High-Quality Ultra-Compact Grid Layout of Grouped Networks

Yoghourdjian, Vahan; Dwyer, Tim; Gange, Graeme; Kieffer, Steve; Klein, Karsten; Marriott, Kim

doi:10.1109/tvcg.2015.2467251

Cited by 34 publications

(27 citation statements)

References 39 publications

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“…As in a spreadsheet, the largest node (e.g., an expanded workflow) defines the width for the remaining cells in the same column, which results in long edges to nodes in adjacent columns. Other layout approaches might create a more compact layout (e.g., [ YDG*15 ]), but must also consider the characteristics of the data provenance graph (see Section 2) and the interactive requirements to ensure fluid transitions when changing hierarchy levels. Since edge crossings decrease the readability of the graph, they are to be minimized.…”

Section: Discussionmentioning

confidence: 99%

AVOCADO: Visualization of Workflow–Derived Data Provenance for Reproducible Biomedical Research

Stitz

Luger

Streit

et al. 2016

Computer Graphics Forum

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A major challenge in data-driven biomedical research lies in the collection and representation of data provenance information to ensure that findings are reproducibile. In order to communicate and reproduce multi-step analysis workflows executed on datasets that contain data for dozens or hundreds of samples, it is crucial to be able to visualize the provenance graph at different levels of aggregation. Most existing approaches are based on node-link diagrams, which do not scale to the complexity of typical data provenance graphs. In our proposed approach, we reduce the complexity of the graph using hierarchical and motif-based aggregation. Based on user action and graph attributes, a modular degree-of-interest (DoI) function is applied to expand parts of the graph that are relevant to the user. This interest-driven adaptive approach to provenance visualization allows users to review and communicate complex multi-step analyses, which can be based on hundreds of files that are processed by numerous workflows. We have integrated our approach into an analysis platform that captures extensive data provenance information, and demonstrate its effectiveness by means of a biomedical usage scenario.

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Section: Discussionmentioning

confidence: 99%

AVOCADO: Visualization of Workflow–Derived Data Provenance for Reproducible Biomedical Research

Stitz

Luger

Streit

et al. 2016

Computer Graphics Forum

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“…The LNS metaheuristic was first proposed in [50]. It has been successfully applied in recent years to problems of different nature, for instance Vehicle Routing Problems, [16,40,48], Scheduling, [35,46] and Visualization [59]. Roughly speaking, LNS performs a search for good solutions in a neighborhood of a starting point.…”

Section: A Large Neighborhood Search Approachmentioning

confidence: 99%

Visualizing proportions and dissimilarities by Space-filling maps: A Large Neighborhood Search approach

Carrizosa

Guerrero

Morales

2017

Computers & Operations Research

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In this paper we address the problem of visualizing a set of individuals, which have attached a statistical value given as a proportion, and a dissimilarity measure. Each individual is represented as a region within the unit square, in such a way that the area of the regions represent the proportions and the distances between them represent the dissimilarities. To enhance the interpretability of the representation, the regions are required to satisfy two properties. First, they must form a partition of the unit square, namely, the portions in which it is divided must cover its area without overlapping. Second, the portions must be made of a connected union of rectangles which verify the so-called box-connectivity constraints, yielding a visualization map called Space-filling Box-connected Map (SBM). The construction of an SBM is formally stated as a mathematical optimization problem, which is solved heuristically by using the Large Neighborhood Search technique. The methodology proposed in this paper is applied to three real-world datasets: the first one concerning financial markets in Europe and Asia, the second one about the letters in the English alphabet, and finally the provinces of The Netherlands as a geographical application.

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“…Such contours share the characteristics of set diagrams such as Euler diagrams. Contour shapes are versatile, for instance, rectangles [DGC*05, DHRMM13, HRD10, YDG*15] (Figures b.2 and b.3), circle sections [ET07] or circles [Hol06, KG06, NIS15] (Figure b.1), convex hulls [BPF14, ST08, WWY*15], arbitrary two‐dimensional curves or splines [BBT06, BD05, BT06, BT09b, DEKB*14, DvKSW12, EHKP14, GHK10, HGK10, HKV14, LQB12, VPF*14] (Figure c), or three‐dimensional bubbles [BD07, SBG00]. The GMap approach [GHK10, HGK10, HKV14] creates a map of contours that are adjacent to each other using a Voronoi tessellation.…”

Section: Taxonomy Of Vertex Group Structure Visualizationsmentioning

confidence: 99%

“…To untangle overlapping contours, Henry Riche and Dwyer [HRD10] introduced two techniques for rectangular contour overlays: a splitting approach (groups with intersections are split up, drawn as non‐overlapping rectangular shapes, and linked by lines) and a duplication approach (Figure b.2) (groups are represented by overlaid rectangles and nodes contained in several groups are duplicated and linked visually). For disjoint hierarchical group structures , the contours or surfaces are nested to encode the hierarchical structure visually [BD05, BD07, DGC*05, DHRMM13, Hol06, KG06, SBG00, YDG*15] (e.g. Figure b.3).…”

Section: Taxonomy Of Vertex Group Structure Visualizationsmentioning

confidence: 99%

Visualizing Group Structures in Graphs: A Survey

Vehlow

Beck

Weiskopf

2016

Computer Graphics Forum

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Graph visualizations encode relationships between objects. Abstracting the objects into group structures provides an overview of the data. Groups can be disjoint or overlapping, and might be organized hierarchically. However, the underlying graph still needs to be represented for analyzing the data in more depth. This work surveys research in visualizing group structures as part of graph diagrams. A particular focus is the explicit visual encoding of groups, rather than only using graph layout to indicate groups implicitly. We introduce a taxonomy of visualization techniques structuring the field into four main categories: visual node attributes vary properties of the node representation to encode the grouping, juxtaposed approaches use two separate visualizations, superimposed techniques work with two aligned visual layers, and embedded visualizations tightly integrate group and graph representation. The derived taxonomies for group structure and visualization types are also applied to group visualizations of edges. We survey group-only, group-node, group-edge and group-network tasks that are described in the literature as use cases of group visualizations. We discuss results from evaluations of existing visualization techniques as well as main areas of application. Finally, we report future challenges based on interviews we conducted with leading researchers of the field.

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High-Quality Ultra-Compact Grid Layout of Grouped Networks

Cited by 34 publications

References 39 publications

AVOCADO: Visualization of Workflow–Derived Data Provenance for Reproducible Biomedical Research

AVOCADO: Visualization of Workflow–Derived Data Provenance for Reproducible Biomedical Research

Visualizing proportions and dissimilarities by Space-filling maps: A Large Neighborhood Search approach

Visualizing Group Structures in Graphs: A Survey

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