For instance:
An approach to compute efficiently the first intersection between a viewing ray and a set of three objects: one sphere, one cone and one cylinder (other 3D primitives).
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For instance: An approach to compute efficiently the first intersection between a viewing ray and a set of three objects: one sphere, one cone and one cylinder (other 3D primitives). 


What you're looking for is a spatial partitioning scheme. There are a lot of options for dealing with this, and lots of research spent in this area as well. A good read would be Christer Ericsson's RealTime Collision Detection. One easy approach covered in that book would be to define a grid, assign all objects to all cells it intersects, and walk along the grid cells intersecting the line, front to back, intersecting with each object associated with that grid cell. Keep in mind that an object might be associated with more gridcells, so the intersection point computed might actually not be in the current cell, but actually later on. The next question would be how you define that grid. Unfortunately, there's no one good answer, and you need to consider what approach might fit your scenario best. Other partitioning schemes of interest are different tree structures, such as kd, Oct and BSPtrees. You could even consider using trees combined with a grid. EDIT 


"computationally efficient" depends on how large the set is. For a trivial set of three, just test each of them in turn, it's really not worth trying to optimise. For larger sets, look at data structures which divide space (e.g. KDTrees). Whole chapters (and indeed whole books) are dedicated to this problem. My favourite reference book is An Introduction to Ray Tracing (ed. Andrew. S. Glassner) Alternatively, if I've misread your question and you're actually asking for algorithms for rayobject intersections for specific types of object, see the same book! 


Well, it depends on what you're really trying to do. If you'd like to produce a solution that is correct for almost every pixel in a simple scene, an extremely quick method is to precalculate "what's in front" for each pixel by prerendering all of the objects with a unique identifying color into a background item buffer using scan conversion (aka the zbuffer). This is sometimes referred to as an item buffer. Using that precomputation, you then know what will be visible for almost all rays that you'll be shooting into the scene. As a result, your rayenvironment intersection problem is greatly simplified: each ray hits one specific object. When I was doing this many years ago, I was producing realtime raytraced images of admittedly simple scenes. I haven't revisited that code in quite a while but I suspect that with modern compilers and graphics hardware, performance would be orders of magnitude better than I was seeing then. PS: I first read about the item buffer idea when I was doing my literature search in the early 90s. I originally found it mentioned in (I believe) an ACM paper from the late 70s. Sadly, I don't have the source reference available but, in short, it's a very old idea and one that works really well on scan conversion hardware. 


I assume you have a ray d = (dx,dy,dz), starting at o = (ox,oy,oz) and you are finding the parameter t such that the point of intersection p = o+d*t. (Like this page, which describes rayplane intersection using P2P1 for d, P1 for o and u for t) The first question I would ask is "Do these objects intersect"? If not then you can cheat a little and check for ray collisions in order. Since you have three objects that may or may not move per frame it pays to precalculate their distance from the camera (e.g. from their centre points). Test against each object in turn, by distance from the camera, from smallest to largest. Although the empty space is the most expensive part of the render now, this is more effective than just testing against all three and taking a minimum value. If your image is high res then this is especially efficient since you amortise the cost across the number of pixels. Otherwise, test against all three and take a minimum value... In other situations you may want to make a hybrid of the two methods. If you can test two of the objects in order then do so (e.g. a sphere and a cube moving down a cylindrical tunnel), but test the third and take a minimum value to find the final object. 

