Upward planar drawing

An upward planar drawing
This planar DAG has no upward drawing, because its source and sink cannot both be in the same face

In graph drawing, an upward planar drawing of a directed acyclic graph is an embedding of the graph into the Euclidean plane, in which the edges are represented as non-crossing monotonic upwards curves. That is, the curve representing each edge should have the property that every horizontal line intersects it in at most one point, and no two edges may intersect except at a shared endpoint.[1] In this sense, it is the ideal case for layered graph drawing, a style of graph drawing in which edges are monotonic curves that may cross, but in which crossings are to be minimized.

Characterizations

A directed acyclic graph must be planar in order to have an upward planar drawing, but not every planar acyclic graph has such a drawing. Among the planar directed acyclic graphs with a single source (vertex with no incoming edges) and sink (vertex with no outgoing edges), the graphs with upward planar drawings are the st-planar graphs, planar graphs in which the source and sink both belong to the same face of at least one of the planar embeddings of the graph. More generally, a graph G has an upward planar drawing if and only if it is directed and acyclic, and is a subgraph of an st-planar graph on the same vertex set.[2]

In an upward embedding, the sets of incoming and outgoing edges incident to each vertex are contiguous in the cyclic ordering of the edges at the vertex. A planar embedding of a given directed acyclic graph is said to be bimodal when it has this property. Additionally, the angle between two consecutive edges with the same orientation at a given vertex may be labeled as small if it is less than π, or large if it is greater than π. Each source or sink must have exactly one large angle, and each vertex that is neither a source nor a sink must have none. Additionally, each internal face of the drawing must have two more small angles than large ones, and the external face must have two more large angles than small ones. A consistent assignment is a labeling of the angles that satisfies these properties; every upward embedding has a consistent assignment. Conversely, every directed acyclic graph that has a bimodal planar embedding with a consistent assignment has an upward planar drawing, that can be constructed from it in linear time.[3]

Another characterization is possible for graphs with a single source. In this case an upward planar embedding must have the source on the outer face, and every undirected cycle of the graph must have at least one vertex at which both cycle edges are incoming (for instance, the vertex with the highest placement in the drawing). Conversely, if an embedding has both of these properties, then it is equivalent to an upward embedding.[4]

Computational complexity

Several special cases of upward planarity testing are known to be possible in polynomial time:

However, it is NP-complete to determine whether a planar directed acyclic graph with multiple sources and sinks has an upward planar drawing.[16]

Straight-line drawing and area requirements

Fáry's theorem states that every planar graph has a drawing in which its edges are represented by straight line segments, and the same is true of upward planar drawing: every upward planar graph has a straight upward planar drawing.[17] A straight-line upward drawing of a transitively reduced st-planar graph may be obtained by the technique of dominance drawing, with all vertices having integer coordinates within an n × n grid.[18] However, certain other upward planar graphs may require exponential area in all of their straight-line upward planar drawings.[17] If a choice of embedding is fixed, even oriented series parallel graphs and oriented trees may require exponential area.[19]

Hasse diagrams

Upward planar drawings are particularly important for Hasse diagrams of partially ordered sets, as these diagrams are typically required to be drawn upwardly. In graph-theoretic terms, these correspond to the transitively reduced directed acyclic graphs; such a graph can be formed from the covering relation of a partial order, and the partial order itself forms the reachability relation in the graph. If a partially ordered set has one minimal element, has one maximal element, and has an upward planar drawing, then it must necessarily form a lattice, a set in which every pair of elements has a unique greatest lower bound and a unique least upper bound.[20] The Hasse diagram of a lattice is planar if and only if its order dimension is at most two.[21] However, some partial orders of dimension two and with one minimal and maximal element do not have an upward planar drawing (take the order defined by the transitive closure of ).

References

Footnotes
  1. Garg & Tamassia (1995); Di Battista et al. (1998).
  2. Garg & Tamassia (1995), pp. 111–112; Di Battista et al. (1998), 6.1 "Inclusion in a Planar st-Graph", pp. 172–179; Di Battista & Tamassia (1988); Kelly (1987).
  3. Garg & Tamassia (1995), pp. 112–115; Di Battista et al. (1998), 6.2 "Angles in Upward Drawings", pp. 180–188; Bertolazzi & Di Battista (1991); Bertolazzi et al. (1994).
  4. Garg & Tamassia (1995), p. 115; Di Battista et al. (1998), 6.7.2 "Forbidden Cycles for Single-Source Digraphs", pp. 209–210; Thomassen (1989).
  5. Garg & Tamassia (1995), p. 119; Di Battista et al. (1998), p. 179.
  6. Garg & Tamassia (1995), pp. 119–121; Di Battista et al. (1998), 6.3 "Upward Planarity Testing of Embedded Digraphs", pp. 188–192; Bertolazzi & Di Battista (1991); Bertolazzi et al. (1994); Abbasi, Healy & Rextin (2010).
  7. Di Battista et al. (1998), pp. 191–192; Bertolazzi & Di Battista (1991); Bertolazzi et al. (1994).
  8. Garg & Tamassia (1995), pp. 125–126; Di Battista et al. (1998), 6.7.1 "Outerplanar Digraph", p. 209; Papakostas (1995).
  9. 1 2 3 Di Battista et al. (1998), 6.7.4 "Some Classes of Upward Planar Digraphs", p. 212.
  10. Didimo, Giordano & Liotta (2009).
  11. Di Battista, Liu & Rival (1990).
  12. Garg & Tamassia (1995), pp. 122–125; Di Battista et al. (1998), 6.5 "Optimal Upward Planarity Testing of Single-Source Digraphs", pp. 195–200; Hutton & Lubiw (1996); Bertolazzi et al. (1998).
  13. Chan (2004); Healy & Lynch (2006).
  14. Healy & Lynch (2006).
  15. Jünger & Leipert (1999).
  16. Garg & Tamassia (1995), pp. 126–132; Di Battista et al. (1998), 6.6 "Upward Planarity Testing is NP-complete", pp. 201–209; Garg & Tamassia (2001).
  17. 1 2 Di Battista & Frati (2012); Di Battista, Tamassia & Tollis (1992).
  18. Di Battista et al. (1998), 4.7 "Dominance Drawings", pp. 112–127; Di Battista, Tamassia & Tollis (1992).
  19. Di Battista & Frati (2012); Bertolazzi et al. (1994); Frati (2008).
  20. Di Battista et al. (1998), 6.7.3 "Forbidden Structures for Lattices", pp. 210–212; Platt (1976).
  21. Garg & Tamassia (1995), pp. 118; Baker, Fishburn & Roberts (1972).
Surveys and textbooks
  • Di Battista, Giuseppe; Eades, Peter; Tamassia, Roberto; Tollis, Ioannis G. (1998), "Flow and Upward Planarity", Graph Drawing: Algorithms for the Visualization of Graphs, Prentice Hall, pp. 171–213, ISBN 978-0-13-301615-4 .
  • Di Battista, Giuseppe; Frati, Fabrizio (2012), "Drawing trees, outerplanar graphs, series-parallel graphs, and planar graphs in small area", Thirty Essays on Geometric Graph Theory, Algorithms and combinatorics, 29, Springer, pp. 121–165, doi:10.1007/978-1-4614-0110-0_9, ISBN 9781461401100 . Section 5, "Upward Drawings", pp. 149–151.
  • Garg, Ashim; Tamassia, Roberto (1995), "Upward planarity testing", Order, 12 (2): 109–133, doi:10.1007/BF01108622, MR 1354797 .
Research articles
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