Polymatroid

In mathematics, a polymatroid is a polytope associated with a submodular function. The notion was introduced by Jack Edmonds in 1970.^[1] It is also described as the multiset analogue of the matroid.

Let ${\displaystyle E}$ be a finite set and ${\displaystyle f:2^E\to {\mathbb{ℝ}}_{+}}$ a non-decreasing submodular function, that is, for each ${\displaystyle A\subseteq B\subseteq E}$ we have ${\displaystyle f(A)\le f(B)}$, and for each ${\displaystyle A,B\subseteq E}$ we have ${\displaystyle f(A)+f(B)\ge f(A\cup B)+f(A\cap B)}$. We define the polymatroid associated to ${\displaystyle f}$ to be the following polytope:

${\displaystyle P_f=\{\text{x}\in {\mathbb{ℝ}}_{+}^E|\sum _{e\in U}\text{x}(e)\le f(U),\mathrm{\forall }U\subseteq E\}}$.

When we allow the entries of ${\displaystyle \text{x}}$ to be negative we denote this polytope by ${\displaystyle E{P}_f}$, and call it the extended polymatroid associated to ${\displaystyle f}$.^[2]

Let ${\displaystyle E}$ be a finite set. If ${\displaystyle \text{u},\text{v}\in {\mathbb{ℝ}}^E}$ then we denote by ${\displaystyle |\text{u}|}$ the sum of the entries of ${\displaystyle \text{u}}$, and write ${\displaystyle \text{u}\le \text{v}}$ whenever ${\displaystyle \text{v}(i)-\text{u}(i)\ge 0}$ for every ${\displaystyle i\in E}$ (notice that this gives an order to ${\displaystyle {\mathbb{ℝ}}_{+}^E}$). A polymatroid on the ground set ${\displaystyle E}$ is a nonempty compact subset ${\displaystyle P}$ in ${\displaystyle {\mathbb{ℝ}}_{+}^E}$, the set of independent vectors, such that:

1. We have that if ${\displaystyle \text{v}\in P}$, then ${\displaystyle \text{u}\in P}$ for every ${\displaystyle \text{u}\le \text{v}}$:
2. If ${\displaystyle \text{u},\text{v}\in P}$ with ${\displaystyle |\text{v}|>|\text{u}|}$, then there is a vector ${\displaystyle \text{w}\in P}$ such that ${\displaystyle \text{u}<\text{w}\le (\max \{\text{u}(1),\text{v}(1)\},\dots ,\max \{\text{u}(|E|),\text{v}(|E|)\})}$.

This definition is equivalent to the one described before,^[3] where ${\displaystyle f}$ is the function defined by ${\displaystyle f(A)=\max \{\sum _{i\in A}\text{v}(i)|\text{v}\in P\}}$ for every ${\displaystyle A\subset E}$.

To every matroid ${\displaystyle M}$ on the ground set ${\displaystyle E}$ we can associate the set ${\displaystyle V_M=\{{\text{w}}_F|F\in {ℐ}\}}$, where ${\displaystyle {ℐ}}$ is the set of independent sets of ${\displaystyle M}$ and we denote by ${\displaystyle {\text{w}}_F}$ the characteristic vector of ${\displaystyle F\subset E}$: for every ${\displaystyle i\in E}$

${\displaystyle {\text{w}}_F(i)=\{\begin{array}{ll}1,& i\in F;\\ 0,& i\in ̸F.\end{array}}$

By taking the convex hull of ${\displaystyle V_M}$ we get a polymatroid. It is associated to the rank function of ${\displaystyle M}$. The conditions of the second definition reflect the axioms for the independent sets of a matroid.

Because generalized permutahedra can be constructed from submodular functions, and every generalized permutahedron has an associated submodular function, we have that there should be a correspondence between generalized permutahedra and polymatroids. In fact every polymatroid is a generalized permutahedron that has been translated to have a vertex in the origin. This result suggests that the combinatorial information of polymatroids is shared with generalized permutahedra.

${\displaystyle P_f}$ is nonempty if and only if ${\displaystyle f\ge 0}$ and that ${\displaystyle E{P}_f}$ is nonempty if and only if ${\displaystyle f(\mathrm{\varnothing })\ge 0}$.

Given any extended polymatroid ${\displaystyle EP}$ there is a unique submodular function ${\displaystyle f}$ such that ${\displaystyle f(\mathrm{\varnothing })=0}$ and ${\displaystyle E{P}_f=EP}$.

For a supermodular f one analogously may define the contrapolymatroid

${\displaystyle \{w\in {\mathbb{ℝ}}_{+}^E|\mathrm{\forall }S\subseteq E,\sum _{e\in S}w(e)\ge f(S)\}}$

This analogously generalizes the dominant of the spanning set polytope of matroids.

When we only focus on the lattice points of our polymatroids we get what is called, discrete polymatroids. Formally speaking, the definition of a discrete polymatroid goes exactly as the one for polymatroids except for where the vectors will live in, instead of ${\displaystyle {\mathbb{ℝ}}_{+}^E}$ they will live in ${\displaystyle {\mathbb{\mathbb{Z}}}_{+}^E}$. This combinatorial object is of great interest because of their relationship to monomial ideals.

Footnotes

Additional reading

• Lee, Jon (2004), A First Course in Combinatorial Optimization, Cambridge University Press, ISBN 0-521-01012-8 
• Fujishige, Satoru (2005), Submodular Functions and Optimization, Elsevier, ISBN 0-444-52086-4 
• Narayanan, H. (1997), Submodular Functions and Electrical Networks, ISBN 0-444-82523-1 

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