I've used a quad-tree in a larger project, which is good for game objects that don't move much (less removals & re-insertions). The same principle applies for octrees.

The basic Idea Is, you create a recursive tree structure, which stores 4(for quad), or 8(oct) child objects of the same type as the tree root. Each node in the tree represents a section of Cartesian space, for example, -100 -> +100 on each applicable axis. each child represents that same space, but subdivided by half (an immediate child of the example would represent, for example, -100->0 on X axis, and -100->0 on Y axis).

Imagine a square, or plane, with a given set of dimensions. Now draw a line through the centre on each axis, dividing that plane into 4 smaller planes. Now take one of them and do It again, and again, until you reach a point when the size of the plane segment Is roughly the size of a game object. Now you have your tree. Only objects occupying the same plane, can possibly collide. When you have determined which objects *can* collide, You generate pairs of possible collisions from them. At this stage, broadphase Is complete, and you can move onto narrow phase collision detection, which Is where your more precise, and expensive calculations are.

The purpose of Broadphase, Is to use inexpensive calculations to generate possible collisions, and cull out contacts that *cannot* occur, thus reducing the work your narrow phase algorithm has to perform, In turn, making your entire collision detection algorithm more efficient.

So before you go ahead and attempt to implement such an algorithm, as yourself:

How many objects are in my game?
If there are a lot, I probably need a broadphase. If not, then the Nnarrowphase should suffice.
Also, am I dealing with many moving objects?

Tree structures generally are slowed down by moving objects, as they can change their position in the tree over time, simply by moving. This requires that objects be removed and reinserted each frame (potentially), which is less than Ideal.

If this is the case, you would be better off with Sweep and Prune, which maintains min/max heaps of the extents of the shapes in your world. Objects do not need to be reinserted, but the heaps need to be resorted each frame, thought this is generally faster than a tree wide, traversal with removals and reinsertions.

Depending on your coding experience, one may be more complicated to code over another. Personally I have found trees to be more intuitive to code, but less efficient, and more prone to error, since they raise other issues, such as what to do if you have an object that sits directly on top of an axis, or the centre of the root node. This can be solved by using loose trees, which have some spacial overlap, so that one child node is always prioritised over others when such a case occurs.