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igraph (version 1.3.5)

layout_with_graphopt: The graphopt layout algorithm

Description

A force-directed layout algorithm, that scales relatively well to large graphs.

Usage

layout_with_graphopt(
  graph,
  start = NULL,
  niter = 500,
  charge = 0.001,
  mass = 30,
  spring.length = 0,
  spring.constant = 1,
  max.sa.movement = 5
)
with_graphopt(...)

Value

A numeric matrix with two columns, and a row for each vertex.

Arguments

graph

The input graph.

start

If given, then it should be a matrix with two columns and one line for each vertex. This matrix will be used as starting positions for the algorithm. If not given, then a random starting matrix is used.

niter

Integer scalar, the number of iterations to perform. Should be a couple of hundred in general. If you have a large graph then you might want to only do a few iterations and then check the result. If it is not good enough you can feed it in again in the start argument. The default value is 500.

charge

The charge of the vertices, used to calculate electric repulsion. The default is 0.001.

mass

The mass of the vertices, used for the spring forces. The default is 30.

spring.length

The length of the springs, an integer number. The default value is zero.

spring.constant

The spring constant, the default value is one.

max.sa.movement

Real constant, it gives the maximum amount of movement allowed in a single step along a single axis. The default value is 5.

...

Passed to layout_with_graphopt.

Author

Michael Schmuhl for the original graphopt code, rewritten and wrapped by Gabor Csardi csardi.gabor@gmail.com.

Details

layout_with_graphopt is a port of the graphopt layout algorithm by Michael Schmuhl. graphopt version 0.4.1 was rewritten in C and the support for layers was removed (might be added later) and a code was a bit reorganized to avoid some unnecessary steps is the node charge (see below) is zero.

graphopt uses physical analogies for defining attracting and repelling forces among the vertices and then the physical system is simulated until it reaches an equilibrium. (There is no simulated annealing or anything like that, so a stable fixed point is not guaranteed.)

See also http://www.schmuhl.org/graphopt/ for the original graphopt.

See Also

Other graph layouts: add_layout_(), component_wise(), layout_as_bipartite(), layout_as_star(), layout_as_tree(), layout_in_circle(), layout_nicely(), layout_on_grid(), layout_on_sphere(), layout_randomly(), layout_with_dh(), layout_with_fr(), layout_with_gem(), layout_with_kk(), layout_with_lgl(), layout_with_mds(), layout_with_sugiyama(), layout_(), merge_coords(), norm_coords(), normalize()