YΔ- and ΔY-transformation explained

In graph theory, ΔY- and YΔ-transformations (also written delta-wye and wye-delta) are a pair of operations on graphs. A ΔY-transformation replaces a triangle by a vertex of degree three; and conversely, a YΔ-transformation replaces a vertex of degree three by a triangle.The names for the operations derive from the shapes of the involved subgraphs, which look respectively like the letter Y and the Greek capital letter Δ.

A YΔ-transformation may create parallel edges, even if applied to a simple graph. For this reason ΔY- and YΔ-transformations are most naturally considered as operations on multigraphs.On multigraphs both operations preserve the edge count and are exact inverses of each other.In the context of simple graphs it is common to combine a YΔ-transformation with a subsequent normalization step that reduces parallel edges to a single edge.This may no longer preserve the number of edges, nor be exactly reversible via a ΔY-transformation.

Formal definition

Let

G

be a graph (potentially a multigraph).

Suppose

G

contains a triangle

\Delta

with vertices

x1,x2,x3

and edges

e12,e23,e31

.A ΔY-transformation of

G

at

\Delta

deletes the edges

e12,e23,e31

and adds a new vertex

y

adjacent to each of

x1,x2,x3

.

Conversely, if

y

is a vertex of degree three with neighbors

x1,x2,x3

, then a YΔ-transformation of

G

at

y

deletes

y

and adds three new edges

e12,e23,e31

, where

eij

connects

xi

and

xj

.If the resulting graph should be a simple graph, then any resulting parallel edges are to be replaced by a single edge.

Relevance

ΔY- and YΔ-transformations are a tool both in pure graph theory as well as applications.

Both operations preserve a number of natural topological properties of graphs.Applying a YΔ-transformation to a 3-vertex of a planar graph, or a ΔY-transformation to a triangle face of a planar graph, results again in a planar graph.[1] Applying ΔY- and YΔ-transformations to a linkless graph results again in a linkless graph.This fact is used to compactly describe the forbidden minors of the associated graph classes as ΔY-families generated from a small number of graphs (see the section on ΔY-families below).

A particularly relevant application exists in electrical engineering in the study of three-phase power systems (see Y-Δ transform (electrical engineering)).[2] In this context they are also known as star-triangle transformations and are a special case of star-mesh transformations.

ΔY-families

The ΔY-family generated by a graph

G

is the smallest family of graphs that contains

G

and is closed under YΔ- and ΔY-transformations.Equivalently, it is constructed from

G

by recursively applying these transformations until no new graph is generated.If

G

is a finite graph it generates a finite ΔY-family, all members of which have the same edge count.

The ΔY-family generated by several graphs is the smallest family that contains all these graphs and is closed under YΔ- and ΔY-transformation.

Some notable families are generated in this way:

K6

. It consists of the six forbidden minors for the class of linkless graphs.[3]

K7

and

K3,3,1,1

. It consists of 78 graphs, each of which is a forbidden minors for the class of 4-flat graphs.[4]

YΔY-reducible graphs

A graph is YΔY-reducible if it can be reduced to a single vertex by a sequence of ΔY- or YΔ-transformations and the following normalization steps:

The YΔY-reducible graphs form a minor closed family and therefore have a forbidden minor characterization (by the Robertson-Seymour theorem). The graphs of the Petersen family constitute some (but not all) of the excluded minors.In fact, already more than 68 billion excluded minor are known.[5]

The class of YΔY-reducible graphs lies between the classes of planar graphs and linkless graphs: each planar graph is YΔY-reducible, while each YΔY-reducible graph is linkless.Both inclusions are strict:

K5

is not planar but YΔY-reducible, while the graph in the figure is not YΔY-reducible but linkless.

Notes and References

  1. Truemper, K. (1989). On the delta‐wye reduction for planar graphs. Journal of graph theory, 13(2), 141-148.
  2. Johnson, D. E., Hilburn, J. L., Johnson, J. R., & Scott, P. D. (1986). Basic electric circuit analysis. Englewood Cliffs: Prentice-Hall.
  3. .
  4. van der Holst, H. (2006). Graphs and obstructions in four dimensions. Journal of Combinatorial Theory, Series B, 96(3), 388-404.
  5. Yu, Y. (2006). More forbidden minors for Wye-Delta-Wye reducibility. the electronic journal of combinatorics, R7-R7.