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I have been learning about the dual contouring algorithm which is useful since it allows surfaces to contain both smooth and sharp edges. I am somewhat confused over how the input data is used. I believe that I would better understand this if I understood how a minimal sharp cube was defined.

Having spent quite some time reading various resources I have come to believe that one of the following ideas is correct, but I have been unable to determine which. To avoid confusion lets call the surface a cube and any 8 neighbouring grid-points a cell. An illustration would be very warmly appreciated to help illustrate the construction.

Idea #1 - A minimal sharp cube is defined by a 2x2x2 grid where each grid point equates to a corner of the formed cube.

|   |
2x2x2 grid points / 1 grid cell

Idea #2 - A minimal sharp cube is defined by a 3x3x3 grid where each grid cell contains a so called "feature point" and it takes 8 feature points to form the cube.

| . | . |          +---+
+---+---+   ===>   |   |
| . | . |          +---+
3x3x3 grid points / 8 grid cells

Idea #3 - A minimal sharp cube is defined by a 1x1x1 grid where one grid cell of a certain density leads to the formation of a minimal sharp cube.

1x1x1 grid points / 0 grid cells

Here is another reference which may be of use to future readers:

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Idea #2 is correct. Do you have any other questions on the algorithm? Keep in mind that the algorithm is used to extract polygonal surfaces from implicit surfaces. – Nico Schertler Aug 7 '13 at 8:11
@NicoSchertler Awesome thanks! if you convert that to an answer I will accept :) Also thanks for the reference to "implicit surfaces" since this caused Google to throw all sorts of additional content at me which I had been missing! – Lea Hayes Aug 7 '13 at 18:28

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