| Graph drawingGraphic representation of a minute fraction of the WWW, demonstrating hyperlinks. Graph drawing is an area of mathematics and computer science combining methods from geometric graph theory and information visualization to derive two-dimensional depictions of graphs arising from applications such as social network analysis, cartography, and bioinformatics.[1] A drawing of a graph or network diagram is a pictorial representation of the vertices and edges of a graph. This drawing should not be confused with the graph itself: very different layouts can correspond to the same graph.[2] In the abstract, all that matters is which pairs vertices are connected by edges. In the concrete, however, the arrangement of these vertices and edges within a drawing affects its understandability, usability, fabrication cost, and aesthetics.[3] The problem gets worse, if the graph changes over time by adding and deleting edges (dynamic graph drawing) and the goal is to preserve the user's mental map.[4] Graphical conventionsGraphs are frequently drawn as node-link diagrams in which the vertices are represented as disks or boxes and the edges are represented as line segments, polylines, or curves in the Euclidean plane.[3] In the case of directed graphs, arrowheads form a commonly used graphical convention to show their orientation;[2] however, user studies have shown that other conventions such as tapering provide this information more effectively.[5] Alternative conventions to node-link diagrams include adjacency representations such as circle packings, in which vertices are represented by disjoint regions in the plane and edges are represented by adjacencies between regions; intersection representations in which vertices are represented by non-disjoint geometric objects and edges are represented by their intersections; visibility representations in which vertices are represented by regions in the plane and edges are represented by regions that have an unobstructed line of sight to each other; confluent drawings, in which edges are represented as smooth curves within mathematical train tracks; and visualizations of the adjacency matrix of the graph. Quality measuresMany different quality measures have been defined for graph drawings, in an attempt to find objective means of evaluating their aesthetics and usability.[6] In addition to guiding the choice between different layout methods for the same graph, some layout methods attempt to directly optimize these measures. - The crossing number of a drawing is the number of pairs of edges that cross each other. If the graph is planar, then it is often convenient to draw it without any edge intersections; that is, in this case, a graph drawing represents a graph embedding. However, nonplanar graphs frequently arise in applications, so graph drawing algorithms must generally allow for edge crossings.[7]
- The area of a drawing is the size of its smallest bounding box, relative to the closest distance between any two vertices. Drawings with smaller area are generally preferable to those with larger area, because they allow the features of the drawing to be shown at greater size and therefore more legibly. The aspect ratio of the bounding box may also be important.
- Symmetry display is the problem of finding symmetry groups within a given graph, and finding a drawing that displays as much of the symmetry as possible. Some layout methods automatically lead to symmetric drawings; alternatively, some drawing methods start by finding symmetries in the input graph and using them to construct a drawing.[8]
- It is important that edges have shapes that are as simple as possible, to make it easier for the eye to follow them. In polyline drawings, the complexity of an edge may be measured by its number of bends, and many methods aim to provide drawings with few total bends or few bends per edge. Similarly for spline curves the complexity of an edge may be measured by the number of control points on the edge.
- Several commonly used quality measures concern lengths of edges: it is generally desirable to minimize the total length of the edges as well as the maximum length of any edge. Additionally, it may be preferable for the lengths of edges to be uniform rather than highly varied.
- Angular resolution is a measure of the sharpest angles in a graph drawing. If a graph has vertices with high degree then it necessarily will have small angular resolution, but the angular resolution can be bounded below by a function of the degree.[9]
- The slope number of a graph is the minimum number of distinct edge slopes needed in a drawing with straight line segment edges (allowing crossings). Cubic graphs have slope number at most four, but graphs of degree five may have unbounded slope number; it remains open whether the slope number of degree-4 graphs is bounded.[9]
Layout methodsThere are many different graph layout strategies: - In force-based layout systems, the graph drawing software modifies an initial vertex placement by continuously moving the vertices according to a system of forces based on physical metaphors related to systems of springs or molecular mechanics. Typically, these systems combine attractive forces between adjacent vertices with repulsive forces between all pairs of vertices, in order to seek a layout in which edge lengths are small while vertices are well-separated. These systems may perform gradient descent based minimization of an energy function, or they may translate the forces directly into velocities or accelerations for the moving vertices.[10]
- Spectral layout methods use as coordinates the eigenvectors of a matrix such as the Laplacian derived from the adjacency matrix of the graph.[11]
- Orthogonal layout methods, which allow the edges of the graph to run horizontally or vertically, parallel to the coordinate axes of the layout. These methods were originally designed for VLSI and PCB layout problems but they have also been adapted for graph drawing. They typically involve a multiphase approach in which an input graph is planarized by replacing crossing points by vertices, a topological embedding of the planarized graph is found, edge orientations are chosen to minimize bends, vertices are placed consistently with these orientations, and finally a layout compaction stage reduces the area of the drawing.[12]
- Tree layout algorithms these show a rooted tree-like formation, suitable for trees. Often, in a technique called "balloon layout", the children of each node in the tree are drawn on a circle surrounding the node, with the radii of these circles diminishing at lower levels in the tree so that these circles do not overlap.[13]
- Layered graph drawing methods (often called Sugiyama-style drawing) are best suited for directed acyclic graphs or graphs that are nearly acyclic, such as the graphs of dependencies between modules or functions in a software system. In these methods, the nodes of the graph are arranged into horizontal layers using methods such as the Coffman–Graham algorithm, in such a way that most edges go downwards from one layer to the next; after this step, the nodes within each layer are arranged in order to minimize crossings.[14]
- Linear embedding places vertices on a line; edges may be drawn as semicircles above or below the line, or as smooth curves linked together from multiple semicircles.
- Circular layout methods place the vertices of the graph on a circle, choosing carefully the ordering of the vertices around the circle to reduce crossings and place adjacent vertices close to each other. Edges may be drawn either as chords of the circle or as arcs inside or outside of the circle. In some cases, multiple circles may be used.[15]
Application-specific graph drawingsGraphs and graph drawings arising in other areas of application include In addition, the placement and routing steps of electronic design automation are similar in many ways to graph drawing, and the graph drawing literature includes several results borrowed from the EDA literature. However, these problems also differ in several important ways: for instance, in EDA, area minimization and signal length are more important than aesthetics, and the routing problem in EDA may have more than two terminals per net while the analogous problem in graph drawing generally only involves pairs of vertices for each edge. SoftwareSoftware, systems, and providers of systems for drawing graphs include: - Cytoscape, open-source software for visualizing molecular interaction networks
- Gephi, an open-source network analysis and visualization software
- Graphviz, an open-source graph drawing system from AT&T Corporation[20]
- Mathematica, a general purpose computation tool that includes 2D and 3D graph visualization and graph analysis tools.[21][22]
- Microsoft Automatic Graph Layout, a .NET library (formerly called GLEE) for laying out graphs[23]
- Tom Sawyer Software[24] Tom Sawyer Perspectives is a graphics-based software for building enterprise-class data visualization and social network analysis applications. It is a Software Development Kit (SDK) with a graphics-based design and preview environment.
- Tulip (software)[25]
- yEd, a widely used graph editor with graph layout functionality[26]
Notes- ^ Di Battista et al. (1994), pp. vii–viii; Herman, Melançon & Marshall (2000), Section 1.1, "Typical Application Areas".
- ^ a b Di Battista et al. (1994), p. 6.
- ^ a b Di Battista et al. (1994), p. viii.
- ^ Misue et al. (1995)
- ^ Holten & van Wijk (2009); Holten et al. (2011).
- ^ Di Battista et al. (1994), Section 2.1.2, Aesthetics, pp. 14–16; Purchase, Cohen & James (1997).
- ^ Di Battista et al. (1994), p 14.
- ^ Di Battista et al. (1994), p. 16.
- ^ a b Pach & Sharir (2009).
- ^ Di Battista et al. (1994), Section 2.7, "The Force-Directed Approach", pp. 29–30, and Chapter 10, "Force-Directed Methods", pp. 303–326.
- ^ Beckman (1994); Koren (2005).
- ^ Di Battista et al. (1994), Chapter 5, "Flow and Orthogonal Drawings", pp. 137–170; (Eiglsperger, Fekete & Klau 2001).
- ^ Herman, Melançon & Marshall (2000), Section 2.2, "Traditional Layout – An Overview".
- ^ Sugiyama, Tagawa & Toda (1981); Bastert & Matuszewski (2001); Di Battista et al. (1994), Chapter 9, "Layered Drawings of Digraphs", pp. 265–302.
- ^ Doğrusöz, Madden & Madden (1997).
- ^ Scott (2000).
- ^ Di Battista et al. (1994), pp. 15-16, and Chapter 6, "Flow and Upward Planarity", pp. 171–214; Freese (2004).
- ^ Zapponi (2003).
- ^ Anderson & Head (2006).
- ^ "Graphviz and Dynagraph – Static and Dynamic Graph Drawing Tools", by John Ellson, Emden R. Gansner, Eleftherios Koutsofios, Stephen C. North, and Gordon Woodhull, in Jünger & Mutzel (2004).
- ^ GraphPlot Mathematica documentation
- ^ Graph drawing tutorial
- ^ Nachmanson, Robertson & Lee (2008).
- ^ Madden et al. (1996).
- ^ "Tulip – A Huge Graph Visualization Framework", by David Auber, in Jünger & Mutzel (2004).
- ^ "yFiles – Visualization and Automatic Layout of Graphs", by Roland Wiese, Markus Eiglsperger, and Michael Kaufmann, in Jünger & Mutzel (2004).
References- Anderson, James Andrew; Head, Thomas J. (2006), Automata Theory with Modern Applications, Cambridge University Press, pp. 38–41, ISBN 978-0-521-84887-9 .
- Bastert, Oliver; Matuszewski, Christian (2001), "Layered drawings of digraphs", in Kaufmann, Michael; Wagner, Dorothea, Drawing Graphs: Methods and Models, Lecture Notes in Computer Science 2025, Springer-Verlag, pp. 87–120, doi:10.1007/3-540-44969-8_5 .
- Beckman, Brian (1994), Theory of Spectral Graph Layout, Tech. Report MSR-TR-94-04, Microsoft Research .
- Di Battista, Giuseppe; Eades, Peter; Tamassia, Roberto; Tollis, Ioannis G. (1994), "Algorithms for Drawing Graphs: an Annotated Bibliography", Computational Geometry: Theory and Applications 4: 235–282 .
- Di Battista, Giuseppe; Eades, Peter; Tamassia, Roberto; Tollis, Ioannis G. (1998), Graph Drawing: Algorithms for the Visualization of Graphs, Prentice Hall, ISBN 978-0-13-301615-4 .
- Doğrusöz, Uğur; Madden, Brendan; Madden, Patrick (1997), "Circular layout in the Graph Layout toolkit", in North, Stephen, Symposium on Graph Drawing, GD '96 Berkeley, California, USA, September 18–20, 1996, Proceedings, Lecture Notes in Computer Science 1190, Springer-Verlag, pp. 92–100, doi:10.1007/3-540-62495-3_40 .
- Eiglsperger, Markus; Fekete, Sándor; Klau, Gunnar (2001), "Orthogonal graph drawing", in Kaufmann, Michael; Wagner, Dorothea, Drawing Graphs, Lecture Notes in Computer Science 2025, Springer Berlin / Heidelberg, pp. 121–171, doi:10.1007/3-540-44969-8_6 .
- Freese, Ralph (2004), "Automated lattice drawing", in Eklund, Peter, Concept Lattices: Second International Conference on Formal Concept Analysis, ICFCA 2004, Sydney, Australia, February 23-26, 2004, Proceedings, Lecture Notes in Computer Science 2961, Springer-Verlag, pp. 589–590, doi:10.1007/978-3-540-24651-0_12 .
- Herman, Ivan; Melançon, Guy; Marshall, M. Scott (2000), "Graph Visualization and Navigation in Information Visualization: A Survey", IEEE Transactions on Visualization and Computer Graphics 6 (1): 24–43, doi:10.1109/2945.841119 .
- Holten, Danny; Isenberg, Petra; van Wijk, Jarke J.; Fekete, Jean-Daniel (2011), "An extended evaluation of the readability of tapered, animated, and textured directed-edge representations in node-link graphs", IEEE Pacific Visualization Symposium (PacificVis 2011), pp. 195–202, doi:10.1109/PACIFICVIS.2011.5742390 .
- Holten, Danny; van Wijk, Jarke J. (2009), "A user study on visualizing directed edges in graphs", Proceedings of the 27th International Conference on Human Factors in Computing Systems (CHI '09), pp. 2299–2308, doi:10.1145/1518701.1519054 .
- Jünger, Michael; Mutzel, Petra (2004), Graph Drawing Software, Springer-Verlag, ISBN 978-3-540-00881-1 .
- Koren, Yehuda (2005), "Drawing graphs by eigenvectors: theory and practice", Computers & Mathematics with Applications 49 (11-12): 1867–1888, doi:10.1016/j.camwa.2004.08.015, MR 2154691 .
- Madden, Brendan; Madden, Patrick; Powers, Steve; Himsolt, Michael (1996), "Portable graph layout and editing", in Brandenburg, Franz J., Graph Drawing: Symposium on Graph Drawing, GD '95, Passau, Germany, September 20–22, 1995, Proceedings, Lecture Notes in Computer Science 1027, Springer-Verlag, pp. 385–395, doi:10.1007/BFb0021822 .
- Misue, K.; Eades, P.; Lai, W.; Sugiyama, K. (1995), "Layout Adjustment and the Mental Map", Journal of Visual Languages and Computing 6 (2): 183–210 .
- Nachmanson, Lev; Robertson, George; Lee, Bongshin (2008), "Drawing Graphs with GLEE", in Hong, Seok-Hee; Nishizeki, Takao; Quan, Wu, Graph Drawing, 15th International Symposium, GD 2007, Sydney, Australia, September 24–26, 2007, Revised Papers, Lecture Notes in Computer Science 4875, Springer-Verlag, pp. 389–394, doi:10.1007/978-3-540-77537-9_38 .
- Pach, János; Sharir, Micha (2009), "5.5 Angular resolution and slopes", Combinatorial Geometry and Its Algorithmic Applications: The Alcalá Lectures, Mathematical Surveys and Monographs 152, American Mathematical Society, pp. 126–127 .
- Purchase, H. C.; Cohen, R. F.; James, M. I. (1997), "An experimental study of the basis for graph drawing algorithms", Journal of Experimental Algorithmics 2, Article 4, doi:10.1145/264216.264222 .
- Scott, John (2000), "Sociograms and Graph Theory", Social network analysis: a handbook (2nd ed.), Sage, pp. 64–69, ISBN 978-0-7619-6339-4 .
- Sugiyama, Kozo; Tagawa, Shôjirô; Toda, Mitsuhiko (1981), "Methods for visual understanding of hierarchical system structures", IEEE Transactions on Systems, Man, and Cybernetics, SMC-11 (2): 109–125, doi:10.1109/TSMC.1981.4308636, MR 0611436 .
- Zapponi, Leonardo (August 2003), "What is a Dessin d'Enfant", Notices of the American Mathematical Society 50: 788–789, ISSN 0002-9920 .
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