Your search keyword '"Wang, Yunhai"' showing total 7 results

1. Data-Driven Colormap Adjustment for Exploring Spatial Variations in Scalar Fields.

Author

Zeng, Qiong, Zhao, Yongwei, Wang, Yinqiao, Zhang, Jian, Cao, Yi, Tu, Changhe, Viola, Ivan, and Wang, Yunhai

Subjects

SPATIAL variation, DATA distribution, IMAGE color analysis, STATISTICS, HISTOGRAMS, SCALAR field theory

Abstract

Colormapping is an effective and popular visualization technique for analyzing patterns in scalar fields. Scientists usually adjust a default colormap to show hidden patterns by shifting the colors in a trial-and-error process. To improve efficiency, efforts have been made to automate the colormap adjustment process based on data properties (e.g., statistical data value or histogram distribution). However, as the data properties have no direct correlation to the spatial variations, previous methods may be insufficient to reveal the dynamic range of spatial variations hidden in the data. To address the above issues, we conduct a pilot analysis with domain experts and summarize three requirements for the colormap adjustment process. Based on the requirements, we formulate colormap adjustment as an objective function, composed of a boundary term and a fidelity term, which is flexible enough to support interactive functionalities. We compare our approach with alternative methods under a quantitative measure and a qualitative user study (25 participants), based on a set of data with broad distribution diversity. We further evaluate our approach via three case studies with six domain experts. Our method is not necessarily more optimal than alternative methods of revealing patterns, but rather is an additional color adjustment option for exploring data with a dynamic range of spatial variations. [ABSTRACT FROM AUTHOR]

Published

2022

2. Joint t -SNE for Comparable Projections of Multiple High-Dimensional Datasets.

Author

Wang, Yinqiao, Chen, Lu, Jo, Jaemin, and Wang, Yunhai

Subjects

DISTRIBUTION (Probability theory), TASK analysis

Abstract

We present Joint t-Stochastic Neighbor Embedding (Joint t-SNE), a technique to generate comparable projections of multiple high-dimensional datasets. Although t-SNE has been widely employed to visualize high-dimensional datasets from various domains, it is limited to projecting a single dataset. When a series of high-dimensional datasets, such as datasets changing over time, is projected independently using t-SNE, misaligned layouts are obtained. Even items with identical features across datasets are projected to different locations, making the technique unsuitable for comparison tasks. To tackle this problem, we introduce edge similarity, which captures the similarities between two adjacent time frames based on the Graphlet Frequency Distribution (GFD). We then integrate a novel loss term into the t-SNE loss function, which we call vector constraints, to preserve the vectors between projected points across the projections, allowing these points to serve as visual landmarks for direct comparisons between projections. Using synthetic datasets whose ground-truth structures are known, we show that Joint t-SNE outperforms existing techniques, including Dynamic t-SNE, in terms of local coherence error, Kullback-Leibler divergence, and neighborhood preservation. We also showcase a real-world use case to visualize and compare the activation of different layers of a neural network. [ABSTRACT FROM AUTHOR]

Published

2022

3. SPEULER: Semantics-preserving Euler Diagrams.

Author

Kehlbeck, Rebecca, Gortler, Jochen, Wang, Yunhai, and Deussen, Oliver

Subjects

REPRESENTATIONS of graphs, VISUALIZATION, TASK analysis, INFORMATION design

Abstract

Creating comprehensible visualizations of highly overlapping set-typed data is a challenging task due to its complexity. To facilitate insights into set connectivity and to leverage semantic relations between intersections, we propose a fast two-step layout technique for Euler diagrams that are both well-matched and well-formed. Our method conforms to established form guidelines for Euler diagrams regarding semantics, aesthetics, and readability. First, we establish an initial ordering of the data, which we then use to incrementally create a planar, connected, and monotone dual graph representation. In the next step, the graph is transformed into a circular layout that maintains the semantics and yields simple Euler diagrams with smooth curves. When the data cannot be represented by simple diagrams, our algorithm always falls back to a solution that is not well-formed but still well-matched, whereas previous methods often fail to produce expected results. We show the usefulness of our method for visualizing set-typed data using examples from text analysis and infographics. Furthermore, we discuss the characteristics of our approach and evaluate our method against state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2022

4. Revisiting Dimensionality Reduction Techniques for Visual Cluster Analysis: An Empirical Study.

Author

Xia, Jiazhi, Zhang, Yuchen, Song, Jie, Chen, Yang, Wang, Yunhai, and Liu, Shixia

Subjects

CLUSTER analysis (Statistics), NONNEGATIVE matrices, MATRIX decomposition, EMPIRICAL research, TASK analysis

Abstract

Dimensionality Reduction (DR) techniques can generate 2D projections and enable visual exploration of cluster structures of high-dimensional datasets. However, different DR techniques would yield various patterns, which significantly affect the performance of visual cluster analysis tasks. We present the results of a user study that investigates the influence of different DR techniques on visual cluster analysis. Our study focuses on the most concerned property types, namely the linearity and locality, and evaluates twelve representative DR techniques that cover the concerned properties. Four controlled experiments were conducted to evaluate how the DR techniques facilitate the tasks of 1) cluster identification, 2) membership identification, 3) distance comparison, and 4) density comparison, respectively. We also evaluated users' subjective preference of the DR techniques regarding the quality of projected clusters. The results show that: 1) Non-linear and Local techniques are preferred in cluster identification and membership identification; 2) Linear techniques perform better than non-linear techniques in density comparison; 3) UMAP (Uniform Manifold Approximation and Projection) and t-SNE (t-Distributed Stochastic Neighbor Embedding) perform the best in cluster identification and membership identification; 4) NMF (Nonnegative Matrix Factorization) has competitive performance in distance comparison; 5) t-SNLE (t-Distributed Stochastic Neighbor Linear Embedding) has competitive performance in density comparison. [ABSTRACT FROM AUTHOR]

Published

2022

5. F2-Bubbles: Faithful Bubble Set Construction and Flexible Editing.

Author

Wang, Yunhai, Cheng, Da, Wang, Zhirui, Zhang, Jian, Zhou, Liang, He, Gaoqi, and Deussen, Oliver

Subjects

MICROELECTROMECHANICAL systems, APPROXIMATION algorithms, VISUALIZATION, SPANNING trees, EDITING

Abstract

In this paper, we propose F2-Bubbles, a set overlay visualization technique that addresses overlapping artifacts and supports interactive editing with intelligent suggestions. The core of our method is a new, efficient set overlay construction algorithm that approximates the optimal set overlay by considering set elements and their non-set neighbors. Thanks to the efficiency of the algorithm, interactive editing is achieved, and with intelligent suggestions, users can easily and flexibly edit visualizations through direct manipulations with local adaptations. A quantitative comparison with state-of-the-art set visualization techniques and case studies demonstrate the effectiveness of our method and suggests that F2-Bubbles is a helpful technique for set visualization. [ABSTRACT FROM AUTHOR]

Published

2022

6. Palettailor: Discriminable Colorization for Categorical Data.

Author

Lu, Kecheng, Feng, Mi, Chen, Xin, Sedlmair, Michael, Deussen, Oliver, Lischinski, Dani, Cheng, Zhanglin, and Wang, Yunhai

Subjects

MATHEMATICAL category theory, VISUAL discrimination, COLORS, COLOR vision, IMAGE color analysis, SIMULATED annealing

Abstract

We present an integrated approach for creating and assigning color palettes to different visualizations such as multi-class scatterplots, line, and bar charts. While other methods separate the creation of colors from their assignment, our approach takes data characteristics into account to produce color palettes, which are then assigned in a way that fosters better visual discrimination of classes. To do so, we use a customized optimization based on simulated annealing to maximize the combination of three carefully designed color scoring functions: point distinctness, name difference, and color discrimination. We compare our approach to state-of-the-art palettes with a controlled user study for scatterplots and line charts, furthermore we performed a case study. Our results show that Palettailor, as a fully-automated approach, generates color palettes with a higher discrimination quality than existing approaches. The efficiency of our optimization allows us also to incorporate user modifications into the color selection process. [ABSTRACT FROM AUTHOR]

Published

2021

7. SineStream: Improving the Readability of Streamgraphs by Minimizing Sine Illusion Effects.

Author

Bu, Chuan, Zhang, Quanjie, Wang, Qianwen, Zhang, Jian, Sedlmair, Michael, Deussen, Oliver, and Wang, Yunhai

Subjects

HIERARCHICAL clustering (Cluster analysis), ALGORITHMS, GEOMETRY, TASK analysis

Abstract

In this paper, we propose SineStream, a new variant of streamgraphs that improves their readability by minimizing sine illusion effects. Such effects reflect the tendency of humans to take the orthogonal rather than the vertical distance between two curves as their distance. In SineStream, we connect the readability of streamgraphs with minimizing sine illusions and by doing so provide a perceptual foundation for their design. As the geometry of a streamgraph is controlled by its baseline (the bottom-most curve) and the ordering of the layers, we re-interpret baseline computation and layer ordering algorithms in terms of reducing sine illusion effects. For baseline computation, we improve previous methods by introducing a Gaussian weight to penalize layers with large thickness changes. For layer ordering, three design requirements are proposed and implemented through a hierarchical clustering algorithm. Quantitative experiments and user studies demonstrate that SineStream improves the readability and aesthetics of streamgraphs compared to state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2021