A sketch-based interface for classifying and visualizing vector fields

Wei, Jishang; Wang, Chaoli; Yu, Hongfeng; Ma, Kwan‐Liu

doi:10.1109/pacificvis.2010.5429603

Cited by 36 publications

(33 citation statements)

References 19 publications

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“…Closely related to our work are the work of Schlemmer et al [15], Wei et al [20], and Lu et al [10]. Schlemmer et al [15] leveraged moment invariants to detect 2D flow features which are invariant under translation, scaling and rotation.…”

Section: Related Workmentioning

confidence: 94%

“…Therefore, they are often used for more robust similarity measuring. In other approaches, the similarity between integral curves are measured in a transformed feature space [1,20,14].…”

Section: Related Workmentioning

confidence: 99%

“…However, their work is restrictive to 2D flow fields and patterns are detected based on local neighborhoods rather than integral curves. Wei et al [20] extracted features along reparameterized streamlines at equal arc length and used the edit distance to measure streamline similarity. Features of varying scales are only roughly captured by simply recording the length of each resampled streamline.…”

Section: Related Workmentioning

confidence: 99%

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FlowString: Partial Streamline Matching Using Shape Invariant Similarity Measure for Exploratory Flow Visualization

Tao

Wang

Shene

2014

2014 IEEE Pacific Visualization Symposium

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Measuring the similarity of integral curves is fundamental to many important flow data analysis and visualization tasks such as feature detection, pattern querying, streamline clustering and hierarchical exploration. In this paper, we introduce FlowString, a novel approach that extracts shape invariant features from streamlines and utilizes a string-based method for exploratory streamline analysis and visualization. Our solution first resamples streamlines by considering their local feature scales. We then classify resampled points along streamlines based on the shape similarity around their local neighborhoods. We encode each streamline into a string of well-selected shape characters, from which we construct meaningful words for querying and retrieval. A unique feature of our approach is that it captures intrinsic streamline similarity that is invariant under translation, rotation and scaling. Leveraging the suffix tree, we enable efficient search of streamline patterns with arbitrary lengths with the complexity linear to the size of the respective pattern. We design an intuitive interface and user interactions to support flexible querying, allowing exact and approximate searches for robust partial streamline similarity matching. Users can perform queries at either the character level or the word level, and define their own characters or words conveniently for customized search. We demonstrate the effectiveness of FlowString with several flow field data sets of different sizes and characteristics.

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Section: Related Workmentioning

confidence: 94%

“…Therefore, they are often used for more robust similarity measuring. In other approaches, the similarity between integral curves are measured in a transformed feature space [1,20,14].…”

Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

FlowString: Partial Streamline Matching Using Shape Invariant Similarity Measure for Exploratory Flow Visualization

Tao

Wang

Shene

2014

2014 IEEE Pacific Visualization Symposium

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“…Hereby comparisons are not performed on data at a specific location, but over a set of features present in the flow field. Similarities can then be defined by the presence or absence of common feature types, shapes, or properties (see for example [32,19] for feature based similarity metrics in flow fields). The techniques presented in this paper represent a hybrid method -comparisons are performed in data-space, while relying on the transport property computed from flow trajectories.…”

Section: Materials Transportmentioning

confidence: 99%

Comparative Visual Analysis of Lagrangian Transport in CFD Ensembles

Hummel

Obermaier

Garth

et al. 2013

IEEE Trans. Visual. Comput. Graphics

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Fig. 1. An ensemble of a 2D convection flow field is analyzed using the proposed joint variance visualization techniques. From left to right: Individual variances of four of the data set runs show high variances around the heating cylinder. Brushing in the classification space allows for the identification of similar (green), dissimilar (red), and uncertain regions (blue and white). Together with a color mapped visualization of the ensemble domain and interactive pathline seeding, a complete analysis of transport is possible.Abstract-Sets of simulation runs based on parameter and model variation, so-called ensembles, are increasingly used to model physical behaviors whose parameter space is too large or complex to be explored automatically. Visualization plays a key role in conveying important properties in ensembles, such as the degree to which members of the ensemble agree or disagree in their output. For ensembles of time-varying vector fields, there are numerous challenges for providing an expressive comparative visualization, among which is the requirement to relate the effect of individual flow divergence to joint transport characteristics of the ensemble. Yet, techniques developed for scalar ensembles are of little use in this context, as the notion of transport induced by a vector field cannot be modeled using such tools. We develop a Lagrangian framework for the comparison of flow fields in an ensemble. Our techniques evaluate individual and joint transport variance and introduce a classification space that facilitates incorporation of these properties into a common ensemble visualization. Variances of Lagrangian neighborhoods are computed using pathline integration and Principal Components Analysis. This allows for an inclusion of uncertainty measurements into the visualization and analysis approach. Our results demonstrate the usefulness and expressiveness of the presented method on several practical examples.

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“…Their interface design strikes a good balance between supporting artistic freedom and maintaining the accuracy with respect to the underlying vector field data. Wei et al [24] targeted 3D flow fields and presented a solution that allows the user to sketch a 2D curve for pattern matching in 2D and streamline clustering in 3D. They also explored another way that creates streamline templates hierarchically to support on-the-fly partial streamline matching in a progressive manner.…”

Section: Related Workmentioning

confidence: 99%

FlowGraph: A compound hierarchical graph for flow field exploration

Wang

2013

2013 IEEE Pacific Visualization Symposium (PacificVis)

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Visual exploration of large and complex 3D flow fields is critically important for understanding many aero-and hydro-dynamical systems that dominate various physical and natural phenomena in the world. In this paper, we introduce the FlowGraph, a novel compound graph representation that organizes streamline clusters and spatial regions hierarchically for occlusion-free and controllable visual exploration. Our approach works with any seeding strategies as long as the domain is well covered and important flow features are captured. By transforming a flow field to a graph representation, we enable observation and exploration of the relationships among streamline clusters, spatial regions and their interconnection in the transformed space. The FlowGraph not only provides a visual mapping that abstracts streamline clusters and spatial regions in various levels of detail, but also serves as a navigation tool that guides flow field exploration and understanding. Through brushing and linking in conjunction with the spatial streamline view, we demonstrate the effectiveness of FlowGraph with several visual exploration and comparison tasks that can not be well accomplished using the streamline view alone. As occlusion and clutter are almost ubiquitous in 3D flows, the FlowGraph represents a promising direction for enhancing our ability to understand large and complex flow field data.

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A sketch-based interface for classifying and visualizing vector fields

Cited by 36 publications

References 19 publications

FlowString: Partial Streamline Matching Using Shape Invariant Similarity Measure for Exploratory Flow Visualization

FlowString: Partial Streamline Matching Using Shape Invariant Similarity Measure for Exploratory Flow Visualization

Comparative Visual Analysis of Lagrangian Transport in CFD Ensembles

FlowGraph: A compound hierarchical graph for flow field exploration

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