gluLookAt, which you've already run into, is your solution. First three arguments are the camera's position (x,y,z), next three are the camera's center (the point it's looking at), and the final three are the up vector (usually (0,1,0)), which defines the *camera*'s y-z plane.*

It's pretty simple: you just glLoadIdentity();, call gluLookAt(...), and then draw your scene as normally. Personally, I always do all the calculations in the CPU myself. I find that orbiting a point is an extremely common task. My template C/C++ code uses spherical coordinates and looks like:

```
double camera_center[3] = {0.0,0.0,0.0};
double camera_radius = 4.0;
double camera_rot[2] = {0.0,0.0};
double camera_pos[3] = {
camera_center[0] + camera_radius*cos(radians(camera_rot[0]))*cos(radians(camera_rot[1])),
camera_center[1] + camera_radius* sin(radians(camera_rot[1])),
camera_center[2] + camera_radius*sin(radians(camera_rot[0]))*cos(radians(camera_rot[1]))
};
gluLookAt(
camera_pos[0], camera_pos[1], camera_pos[2],
camera_center[0],camera_center[1],camera_center[2],
0,1,0
);
```

Clearly you can adjust camera_radius, which will change the "zoom" of the camera, camera_rot, which will change the rotation of the camera about its axes, or camera_center, which will change the point about which the camera orbits.

*The only other tricky bit is learning *exactly* what all that means. To clarify, because the internet is lacking:

- The position is the (x,y,z) position of the camera. Pretty straightforward.
- The center is the (x,y,z) point the camera is focusing at. You're basically looking along an imaginary ray
*from* the position *to* the center.
- Now, your camera could still be looking any direction
*around* this vector (e.g., it could be upsidedown, but still looking along the same direction). The up vector is a vector, *not* a position. It, along with that imaginary vector from the position to the center, form a plane. This is the camera's y-z plane.