Evaluating Isosurfaces with Level‐set‐based Information Maps

Wei, Tzu-Hsuan; Lee, Teng-Yok; Shen, Han‐Wei

doi:10.1111/cgf.12087

Cited by 11 publications

(6 citation statements)

References 23 publications

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“…This holistic nature of information-theoretic reasoning has enabled many applications in visualization, including light source placement by Gumhold [33], view selection in mesh rendering by Vázquez et al [64] and Feixas et al [22], view selection in volume rendering by Bordoloi and Shen [5], and Takahashi and Takeshima [56], focus of attention in volume rendering by Viola et al [66], multi-resolution volume visualization by Wang and Shen [68], feature highlighting in unsteady multi-field visualization by Jänicke and Scheuermann [35,37], feature highlighting in time-varying volume visualization by Wang et al [70], transfer function design by Bruckner and Möller [10], and by Ruiz et al [8,49], multimodal data fusion by Bramon et al [6], evaluating isosurfaces [74], measuring of observation capacity [7], measuring information content in multivariate data [23], and confirming the mathematical feasibility of visual multiplexing [15].…”

Section: Related Workmentioning

confidence: 99%

What May Visualization Processes Optimize?

Chen

Golan

2016

IEEE Trans. Visual. Comput. Graphics

144

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Abstract-In this paper, we present an abstract model of visualization and inference processes and describe an information-theoretic measure for optimizing such processes. In order to obtain such an abstraction, we first examined six classes of workflows in data analysis and visualization, and identified four levels of typical visualization components, namely disseminative, observational, analytical and model-developmental visualization. We noticed a common phenomenon at different levels of visualization, that is, the transformation of data spaces (referred to as alphabets) usually corresponds to the reduction of maximal entropy along a workflow. Based on this observation, we establish an information-theoretic measure of cost-benefit ratio that may be used as a cost function for optimizing a data visualization process. To demonstrate the validity of this measure, we examined a number of successful visualization processes in the literature, and showed that the information-theoretic measure can mathematically explain the advantages of such processes over possible alternatives.

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Section: Related Workmentioning

confidence: 99%

What May Visualization Processes Optimize?

Chen

Golan

2016

IEEE Trans. Visual. Comput. Graphics

144

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“…Information theory has been used extensively in visualization [ 8 ]. It has enabled many applications in visualization, including scene and shape complexity analysis by Feixas et al [ 9 ] and Rigau et al [ 10 ], light source placement by Gumhold [ 11 ], view selection in mesh rendering by Vázquez et al [ 12 ] and Feixas et al [ 13 ], attribute selection by Ng and Martin [ 14 ], view selection in volume rendering by Bordoloi and Shen [ 15 ], and Takahashi and Takeshima [ 16 ], multi-resolution volume visualization by Wang and Shen [ 17 ], focus of attention in volume rendering by Viola et al [ 18 ], feature highlighting by Jänicke and Scheuermann [ 19 , 20 ], and Wang et al [ 21 ], transfer function design by Bruckner and Möller [ 22 ], and Ruiz et al [ 23 , 24 ], multi-modal data fusion by Bramon et al [ 25 ], isosurface evaluation by Wei et al [ 26 ], measuring observation capacity by Bramon et al [ 27 ], measuring information content by Biswas et al [ 28 ], proving the correctness of “overview first, zoom, details-on-demand” by Chen and Jänicke [ 29 ] and Chen et al [ 8 ], and confirming visual multiplexing by Chen et al [ 30 ].…”

Section: Related Workmentioning

confidence: 99%

A Bounded Measure for Estimating the Benefit of Visualization (Part I): Theoretical Discourse and Conceptual Evaluation

Chen

Sbert

2022

Entropy

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Information theory can be used to analyze the cost–benefit of visualization processes. However, the current measure of benefit contains an unbounded term that is neither easy to estimate nor intuitive to interpret. In this work, we propose to revise the existing cost–benefit measure by replacing the unbounded term with a bounded one. We examine a number of bounded measures that include the Jenson–Shannon divergence, its square root, and a new divergence measure formulated as part of this work. We describe the rationale for proposing a new divergence measure. In the first part of this paper, we focus on the conceptual analysis of the mathematical properties of these candidate measures. We use visualization to support the multi-criteria comparison, narrowing the search down to several options with better mathematical properties. The theoretical discourse and conceptual evaluation in this part provides the basis for further data-driven evaluation based on synthetic and experimental case studies that are reported in the second part of this paper.

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“…For scalar datasets, Bruckner et al [ 40 ] used MI to identify the isosurface similarities. Wei et al [ 41 ] used MI to compute representativeness of isosurfaces via a level-sets for volumetric data. Bramon et al [ 42 ] used MI between data values and color pixels to compute information transfer.…”

Section: Related Workmentioning

confidence: 99%

Multivariate Pointwise Information-Driven Data Sampling and Visualization

Dutta

Biswas

Ahrens

2019

Entropy

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With increasing computing capabilities of modern supercomputers, the size of the data generated from the scientific simulations is growing rapidly. As a result, application scientists need effective data summarization techniques that can reduce large-scale multivariate spatiotemporal data sets while preserving the important data properties so that the reduced data can answer domain-specific queries involving multiple variables with sufficient accuracy. While analyzing complex scientific events, domain experts often analyze and visualize two or more variables together to obtain a better understanding of the characteristics of the data features. Therefore, data summarization techniques are required to analyze multi-variable relationships in detail and then perform data reduction such that the important features involving multiple variables are preserved in the reduced data. To achieve this, in this work, we propose a data sub-sampling algorithm for performing statistical data summarization that leverages pointwise information theoretic measures to quantify the statistical association of data points considering multiple variables and generates a sub-sampled data that preserves the statistical association among multi-variables. Using such reduced sampled data, we show that multivariate feature query and analysis can be done effectively. The efficacy of the proposed multivariate association driven sampling algorithm is presented by applying it on several scientific data sets.

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Evaluating Isosurfaces with Level‐set‐based Information Maps

Cited by 11 publications

References 23 publications

What May Visualization Processes Optimize?

What May Visualization Processes Optimize?

A Bounded Measure for Estimating the Benefit of Visualization (Part I): Theoretical Discourse and Conceptual Evaluation

Multivariate Pointwise Information-Driven Data Sampling and Visualization

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