705 research outputs found
Visual Computing in Materials Sciences (Dagstuhl Seminar 19151)
Visual computing has become highly attractive for boosting research endeavors in the materials science domain. Using visual computing, a multitude of different phenomena may now be studied, at various scales, dimensions, or using different modalities. This was simply impossible before. Visual computing techniques generate novel insights to understand, discover, design, and use complex material systems of interest. Its huge potential for retrieving and visualizing (new) information on materials, their characteristics and interrelations as well as on simulating the material's behavior in its target application environment is of core relevance to material scientists. This Dagstuhl seminar on Visual Computing in Materials Sciences thus focuses on the intersection of both domains to guide research endeavors in this field. It targets to provide answers regarding the following four challenges, which are of imminent need:
-The Integrated Visual Analysis Challeng identifies standard visualization tools as insufficient for exploring materials science data in detail. What is required are integrated visual analysis tools, which are tailored to a specific application area and guide users in their investigations. Using linked views and other interaction concepts, these tools are required to combine all data domains using meaningful and easy to understand visualization techniques. Especially for the analysis of spatial and temporal data in dynamic processes (e.g., materials tested under load or in different environmental conditions) or multimodal, multiscale data, these tools and techniques are highly anticipated. Only integrated analysis concepts allow to make the most out of all the data available.
- The Quantitative Data Visualization Challenge centers around the design and implementation of tailored visual analysis systems for extracting and analyzing derived data (e.g., computed from extracted features over spatial, temporal or even higher dimensional domains). Therefore, feature extraction and quantification techniques, segmentation techniques, or clustering techniques, are required as prerequisites for the targeted visual analysis. As the quantification may easily end up in 25 or more properties to be computed per feature, clustering techniques allow to distinguish features of interest into feature classes. These feature classes may then be statistically evaluated to visualize the properties of the individual features as well as the properties of the different classes. Information visualization techniques will be of special interest for solving this challenge.
- The Visual Debugger Challenge is an idea which uses visual analysis to remove errors in the parametrization of a simulation or a data acquisition process. Similarly, to a debugger in computer programming, identifying errors in the code and providing hints to improve, a visual debugger in the domain of visual computing for materials science should show the following characteristics: It should indicate errors and identify wrongly used algorithms in the data analysis. Such a tool should also identify incorrect parameters, which either show no or very limited benefit or even provide erroneous results. Furthermore, it should give directions on how to improve a targeted analysis and suggest suitable algorithms or pipelines for specific tasks.
- The Interactive Steering Challenge uses visual analysis tools to control a running simulation or an ongoing data acquisition process. Respective tools monitor costly processes and give directions to improve results regarding the respective targets. For example, in the material analysis domain, this could be a system which provides settings for improved data acquisition based on the current image quality achieved: If the image quality does no more fulfill the target requirements, the system influences all degrees of freedom in the data acquisition to enhance image quality. The same holds for the materials simulation domain. Visual analysis can help to steer target material properties in a specific application environment by predicting tendencies of costly simulation runs, e.g., using cheaper surrogate models
Learning Multiple-Scattering Solutions for Sphere-Tracing of Volumetric Subsurface Effects
Code for reproducing the results in "Learning Multiple-Scattering Solutions for Sphere-Tracing of Volumetric Subsurface Effects", Leonard, L., Höhlein, K. and Westermann, R. (Eurographics, 2021
Réplica à Antonio Hohlfeldt
In this review, the author responds to criticisms made by Antonio Hohlfeldt about the book by Francisco Rüdiger.Nesta resenha, o autor responde às críticas realizadas por Antonio Hohlfeldt a cerca do livro de Francisco Rüdiger
Réplica à Antonio Hohlfeldt
In this review, the author responds to criticisms made by Antonio Hohlfeldt about the book by Francisco Rüdiger.Nesta resenha, o autor responde às críticas realizadas por Antonio Hohlfeldt a cerca do livro de Francisco Rüdiger
khoehlein/Permutation-invariant-Postprocessing: Preliminary code release with DOI batch
Code for paper "Postprocessing of Ensemble Weather Forecasts Using Permutation-invariant Neural Networks" by Kevin Höhlein, Benedikt Schulz, Rüdiger Westermann and Sebastian Lerch
Code "Postprocessing of Ensemble Weather Forecasts Using Permutation-invariant Neural Networks"
Code for paper "Postprocessing of Ensemble Weather Forecasts Using Permutation-invariant Neural Networks" by Kevin Höhlein, Benedikt Schulz, Rüdiger Westermann and Sebastian Lerch
A Globally Conforming Lattice Structure for 2D Stress Tensor Visualization
We present a visualization technique for 2D stress tensor fields based on the construction of a globally conforming lattice. Conformity ensures that the lattice edges follow the principal stress directions and the aspect ratio of lattice elements represents the stress anisotropy. Since such a lattice structure cannot be space-filling in general, it is constructed from multiple intersecting lattice beams. Conformity at beam intersections is ensured via a constrained optimization problem, by computing the aspect ratio of elements at intersections so that their edges meet when continued along the principal stress lines. In combination with a coloring scheme that encodes relative stress magnitudes, a global visualization is achieved. By introducing additional constraints on the positional variation of the beam intersections, coherent visualizations are achieved when external loads or material parameters are changed. In a number of experiments using non-trivial scenarios, we demonstrate the capability of the proposed visualization technique to show the global and local structure of a given stress field.Accepted Author ManuscriptMaterials and Manufacturin
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