Showing total 2 results

1. Modeling Bidirectional Texture Functions with Multivariate Spherical Radial Basis Functions.

Author

Tsai, Yu-Ting, Fang, Kuei-Li, Lin, Wen-Chieh, and Shih, Zen-Chung

Subjects

TEXTURE mapping, MULTIVARIATE analysis, ALGORITHMS, APPROXIMATION theory, REFLECTANCE, PARAMETER estimation, MATHEMATICAL optimization, COMPUTER simulation

Abstract

This paper presents a novel parametric representation for bidirectional texture functions. Our method mainly relies on two original techniques, namely, multivariate spherical radial basis functions (SRBFs) and optimized parameterization. First, since the surface appearance of a real-world object is frequently a mixed effect of different physical factors, the proposed sum-of-products model based on multivariate SRBFs especially provides an intrinsic and efficient representation for heterogenous materials. Second, optimized parameterization particularly aims at overcoming the major disadvantage of traditional fixed parameterization. By using a parametric model to account for variable transformations, the parameterization process can be tightly integrated with multivariate SRBFs into a unified framework. Finally, a hierarchical fitting algorithm for bidirectional texture functions is developed to exploit spatial coherence and reduce computational cost. Our experimental results further reveal that the proposed representation can easily achieve high-quality approximation and real-time rendering performance. [ABSTRACT FROM AUTHOR]

Published

2011

2. Optimal Combination of Nested Clusters by a Greedy Approximation Algorithm.

Author

Dang, Edward K. F., Luk, Robert W. P., Lee, D. L., Ho, K. S., and Chan, Stephen C. F.

Subjects

COMBINATORIAL optimization, CLUSTER set theory, ALGORITHMS, APPROXIMATION theory, MATHEMATICAL optimization

Abstract

Given a set of clusters, we consider an optimization problem which seeks a subset of clusters that maximizes the microaverage F-measure. This optimal value can be used as an evaluation measure of the goodness of clustering. For arbitrarily overlapping clusters, finding the optimal value is NP-hard. We claim that a greedy approximation algorithm yields the global optimal solution for clusters that overlap only by nesting. We present a mathematical proof of this claim by induction. For a family of n clusters containing a total of N objects, this algorithm has an O(n²) time complexity and O(N) space complexity. [ABSTRACT FROM AUTHOR]

Published

2009