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In mathematics, a sequence { a_n }, n ≥ 1, is called superadditive if it satisfies the inequality

$a_{n+m} \geq a_n+a_m\,$

for all m and n. The major reason for the use of superadditive sequences is the following lemma due to Fekete.

Lemma: (Fekete) For every superadditive sequence { a_n }, n ≥ 1, the limit lim a_n/n exists and equal to sup a_n/n. (The limit may be positive infinity, for instance, for the sequence a_n = log n!.)

Similarly, a function f(x) is superadditive if

$f(x+y) \geq f(x)+f(y)\,$

for all x and y in the domain of f.

For example, $f (x) = x 2$ is a superadditive function for nonnegative real numbers because the square of $(x + y)$ is always greater than or equal to the square of $x$ plus the square of $y$ , for nonnegative real numbers $x$ and $y$ .

The analogue of Fekete's lemma holds for subadditive functions as well.

There are extensions of Fekete's lemma that do not require the definition of superadditivity above to hold for all m and n. There are also results that allow one to deduce the rate of convergence to the limit whose existence is stated in Fekete's lemma if some kind of both superadditivity and subadditivity is present. A good exposition of this topic may be found in Steele (1997).^[1]

[edit] References

^ Michael J. Steele (1997). Probability theory and combinatorial optimization. SIAM, Philadelphia. ISBN 0-89871-380-3.

Notes

György Polya and Gábor Szegö. (1976). Problems and theorems in analysis, volume 1. Springer-Verlag, New York. ISBN 0-387-05672-6.

This article incorporates material from Superadditivity on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

[0] Michael J. Steele (1997). Probability theory and combinatorial optimization. SIAM, Philadelphia. ISBN 0-89871-380-3.

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