Semi-infinite

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In mathematics, semi-infinite objects are objects which are infinite or unbounded in some but not all possible ways.

In ordered structures and Euclidean spaces

Generally, a semi-infinite set is bounded in one direction, and unbounded in another. For instance, the natural numbers are semi-infinite considered as a subset of the integers; similarly, the intervals [math]\displaystyle{ (c,\infty) }[/math] and [math]\displaystyle{ (-\infty,c) }[/math] and their closed counterparts are semi-infinite subsets of [math]\displaystyle{ \R }[/math] if [math]\displaystyle{ c }[/math] is finite.[1] Half-spaces and half-lines are sometimes described as semi-infinite regions.

Semi-infinite regions occur frequently in the study of differential equations.[2][3] For instance, one might study solutions of the heat equation in an idealised semi-infinite metal bar.

A semi-infinite integral is an improper integral over a semi-infinite interval. More generally, objects indexed or parametrised by semi-infinite sets may be described as semi-infinite.[4]

Most forms of semi-infiniteness are boundedness properties, not cardinality or measure properties: semi-infinite sets are typically infinite in cardinality and measure.

In optimization

Main page: Semi-infinite programming

Many optimization problems involve some set of variables and some set of constraints. A problem is called semi-infinite if one (but not both) of these sets is finite. The study of such problems is known as semi-infinite programming.[5]

References

  1. Trench, William (in en). Introduction to Real Analysis. p. 21. ISBN 0-13-045786-8. 
  2. Bateman, Transverse seismic waves on the surface of a semi-infinite solid composed of heterogeneous material, Bull. Amer. Math. Soc. Volume 34, Number 3 (1928), 343–348.
  3. Wolfram Demonstrations Project, Heat Diffusion in a Semi-Infinite Region (accessed November 2010).
  4. Cator, Pimentel, A shape theorem and semi-infinite geodesics for the Hammersley model with random weights, 2010.
  5. Reemsten, Rückmann, Semi-infinite Programming, Kluwer Academic, 1998. ISBN:0-7923-5054-5