Title :
Progressive geometry compression for meshes
Author :
Liu, Xinguo ; Bao, Hujun ; Heng, PhengAnn ; Wong, TienTsin ; Sun, Hanqiu ; Peng, Qunsheng
Author_Institution :
State Key Lab. of CAD & CG, Zhejiang Univ., China
Abstract :
A novel progressive geometry compression scheme is presented in this paper. In this scheme, a mesh is represented as a base mesh followed by some groups of vertex split operations using an improved simplification method in which each level of the mesh can be refined into the next level by carrying out a group of vertex split operations in any order. Consequently, the progressive mesh (PM) representation can be effectively encoded by permuting the vertex split operations in each group. Meanwhile, a geometry predictor using the Laplacian operator is designed to predict each new vertex position using its neighbours. The correction is quantized and encoded using a Huffman coding scheme. Experimental results show that our algorithm obtains higher compression ratios than previous work. It is very suitable for the progressive transmission of geometric models over the Internet
Keywords :
Huffman codes; Internet; computational geometry; data communication; data compression; mesh generation; Huffman coding; Internet; Laplacian operator; compression ratio; geometric models; geometry predictor; manifold surface; mesh level refinement; progressive geometry compression scheme; progressive mesh representation; progressive model transmission; quantized correction; simplification method; triangular mesh; vertex position prediction; vertex split operations; Application software; Bandwidth; Computational geometry; Computer graphics; Computer science; Huffman coding; Information geometry; Internet; Laplace equations; Solid modeling;
Conference_Titel :
Computer Graphics and Applications, 2000. Proceedings. The Eighth Pacific Conference on
Conference_Location :
Hong Kong
Print_ISBN :
0-7695-0868-5
DOI :
10.1109/PCCGA.2000.883969
