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complexity results for threedimensional orthogonal graph drawing

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gd 1998. 4 bends per edge in O(n3) time, but less than 7m/3 bends in total ... gd'96, 1997 ... orthogonal drawings of cycles in 3d space, gd'00, 2001 ... – PowerPoint PPT presentation

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Title: complexity results for threedimensional orthogonal graph drawing


1
complexity results for three-dimensional
orthogonal graph drawing
  • maurizio patrignani
  • third university of rome
  • graph drawing
  • dagstuhl 05191-2005

2
three-dimensional orthogonal GD
  • nodes are (distinct) points in 3d space
  • edges are composed by sequences of axis-parallel
    segments
  • only degree six graphs admit such drawings

3
what we know (1)
  • volume is ?(n3/2)
  • rosenberg. three-dimensional vlsi a case study.
    j acm 1983
  • volume is ?(n3/2)
  • eades, stirk, and whitesides, the techniques of
    komolgorov and bardzin for three-dimensional
    orthogonal graph drawings. ipl 96
  • up to 16 bends per edge in time
  • eades, symvonis, and whitesides,
    three-dimensional orthogonal graph drawing
    algorithms. discr. appl. math 2000
  • up to 7 bends per edge in time

4
what we know (2)
  • if only three bends per edges are allowed
  • eades, symvonis, and whitesides,
    three-dimensional orthogonal graph drawing
    algorithms. discr. appl. math 2000
  • linear time complexity in O(n3) volume
  • papakostas and tollis. algorithms for incremental
    orthogonal graph drawing in three-dimensions.
    jgaa 1999
  • linear time complexity in O(n3) volume
  • other algorithms
  • biedl. heuristics for 3d orthogonal graph
    drawing. twente workshop 1995
  • 14 bends per edge in linear time and O(n2) volume
  • closson, gartshore, johansen, and wismath. fully
    dynamic 3-dimensional orthogonal graph drawing.
    jgaa 2000
  • 6 bends per edge in O(n2) volume and linear time,
    but insertions/deletions in O(1) time
  • wood. an algorithm for three-dimensional
    orthogonal graph drawing. gd 1998
  • 4 bends per edge in O(n3) time, but less than
    7m/3 bends in total
  • di battista, patrignani, and vargiu. a splitpush
    approach to 3d orthogonal drawing. jgaa 2000
  • no bound given

5
plenty of drawings
papakostas and tollis 1999
eades, stirk, and whitesides 1996
eades, symvonis, and whitesides 2000
di battista, patrignani, and vargiu 2000
eades, symvonis, and whitesides 2000
biedl 1995
6
what we would like to know
  • two very difficult problems
  • what happens if a maximum of two bends per edge
    is allowed?
  • can we extend to 3d the topology-shape-metrics
    approach?

7
2-bend drawing problem
  • does a (degree six) graph always admit a 3d
    orthogonal drawing with at most 2 bends per edge?
  • a positive answer could provide an algorithm of
    unprecedented effectiveness
  • a negative answer was conjectured
  • eades, symvonis, and whitesides. two algorithms
    for three dimensional orthogonal graph drawing.
    gd96, 1997
  • but the K7 graph that was thought to require 3
    bends turned out to admit a 2-bend drawing
  • wood. on higher dimensional orthogonal graph
    drawing. cats97
  • problem 46 of the open problem project
  • demaine, mitchell, and orourke

8
topology-shape-metrics approach in 2d
V1,2,3,4,5,6 E(1,4),(1,5),(1,6),
(2,4),(2,5),(2,6), (3,4),(3,5),(3,6)
6
1
2
5
3
4
9
topology-shape-metrics approach in 3d
V1,2,3,4,5,6 E(1,4),(1,5),(1,6),
(2,4),(2,5),(2,6), (3,4),(3,5),(3,6)
6
1
2
5
3
4
10
simple and not simple shape graphs
not simple shape graph (always intersects)
simple shape graph (admitting non-intersecting
metrics)
11
characterization of simple shapes
  • known results
  • characterization for cycles
  • di battista, liotta, lubiw, and whitesides.
    orthogonal drawings of cycles in 3d space, gd00,
    2001
  • characterization for paths (with additional
    constraints)
  • di battista, liotta, lubiw, and whitesides.
    embedding problems for paths with direction
    constrained edges. theor. comp. sci., 2002
  • proof that the characterization for cycles is not
    easy to extend to simple graphs (theta graphs)
  • di giacomo, liotta, and patrignani. a note on 3d
    orthogonal drawings with direction constrained
    edges. ipl, 2004
  • characterizing simple shapes is an open problem
  • problem 20 of brandenburg, eppstein, goodrich,
    kobourov, liotta, and mutzel. selected open
    problems in graph drawing. gd 2003

12
two open problems
  • existence of a 2-bend drawing
  • characterization of simple shapes

can complexity considerations give us some
insight?
13
what we show
  • given a 6-degree graph we prove that
  • statement 1 simplicity testing is NP-hard
  • if you fix edge shapes (with a maximum of 2
    bends per edge) finding the metrics corresponding
    to a non intersecting drawing is NP-hard
  • statement 2 2-bend routing is NP-hard
  • if you fix node positions finding a routing
    without intersections with a maximum of two bends
    per edge is NP-hard

14
consequences of statement 1(simplicity testing
is NP-hard)
  • any characterization of simple orthogonal shapes
    involves a hard computation
  • even if we were able to find simple orthogonal
    shapes the compaction step would be NP-hard
  • questions
  • are there classes of graphs such that the
    compaction step is polynomial?
  • are there families of shape graphs such that each
    graph is represented and the metrics can always
    be computed in polynomial time?

15
consequences of statement 2(2-bend routing is
NP-hard)
  • yet another problem where two bends per edge
    implies NP-hardness
  • two bends per edge fixed shape ? NP-hardness
  • two bends per edge fixed positions ?
    NP-hardness
  • two bends per edge diagonal layout ?
    NP-hardness
  • wood. minimising the number of bends and volume
    in 3d orthogonal graph drawings with a diagonal
    vertex layout. algorithmica, 2004
  • question
  • what is the problem of finding a 2-bend drawing
    of a graph?

16
how we prove the statements
  • reductions from the 3sat problem
  • instance a set of clauses c1, c2, , cm each
    containing three literals from a set of boolean
    variables v1, v2, , vn
  • question can truth values be assigned to the
    variables so that each clause contains at lest
    one true literal?

example of 3sat instance (v1 ? v3 ? v4) ? (v1
? v2 ? v5) ? (v2 ? v3 ? v5)
c3
c1
c2
17
the 3sat reduction framework
variable gadgets
joint gadgets
clause gadgets
18
variable gadget
true variable
false variable
19
variable gadget propagating truth values
false variable
20
joint-gadget
T
F
T
F
21
joint-gadget
T
F
T
F
F
T
T
F
22
clause gadget
from the joint gadget
from the variable gadget
from the joint gadget
23
all literals false ? intersecting clause gadget
F
T
F
T
F
F
T
T
F
F
F
F
F
T
F
T
F
T
F
T
T
T
T
T
24
variable gadget
25
variable gadget propagating truth values
to clause gadget c1
variable gadget
to clause gadget c2
to clause gadget c3
26
joint gadget
from the variable gadget
27
joint gadget
from the variable gadget
28
joint gadget
to the clause gadget
from the variable gadget
29
clause gadget
30
conclusions
  • simplicity testing is NP-hard
  • 2-bend routing is NP-hard
  • open problems
  • classes of graphs for which simplicity testing is
    polynomial?
  • classes of shapes for which simplicity testing is
    polynomial?
  • complexity of finding 2-bend drawings?

31
questions?
32
title
33
title
34
title
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