is a `unit vector`

pointing in the axis that you generally consider to be your forward, for example `(1,0,0)`

(here, if we were building a relative camera, we would use our target's forward vector) and you invert it (`* -1`

) to go "from the target" "to your camera".

(The following is untested pseudo code, but you should get the gist - also, keep note that it can be simplified, I just went for clarity)

Next step is to `rotate`

this vector using our azimuth angle, which is the horizontal orientation component of your camera. Something like:

```
Vector toCamera = WorldForward * -1;
Matrix horizontalRotation = Matrix.CreateRotationZ(azimuth); // assuming Z is up
Vector horizontalRotationPosition = horizontalRotation.Transform(toCamera);
```

At this point, you have a camera that can rotate horizontally around your target, now to add the other axis, you simply transform again using the polar angle rotation:

```
Matrix verticalRotation = Matrix.CreateRotationY(polar); // assuming Y is right
Vector finalRotatedVector = verticalRotation.Transform(horizontalRotationPosition);
```

Now, what we have is a `unit vector`

that points to the position where the camera should be, if you multiply it by the `distance`

you want to keep from your target and add the position of your target, you should get your final `position`

. Keep in mind that this unit vector, if negated, represents the `forward`

vector of your camera.

```
Vector cameraPosition = targetPosition + finalRotatedVector * distanceFromTarget;
```