L-infinity
In mathematics,, the vector space of bounded sequences with the supremum norm, and, the vector space of essentially bounded measurable functions with the essential supremum norm, are two closely related Banach spaces. In fact the former is a special case of the latter. As a Banach space they are, respectively, the continuous dual of the Banach spaces of absolutely summable sequences, and of absolutely integrable measurable functions. Pointwise multiplication gives them the structure of a Banach algebra, and in fact they are the standard examples of abelian Von Neumann algebras.
Sequence space
The vector space is a sequence space whose elements are the bounded sequences. The vector space operations, addition and scalar multiplication, are applied coordinate by coordinate. With respect to the normis a standard example of a Banach space. In fact, can be considered as the space with the largest.
This space is the strong dual space of : indeed, every defines a continuous functional on the space of absolutely summable sequences by component-wise multiplication and summing:
via
By evaluating on we see that every continuous linear functional on arises in this way. i.e.
However, not every continuous linear functional on arises from an absolutely summable series in and hence is not a reflexive Banach space.
Function space
is a function space. Its elements are the essentially bounded measurable functions.More precisely, is defined based on an underlying measure space, Start with the set of all measurable functions from to which are essentially bounded, that is, bounded except on a set of measure zero. Two such functions are identified if they are equal almost everywhere. Denote the resulting set by
For a function in this set, its essential supremum serves as an appropriate norm:
This norm is the uniform norm. It is an norm for
The sequence space is a special case of the function space: where the natural numbers are equipped with the counting measure.