In mathematics, a subadditive set function is a set function whose value, informally, has the property that the value of function on the union of two sets is at most the sum of values of the function on each of the sets. This is thematically related to the subadditivity property of real-valued functions.
Let
\Omega
f\colon2\Omega → R
2\Omega
\Omega
S
T
\Omega
f(S)+f(T)\geqf(S\cupT)
Every non-negative submodular set function is subadditive (the family of non-negative submodular functions is strictly contained in the family of subadditive functions).
The function that counts the number of sets required to cover a given set is subadditive. Let
T1,...c,Tm\subseteq\Omega
| m | |
| \cup | |
| i=1 |
Ti=\Omega
f
f(S)
t
| T | |
| i1 |
,...c,
| T | |
| it |
S\subseteq
| t | |
| \cup | |
| j=1 |
| T | |
| ij |
f
The maximum of additive set functions is subadditive (dually, the minimum of additive functions is superadditive). Formally, for each
i\in\{1,...c,m\}
ai\colon\Omega\toR+
f(S)=maxi\left(\sumx\inai(x)\right)
Fractionally subadditive set functions are a generalization of submodular functions and a special case of subadditive functions. A subadditive function
f
S\subseteq\Omega
X1,...c,Xn\subseteq\Omega
\alpha1,...c,\alphan\in[0,1]
1S\leq
| n | |
| \sum | |
| i=1 |
\alphai
| 1 | |
| Xi |
f(S)\leq
| n | |
| \sum | |
| i=1 |
\alphaif(Xi)