# All possible directions in which body can move in some closed space

Input: body and some closed space. Body and space are represented as meshes(or BReps, if you like). Initially body doesn't intersect the boundary of the space.

The problem is to find all possible directions in which body can move. For example, in following picture, body can move only in directions from (-1,0) to (0,1). If body has a circle(or sphere) surface - it is ok to return directions with some step (for example, for picture below, output can be (-1,0), (-pi/4,pi/4), (0,1) with step = 3).

Output: set of directions in which body can move.

Problem must be solved in 2d and 3d space.

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You want to work in the configuration space. Basically increase the size of your boundary based on the shape of your body, then treat the body as a point object. What's left are all the valid positions of the body. Of course, if your body is not a circle and can rotate, then your configuration space is no longer 2D or 3D. It has as many dimensions as your body has degrees of freedom, so 6 for a rigid body that can translate and rotate.

This is a well known problem in robotic motion planning. Google for "configuration space" or "c-space", and "motion planning".

This is a good set of slides from a class at Carnegie Mellon: Configuration Space Lecture

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do you mean work with minkowski sum? Is there any easier solution? –  innochenti Mar 22 '12 at 21:07

Displace the object (temporarily) by a vector (with a very small magnitude) representing the direction you want to test. Then run a collision detection algorithm between the object and the environment.

If there are no collisions, then the object can move in that direction. If there is a collision, then it can't.

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too obvious. =) –  innochenti Mar 22 '12 at 20:41

I assume, the body initially doesn't intersect the boundary of your space.

As long as the body does not touch the boundary (or is closer to it than some epsilon), your body can move freely.

So start with the full range `[0, 2 * pi]` of valid directions.

Iterate over all vertices of your body and for each one, check if it touches the bondary. If so, compute the normal of the bondary segment touching the body and remove the 180-degree interval centered at your negative normal direction from the set of valid directions.

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too obvious. =) –  innochenti Mar 22 '12 at 20:40