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Smoothing a Voxel World

My graphics application is written in C++ using OpenGL. It comes up with a 3 dimensional space where the terrain is out of voxel, so the world consists of cubes and looks blocky. My aim is now to render this world (still represented by voxels) more smoothly.

What I am looking for is an algorithm for rounding over the edges of my blocky world. But to get a visually nice result I don't simply want to do that by circular rounding the edges. I provide some pictures for you to understand.

Explaination with Images

I figured it out to smooth 2 dimensional terrain the way I want. My question is how to transfer and abstract this algorithm to shift it into the 3rd dimenstion. (Maybe we need bezier-surfaces, but I am not sure.)

Let's explain my algorithm working for 2 dimensional terrain.

Edged World without Smoothing in 2d This is how the raw 2d world data would look without smoothing.

Let's see the oppertunities of smoothing.

Circular Smoothing in 2d This is smoothed but not in a nice way and it is also 2d.

To get better results I have to use information about near pixels (or voxels in a 3 dimensional space) to round out a pixel. Firstly see my result in 2d. (It is a working application.)

Bezier Smoothing in 2d This looks much more natural but is still 2 dimensional.

I want to explain my algorithm to get the result above. Sadly it is 2d and I believe that there is a possibility to abstract from it to a 3 dimensional world. It also don't work for overhangs in terrain yet.

Working Algorithm for a 2D World

  1. Given a pixel in the world calculate the height offset of the left and right neighbour pixels. The offset can range from +2 to -2. Here are two examples

    Neighbour Offset Example One     Neighbour Offset Example Two

  2. Calculate a bezier curve along four control points.

    • The first point is X=0 and Y=(OffsetLeft/2)
    • Second is X=0 or if (OffsetLeft is 1 or -1) X=0.5 and Y=0
    • Third is X=1 or if (OffsetRight is 1 or -1) X=0.5 and Y=0
    • The last point is X=1 and Y=(OffsetRight/2)


    Where the coordinates are relative to the current pixel's position. X=0 and Y=0 is the bottom left corner and X=1 and Y=1 is the top right corner of the pixel.

You can see the result in the picture above but here is also another demo.

Bezier Smoothing 2d Demo More complicated terrain smoothed by the described algorithm which uses bezier curves.

I need your Bright Minds now!

Finally my question is How can I abstract my algorithm to the third dimension and also let it handle overhanging cliffs in terrain?

I am grateful for all thoughts and ideas. Remember it is about a realtime graphics application so it is performance related. But it would be awesome to just see any answer cracking the problem!

Update to make things clear

First of all thank you for suggesting me algorithms. It's too bad that you misunderstood my question. There is a chance that I proposed my question unclear.

  • What this question is looking for: Approaches for developing an algorithm that uses the same technique I introduced, but for a 3 dimensional world. Or a ready algorithm that you developed or that is known.

  • What this question is not looking for: Known algorithms that meight provide a similar result.

If somebody is interested in the source code for my 2d smoothing implementation I would provide it, it is written in C#.

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"Known algorithms that meight provide a similar result.". Please, please, look up marching cubes. You wouldn't want to make a new sorting algorithm without understanding quicksort first either. –  starmole Sep 14 '12 at 5:59
    
Your technique can't handle overhanging terrain. So it's impossible to use your algorithm to handle overhanging cliffs. You need a different algorithm. Also all algorithms listed as answers are "ready (?) algorithms that are known". –  Simon Sep 14 '12 at 9:01
    
Certainly my algorithm can't handle overhangs. That's why I would love your help to improve and generalize it. By now it is orientated on the top of my squares. I believe that there is a way to bring it up to handle all sides of cubes the same way. (I understand marching cubes but it is not what I need, it is another approach.) –  danijar Sep 14 '12 at 9:38
    
Are you saying that marching cubes does not solve your problem? Why not? The answer might allow me to give a better answer. –  Simon Sep 16 '12 at 20:44
    
i have the same problem but marching cubes simply made blocks in to 45 degree slopes not very smooth at all ... i couldn't figure out how to convert voxel "on off" data in to density data in any way that marching cubes would render smooth edges. –  Wardy Apr 10 '13 at 17:32
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3 Answers 3

up vote 2 down vote accepted

You should probably have a look at the marching cubes algorithm and work from there. You can easily control the smoothness of the resulting blob:

  1. Imagine that each voxel defines a field, with a high density at it's center, slowly fading to nothing as you move away from the center. For example, you could use a function that is 1 inside a voxel and goes to 0 two voxels away. No matter what exact function you choose, make sure that it's only non-zero inside a limited (preferrably small) area.
  2. For each point, sum the densities of all fields.
  3. Use the marching cubes algorithm on the sum of those fields
  4. Use a high resolution mesh for the algorithm

In order to change the look/smoothness you change the density function and the threshold of the marching cubes algorithm. A possible extension to marching cubes to create smoother meshes is the following idea: Imagine that you encounter two points on an edge of a cube, where one point lies inside your volume (above a threshold) and the other outside (under the threshold). In this case many marching cubes algorithms place the boundary exactly at the middle of the edge. One can calculate the exact boundary point - this gets rid of aliasing.

Also I would recommend that you run a mesh simplification algorithm after that. Using marching cubes results in meshes with many unnecessary triangles.

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I realized that I will do some research in my algorithm on my own. However this answer helped me the most, so I accept that. Thanks for your other answer, too. –  danijar Oct 9 '12 at 16:38
    
hey danijar did you figure this out in the end? I still have a problem with my marching cubes ... only seems to do a very simple cube to 45 degree slope type conversion ... others have suggested implementing "surface nets" on the mc results and I have not yet figured out the uv mappings on the new mc mesh either since there are now definable "block faces" any more. –  Wardy Apr 10 '13 at 17:36
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As an alternative to my answer above: You could also use NURBS or any algorithm for subdivision surfaces. Especially the subdivision surfaces algorithms are spezialized to smooth meshes. Depending on the algorithm and it's configuration you will get smoother versions of your original mesh with

  • the same volume
  • the same surface
  • the same silhouette

and so on.

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1  
Also, have a look at dual contouring. Here's the paper frankpetterson.com/publications/dualcontour/dualcontour.pdf and some related SO question stackoverflow.com/questions/6485908/… –  Simon Sep 12 '12 at 12:03
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Use 3D implementations for Biezer curves known as Biezer surfaces or use the B-Spline Surface algorithms explained:

here

or

here

share|improve this answer
    
Ok I mentioned bezier surfaces in my question. But how could I find the control points then? And how could I get it to handle overhangs. The question is about an algorithm or an approach to that. –  danijar Sep 10 '12 at 16:36
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