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Deficiency is a concept in
graph theory In mathematics, graph theory is the study of ''graphs'', which are mathematical structures used to model pairwise relations between objects. A graph in this context is made up of '' vertices'' (also called ''nodes'' or ''points'') which are conne ...
that is used to refine various theorems related to
perfect matching In graph theory, a perfect matching in a graph is a matching that covers every vertex of the graph. More formally, given a graph , a perfect matching in is a subset of edge set , such that every vertex in the vertex set is adjacent to exactly ...
in graphs, such as
Hall's marriage theorem In mathematics, Hall's marriage theorem, proved by , is a theorem with two equivalent formulations: * The combinatorial formulation deals with a collection of finite sets. It gives a necessary and sufficient condition for being able to select a di ...
. This was first studied by
Øystein Ore Øystein Ore (7 October 1899 – 13 August 1968) was a Norwegian mathematician known for his work in ring theory, Galois connections, graph theory, and the history of mathematics. Life Ore graduated from the University of Oslo in 1922, with a ...
. A related property is surplus.


Definition of deficiency

Let be a graph, and let ''U'' be an independent set of vertices, that is, ''U'' is a subset of ''V'' in which no two vertices are connected by an edge. Let denotes the set of neighbors of ''U'', which is formed by all vertices from 'V' that are connected by an edge to one or more vertices of ''U''. The deficiency of the set ''U'' is defined by: :\mathrm_G(U) := , U, - , N_G(U), Suppose ''G'' is a
bipartite graph In the mathematical field of graph theory, a bipartite graph (or bigraph) is a graph whose vertices can be divided into two disjoint and independent sets U and V, that is every edge connects a vertex in U to one in V. Vertex sets U and V are ...
, with bipartition ''V'' = ''X'' ∪ ''Y''. The deficiency of ''G'' with respect to one of its parts (say ''X''), is the maximum deficiency of a subset of ''X'': :\mathrm(G;X) := \max_ \mathrm_G(U) Sometimes this quantity is called the critical difference of ''G''. Note that defG of the empty subset is 0, so def(''G;''X) ≥ 0.


Deficiency and matchings

If def(''G;''X) = 0, it means that for all subsets ''U'' of ''X'', , N''G''(''U''), ≥ , ''U'', . Hence, by
Hall's marriage theorem In mathematics, Hall's marriage theorem, proved by , is a theorem with two equivalent formulations: * The combinatorial formulation deals with a collection of finite sets. It gives a necessary and sufficient condition for being able to select a di ...
, ''G'' admits a
perfect matching In graph theory, a perfect matching in a graph is a matching that covers every vertex of the graph. More formally, given a graph , a perfect matching in is a subset of edge set , such that every vertex in the vertex set is adjacent to exactly ...
. In contrast, if def(''G;''X) > 0, it means that for some subsets ''U'' of ''X'', , N''G''(''U''), < , ''U'', . Hence, by the same theorem, ''G'' does not admit a
perfect matching In graph theory, a perfect matching in a graph is a matching that covers every vertex of the graph. More formally, given a graph , a perfect matching in is a subset of edge set , such that every vertex in the vertex set is adjacent to exactly ...
. Moreover, using the notion of deficiency, it is possible to state a quantitative version of Hall's theorem: ''Proof''. Let ''d'' = def(G;X). This means that, for every subset ''U'' of ''X'', , N''G''(''U''), ≥ , ''U'', -''d''. Add ''d'' dummy vertices to ''Y'', and connect every dummy vertex to all vertices of ''X''. After the addition, for every subset ''U'' of ''X'', , N''G''(''U''), ≥ , ''U'', . By Hall's marriage theorem, the new graph admits a matching in which all vertices of ''X'' are matched. Now, restore the original graph by removing the ''d'' dummy vertices; this leaves at most ''d'' vertices of ''X'' unmatched. This theorem can be equivalently stated as: :\nu(G) = , X, - \operatorname(G;X), where ''ν''(''G'') is the size of a maximum matching in ''G'' (called the ''matching number'' of ''G'').


Properties of the deficiency function

In a
bipartite graph In the mathematical field of graph theory, a bipartite graph (or bigraph) is a graph whose vertices can be divided into two disjoint and independent sets U and V, that is every edge connects a vertex in U to one in V. Vertex sets U and V are ...
''G'' = (''X''+''Y'', ''E''), the deficiency function is a supermodular set function: for every two subsets ''X''1, ''X''2 of ''X'':
\operatorname_G(X_1\cup X_2) + \operatorname_G(X_1\cap X_2) \geq \operatorname_G(X_1) + \operatorname_G(X_2)
A tight subset is a subset of ''X'' whose deficiency equals the deficiency of the entire graph (i.e., equals the maximum). The intersection and union of tight sets are tight; this follows from properties of upper-bounded supermodular set functions. In a non-bipartite graph, the deficiency function is, in general, not supermodular.


Strong Hall property

A graph ''G'' has the Hall property if Hall's marriage theorem holds for that graph, namely, if ''G'' has either a perfect matching or a vertex set with a positive deficiency. A graph has the strong Hall property if def(G) = , V, - 2 ν(G). Obviously, the strong Hall property implies the Hall property. Bipartite graphs have both of these properties, however there are classes of non-bipartite graphs that have these properties. In particular, a graph has the strong Hall property if-and-only-if it is stable - its maximum matching size equals its maximum
fractional matching In graph theory, a fractional matching is a generalization of a matching in which, intuitively, each vertex may be broken into fractions that are matched to different neighbor vertices. Definition Given a graph ''G'' = (''V'', ''E''), a fraction ...
size.


Surplus

The surplus of a subset ''U'' of ''V'' is defined by:
surG(''U'') := , N''G''(''U''), − , ''U'', = −defG(''U'')
The surplus of a graph ''G'' w.r.t. a subset ''X'' is defined by the minimum surplus of ''non-empty'' subsets of ''X'':
sur(''G;''X) := min 'U'' a non-empty subset of ''X''surG(''U'')
Note the restriction to non-empty subsets: without it, the surplus of all graphs would always be 0. Note also that:
def(G;X) = max , −sur(''G;'' X)/blockquote>In a bipartite graph ''G'' = (''X''+''Y'', ''E''), the surplus function is a
submodular set function In mathematics, a submodular set function (also known as a submodular function) is a set function whose value, informally, has the property that the difference in the incremental value of the function that a single element makes when added to an ...
: for every two subsets ''X''1, ''X''2 of ''X'':
\operatorname_G(X_1\cup X_2) + \operatorname_G(X_1\cap X_2) \leq \operatorname_G(X_1) + \operatorname_G(X_2)
A surplus-tight subset is a subset of ''X'' whose surplus equals the surplus of the entire graph (i.e., equals the minimum). The intersection and union of tight sets with non-empty intersection are tight; this follows from properties of lower-bounded submodular set functions. For a bipartite graph ''G'' with def(''G'';''X'') = 0, the number sur(''G'';X) is the largest integer ''s'' satisfying the following property for every vertex ''x'' in ''X'': if we add ''s'' new vertices to ''X'' and connect them to the vertices in ''N''G(''x''), the resulting graph has a non-negative surplus. If ''G'' is a bipartite graph with a positive surplus, such that deleting any edge from ''G'' decreases sur(''G;''X), then every vertex in ''X'' has degree sur(''G'';X) + 1. A bipartite graph has a positive surplus (w.r.t. ''X'') if-and-only-if it contains a forest ''F'' such that every vertex in ''X'' has degree 2 in ''F''. Graphs with a positive surplus play an important role in the theory of graph structures; see the
Gallai–Edmonds decomposition In graph theory, the Gallai–Edmonds decomposition is a partition of the vertices of a graph into three subsets which provides information on the structure of maximum matchings in the graph. Tibor Gallai and Jack Edmonds independently discove ...
. In a non-bipartite graph, the surplus function is, in general, not submodular.


References

{{reflist Graph theory