Rendering 2024 - Symposium Track
Permanent URI for this collection
Browse
Browsing Rendering 2024 - Symposium Track by Subject "!"
Now showing 1 - 2 of 2
Results Per Page
Sort Options
Item Estimating Uncertainty in Appearance Acquisition(The Eurographics Association, 2024) Zhou, Zhiqian; Zhang, Cheng; Dong, Zhao; Marshall, Carl; Zhao, Shuang; Haines, Eric; Garces, ElenaThe inference of material reflectance from physical observations (e.g., photographs) is usually under-constrained, causing point estimates to suffer from ambiguity and, thus, generalize poorly to novel configurations. Conventional methods address this problem by using dense observations or introducing priors. In this paper, we tackle this problem from a different angle by introducing a method to quantify uncertainties. Based on a Bayesian formulation, our method can quantitatively analyze how under-constrained a material inference problem is (given the observations and priors), by sampling the entire posterior distribution of material parameters rather than optimizing a single point estimate as given by most inverse rendering methods. Further, we present a method to guide acquisition processes by recommending viewing/lighting configurations for making additional observations. We demonstrate the usefulness of our technique using several synthetic and one real example.Item An Implementation Algorithm of 2D Sobol Sequence Fast, Elegant, and Compact(The Eurographics Association, 2024) Ahmed, Abdalla G. M.; Haines, Eric; Garces, ElenaWe present a novel algorithm to evaluate 2D Sobol samples, bringing the time complexity for m-bit resolution to O(log(m)) instead of O(m), thus gaining tangible performance boost. We take advantage of the geometric structure of the underlying Pascal matrix to factor it into diagonally-running matrices that are efficient to implement using bit-wise operations. We extend the method to inversion in global Sobol sampling. The algorithms form a flexible framework, able to generate several wellknown sample sequences as special cases. We compare the speed performance and memory footprint of our algorithms to state of the art implementations.