In mathematics, weak topology is an alternative term for certain initial topologies, often on topological vector spaces or spaces of linear operators, for instance on a Hilbert space. The term is most commonly used for the initial topology of a topological vector space (such as a normed vector space) with respect to its continuous dual. The remainder of this article will deal with this case, which is one of the concepts of functional analysis.
One may call subsets of a topological vector space weakly closed (respectively, weakly compact, etc.) if they are closed (respectively, compact, etc.) with respect to the weak topology. Likewise, functions are sometimes called weakly continuous (respectively, weakly differentiable, weakly analytic, etc.) if they are continuous (respectively, differentiable, analytic, etc.) with respect to the weak topology.
Starting in the early 1900s, David Hilbert and Marcel Riesz made extensive use of weak convergence. The early pioneers of functional analysis did not elevate norm convergence above weak convergence and oftentimes viewed weak convergence as preferable. In 1929, Banach introduced weak convergence for normed spaces and also introduced the analogous weak-* convergence. The weak topology is also called French: topologie faible in French and German: schwache Topologie in German.
See main article: Topologies on spaces of linear maps.
Let
K
K
Both the weak topology and the weak* topology are special cases of a more general construction for pairings, which we now describe. The benefit of this more general construction is that any definition or result proved for it applies to both the weak topology and the weak* topology, thereby making redundant the need for many definitions, theorem statements, and proofs. This is also the reason why the weak* topology is also frequently referred to as the "weak topology"; because it is just an instance of the weak topology in the setting of this more general construction.
Suppose is a pairing of vector spaces over a topological field
K
K
Notation. For all, let denote the linear functional on defined by . Similarly, for all, let be defined by .
Definition. The weak topology on induced by (and) is the weakest topology on, denoted by or simply, making all maps continuous, as ranges over .
The weak topology on is now automatically defined as described in the article Dual system. However, for clarity, we now repeat it.
Definition. The weak topology on induced by (and) is the weakest topology on, denoted by or simply, making all maps continuous, as ranges over .
If the field
K
for all and . This shows that weak topologies are locally convex.
Assumption. We will henceforth assume that
K
R
C
We now consider the special case where is a vector subspace of the algebraic dual space of (i.e. a vector space of linear functionals on).
There is a pairing, denoted by
(X,Y,\langle ⋅ , ⋅ \rangle)
(X,Y)
\langle ⋅ , ⋅ \rangle
\langlex,x'\rangle=x'(x)
x\inX
x'\inY
\langle ⋅ ,x'\rangle
x'
\langle ⋅ ,x'\rangle=x'( ⋅ )
Assumption. If is a vector subspace of the algebraic dual space of then we will assume that they are associated with the canonical pairing .
In this case, the weak topology on (resp. the weak topology on ), denoted by (resp. by) is the weak topology on (resp. on) with respect to the canonical pairing .
The topology is the initial topology of with respect to .
If is a vector space of linear functionals on, then the continuous dual of with respect to the topology is precisely equal to .
Let be a topological vector space (TVS) over
K
K
X*
K
Recall that
\langle ⋅ , ⋅ \rangle
\langlex,x'\rangle=x'(x)
x\inX
x'\inX*
\langle ⋅ ,x'\rangle=x'( ⋅ )=x'
\langleX,X*\rangle
x'=\langle ⋅ ,x'\rangle:X\toK
x'
X*
Definition: The weak topology on
X*
X*
\langleX,X*\rangle
X*
\langlex, ⋅ \rangle:X*\toK
We give alternative definitions below.
Alternatively, the weak topology on a TVS is the initial topology with respect to the family
X*
X*
A subbase for the weak topology is the collection of sets of the form
\phi-1(U)
\phi\inX*
K
\phi-1(U)
From this point of view, the weak topology is the coarsest polar topology.
(xλ)
\phi(xλ)
\phi(x)
R
C
\phi\inX*
In particular, if
xn
xn
\varphi(xn)\to\varphi(x)
as for all
\varphi\inX*
xn\overset{w
or, sometimes,
xn\rightharpoonupx.
If is equipped with the weak topology, then addition and scalar multiplication remain continuous operations, and is a locally convex topological vector space.
If is a normed space, then the dual space
X*
\|\phi\|=\sup\|x\|\le|\phi(x)|.
This norm gives rise to a topology, called the strong topology, on
X*
See also: Polar topology.
The weak* topology is an important example of a polar topology.
A space can be embedded into its double dual X** by
x\mapsto\begin{cases}Tx:X*\toK\ Tx(\phi)=\phi(x)\end{cases}
Thus
T:X\toX**
X*
T:T(X)\subsetX**
Tx(\phi)=\phi(x)
X*
R
C
\phiλ
X*
\phi
\phiλ(x)\to\phi(x)
for all
x\inX
\phin\inX*
\phi
\phin(x)\to\phi(x)
for all . In this case, one writes
\phin\overset{w*}{\to}\phi
as .
Weak-* convergence is sometimes called the simple convergence or the pointwise convergence. Indeed, it coincides with the pointwise convergence of linear functionals.
If is a separable (i.e. has a countable dense subset) locally convex space and H is a norm-bounded subset of its continuous dual space, then H endowed with the weak* (subspace) topology is a metrizable topological space. However, for infinite-dimensional spaces, the metric cannot be translation-invariant. If is a separable metrizable locally convex space then the weak* topology on the continuous dual space of is separable.
By definition, the weak* topology is weaker than the weak topology on
X*
X*
X*
In more generality, let be locally compact valued field (e.g., the reals, the complex numbers, or any of the p-adic number systems). Let be a normed topological vector space over, compatible with the absolute value in . Then in
X*
If is a normed space, a version of the Heine-Borel theorem holds. In particular, a subset of the continuous dual is weak* compact if and only if it is weak* closed and norm-bounded. This implies, in particular, that when is an infinite-dimensional normed space then the closed unit ball at the origin in the dual space of does not contain any weak* neighborhood of 0 (since any such neighborhood is norm-unbounded). Thus, even though norm-closed balls are compact, X* is not weak* locally compact.
If is a normed space, then is separable if and only if the weak* topology on the closed unit ball of
X*
X*
X*
Consider, for example, the difference between strong and weak convergence of functions in the Hilbert space . Strong convergence of a sequence
\psik\inL2(\Rn)
| \int | |
| \Rn |
|\psik-\psi|2{\rmd}\mu\to0
as . Here the notion of convergence corresponds to the norm on .
In contrast weak convergence only demands that
| \int | |
| \Rn |
\bar{\psi}kfd\mu\to
| \int | |
| \Rn |
\bar{\psi}fd\mu
for all functions (or, more typically, all f in a dense subset of such as a space of test functions, if the sequence is bounded). For given test functions, the relevant notion of convergence only corresponds to the topology used in
C
For example, in the Hilbert space, the sequence of functions
\psik(x)=\sqrt{2/\pi}\sin(kx)
form an orthonormal basis. In particular, the (strong) limit of
\psik
See main article: distribution (mathematics).
One normally obtains spaces of distributions by forming the strong dual of a space of test functions (such as the compactly supported smooth functions on
Rn
Suppose that is a vector space and X# is the algebraic dual space of (i.e. the vector space of all linear functionals on). If is endowed with the weak topology induced by X# then the continuous dual space of is, every bounded subset of is contained in a finite-dimensional vector subspace of, every vector subspace of is closed and has a topological complement.
If and are topological vector spaces, the space of continuous linear operators may carry a variety of different possible topologies. The naming of such topologies depends on the kind of topology one is using on the target space to define operator convergence . There are, in general, a vast array of possible operator topologies on, whose naming is not entirely intuitive.
For example, the strong operator topology on is the topology of pointwise convergence. For instance, if is a normed space, then this topology is defined by the seminorms indexed by :
f\mapsto\|f(x)\|Y.
More generally, if a family of seminorms Q defines the topology on, then the seminorms on defining the strong topology are given by
pq,x:f\mapstoq(f(x)),
indexed by and .
In particular, see the weak operator topology and weak* operator topology.