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Dominance order

In discrete mathematics, dominance order (synonyms: dominance ordering, majorization order, natural ordering) is a partial order on the set of partitions of a positive integer n that plays an important role in algebraic combinatorics and representation theory, especially in the context of symmetric functions and representation theory of the symmetric group.

Definition

If p = (p<sub>1</sub>,p<sub>2</sub>,...) and q = (q<sub>1</sub>,q<sub>2</sub>,...) are partitions of n, with the parts arranged in the weakly decreasing order, then p precedes q in the dominance order if for any k ≥ 1, the sum of the k largest parts of p is less than or equal to the sum of the k largest parts of q:

In this definition, partitions are extended by appending zero parts at the end as necessary.

Properties of the dominance ordering

  • Among the partitions of n, (1,...,1) is the smallest and (n) is the largest.
  • The dominance ordering implies lexicographical ordering, i.e. if p dominates q and p&nbsp;≠&nbsp;q, then for the smallest i such that p<sub>i</sub> ≠ q<sub>i</sub> one has p<sub>i</sub> &gt; q<sub>i</sub>.
  • The poset of partitions of n is linearly ordered (and is equivalent to lexicographical ordering) if and only if n ≤ 5. It is graded if and only if n ≤ 6. See image at right for an example.
  • A partition p covers a partition q if and only if p<sub>i</sub> = q<sub>i</sub> + 1, p<sub>k</sub> = q<sub>k</sub> &minus; 1, p<sub>j</sub> = q<sub>j</sub> for all j &ne; i,k and either (1) k = i + 1 or (2) q<sub>i</sub> = q<sub>k</sub> (Brylawski, Prop. 2.3). Starting from the Young diagram of q, the Young diagram of p is obtained from it by first removing the last box of row k and then appending it either to the end of the immediately preceding row k &minus; 1, or to the end of row i < k if the rows i through k of the Young diagram of q all have the same length.
  • Every partition p has a conjugate (or dual) partition p&prime;, whose Young diagram is the transpose of the Young diagram of p. This operation reverses the dominance ordering:
: if and only if

Lattice structure

Partitions of n form a lattice under the dominance ordering, denoted L<sub>n</sub>, and the operation of conjugation is an antiautomorphism of this lattice. To explicitly describe the lattice operations, for each partition p consider the associated (n&nbsp;+&nbsp;1)-tuple:

The partition p can be recovered from its associated (n+1)-tuple by applying the step 1 difference, Moreover, the (n+1)-tuples associated to partitions of n are characterized among all integer sequences of length n&nbsp;+&nbsp;1 by the following three properties:

  • Nondecreasing,
  • Concave,
  • The initial term is 0 and the final term is n,

By the definition of the dominance ordering, partition p precedes partition q if and only if the associated (n&nbsp;+&nbsp;1)-tuple of p is term-by-term less than or equal to the associated (n&nbsp;+&nbsp;1)-tuple of q. If p, q, r are partitions then if and only if The componentwise minimum of two nondecreasing concave integer sequences is also nondecreasing and concave. Therefore, for any two partitions of n, p and q, their meet is the partition of n whose associated (n&nbsp;+&nbsp;1)-tuple has components The natural idea to use a similar formula for the join fails, because the componentwise maximum of two concave sequences need not be concave. For example, for n&nbsp;=&nbsp;6, the partitions [3,1,1,1] and [2,2,2] have associated sequences (0,3,4,5,6,6,6) and (0,2,4,6,6,6,6), whose componentwise maximum (0,3,4,6,6,6,6) does not correspond to any partition. To show that any two partitions of n have a join, one uses the conjugation antiautomorphism: the join of p and q is the conjugate partition of the meet of p&prime; and q&prime;:

For the two partitions p and q in the preceding example, their conjugate partitions are [4,1,1] and [3,3] with meet [3,2,1], which is self-conjugate; therefore, the join of p and q is [3,2,1].

Thomas Brylawski has determined many invariants of the lattice L<sub>n</sub>, such as the minimal height and the maximal covering number, and classified the intervals of small length. While L<sub>n</sub> is not distributive for n&nbsp;&ge;&nbsp;7, it shares some properties with distributive lattices: for example, its Möbius function takes on only values 0, 1, &minus;1.

Generalizations

Partitions of n can be graphically represented by Young diagrams on n boxes. Standard Young tableaux are certain ways to fill Young diagrams with numbers, and a partial order on them (sometimes called the dominance order on Young tableaux) can be defined in terms of the dominance order on the Young diagrams. For a Young tableau T to dominate another Young tableau S, the shape of T must dominate that of S as a partition, and moreover the same must hold whenever T and S are first truncated to their sub-tableaux containing entries up to a given value k, for each choice of k.

Similarly, there is a dominance order on the set of standard Young bitableaux, which plays a role in the theory of standard monomials.

See also

References