The Weak and Strong Topologies
Let K be a topological field, namely a field with a topology such that addition, multiplication, and division are continuous. In most applications K will be either the field of complex numbers or the field of real numbers with the familiar topologies. Let X be a topological vector space over K. Namely, X is a K vector space equipped with a topology so that vector addition and scalar multiplication are continuous.
We may define a possibly different topology on X using the continuous (or topological) dual space X*. The topological dual space consists of all linear functions from X into the base field K which are continuous with respect to the given topology. The weak topology on X is the initial topology with respect to X*. In other words, it is the coarsest topology (the topology with the fewest open sets) such that each element of X* is a continuous function. In order to distinguish the weak topology from the original topology on X, the original topology is often called the strong topology.
A subbase for the weak topology is the collection of sets of the form φ-1(U) where φ ∈ X* and U is an open subset of the base field K. In other words, a subset of X is open in the weak topology if and only if it can be written as a union of (possibly infinitely many) sets, each of which is an intersection of finitely many sets of the form φ-1(U).
More generally, if F is a subset of the algebraic dual space, then the initial topology of X with respect to F, denoted by σ(X,F), is the weak topology with respect to F . If one takes F to be the whole continuous dual space of X, then the weak topology with respect to F coincides with the weak topology defined above.
If the field K has an absolute value, then the weak topology σ(X,F) is induced by the family of seminorms,
for all f∈F and x∈X. In particular, weak topologies are locally convex. From this point of view, the weak topology is the coarsest polar topology; see weak topology (polar topology) for details. Specifically, if F is a vector space of linear functionals on X which separates points of X, then the continuous dual of X with respect to the topology σ(X,F) is precisely equal to F (Rudin 1991, Theorem 3.10).
Read more about this topic: Weak Topology
Famous quotes containing the words weak and/or strong:
“Though much is taken, much abides; and though
We are not now that strength which in old days
Moved earth and heaven, that which we are, we are
One equal temper of heroic hearts,
Made weak by time and fate, but strong in will
To strive, to seek, to find, and not to yield.”
—Alfred Tennyson (18091892)
“When a child stays needy until he is fifty
oh mother-eye, oh mother-eye, crush me in
the parent is as strong as a telephone pole.”
—Anne Sexton (19281974)