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Gale–Ryser theorem

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The Gale–Ryser theorem is a result in graph theory and combinatorial matrix theory, two branches of combinatorics. It provides one of two known approaches to solving the bipartite realization problem, i.e. it gives a necessary and sufficient condition for two finite sequences of natural numbers to be the degree sequence of a labeled simple bipartite graph; a sequence obeying these conditions is called "bigraphic". It is an analog of the Erdős–Gallai theorem for simple graphs. The theorem was published independently in 1957 by H. J. Ryser and David Gale.

Statement

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A pair of sequences of nonnegative integers and with is bigraphic if and only if and the following inequality holds for all :

Sometimes this theorem is stated with the additional constraint . This condition is not necessary, because the labels of vertices of one partite set in a bipartite graph can be rearranged arbitrarily.

In 1962 Ford and Fulkerson [1] gave a different but equivalent formulation of the theorem.

Other notations

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The theorem can also be stated in terms of zero-one matrices. The connection can be seen if one realizes that each bipartite graph has a biadjacency matrix where the column sums and row sums correspond to and .

Each sequence can also be considered as an integer partition of the same number . It turns out that partition where is the conjugate partition of . The conjugate partition can be determined by a Ferrers diagram. Moreover, there is a connection to the relation majorization. Consider sequences , and as -dimensional vectors , and . Since , the theorem above states that a pair of nonnegative integer sequences a and b with nonincreasing a is bigraphic if and only if the conjugate partition of majorizes .

A third formulation is in terms of degree sequences of simple directed graphs with at most one loop per vertex. In this case the matrix is interpreted as the adjacency matrix of such a directed graph. When are pairs of nonnegative integers the indegree-outdegree pairs of a labeled directed graph with at most one loop per vertex? The theorem can easily be adapted to this formulation, because there does not exist a special order of b.

Proofs

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The proof is composed of two parts: the necessity of the condition and its sufficiency. We outline the proof of both parts in the language of matrices. To see that the condition in the theorem is necessary, consider the adjacency matrix of a bigraphic realization with row sums and column sums , and shift all ones in the matrix to the left. The row sums remain, while the column sums are now . The operation of shifting all ones to the left increases a partition in majorization order, and so majorizes .

The original proof of sufficiency of the condition was rather complicated. Krause (1996) gave a simple algorithmic proof. The idea is to start with the Ferrers diagram of and shift ones to the right until the column sums are . The algorithm runs in at most steps, in each of which a single one entry is moved to the right.

Stronger version

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Berger proved[2] that it suffices to consider those th inequalities such that with and the equality for .

Generalization

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A pair of finite sequences of nonnegative integers and with nonincreasing is bigraphic if and only if and there exists a sequence such that the pair is bigraphic and majorizes .[3] Moreover, in [4] is also proved that pair and has more bigraphic realizations than pair and . This yields to the result that regular sequences have for fixed numbers of vertices and edges the largest number of bigraphic realizations, if n divides m. They are the contrary sequences of threshold sequences with only one unique bigraphic realization, which is known as threshold graph. Minconvex sequences generalize this concept if n does not divide m.

Characterizations for similar problems

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Similar theorems describe the degree sequences of simple graphs and simple directed graphs. The first problem is characterized by the Erdős–Gallai theorem. The latter case is characterized by the Fulkerson–Chen–Anstee theorem.

Notes

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References

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  • Gale, D. (1957). "A theorem on flows in networks". Pacific J. Math. 7 (2): 1073–1082. doi:10.2140/pjm.1957.7.1073.
  • Ryser, H. J. (1957). "Combinatorial properties of matrices of zeros and ones". Can. J. Math. 9: 371–377. doi:10.4153/cjm-1957-044-3. S2CID 120496629.
  • Ryser, H. J. (1963). Combinatorial Mathematics. John Wiley & Sons.
  • Brualdi, R.; Ryser, H. J. (1991). Combinatorial Matrix Theory. New York: Cambridge University Press. ISBN 9780521322652.
  • Ford (Jr.), L.R.; Fulkerson, D.R. (1962). Flows in Networks. Princeton.{{cite book}}: CS1 maint: location missing publisher (link)
  • Krause, Manfred (1996), "A simple proof of the Gale–Ryser theorem", American Mathematical Monthly, 103 (4): 335–337, doi:10.2307/2975191, JSTOR 2975191
  • Berger, Annabell (2013), "A note on the characterization of digraph sequences", Discrete Mathematics, 314: 38–41, arXiv:1112.1215, doi:10.1016/j.disc.2013.09.010, S2CID 119170629.
  • Berger, Annabell (2018), "Majorization and the number of bipartite graphs for given vertex degrees", Transactions on Combinatorics, 1: 19–30, doi:10.22108/toc.2017.21469.