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In the mathematical field of functional analysis there are several standard topologies which are given to the algebra $B(X)$ of bounded linear operators on a Banach space $X$ .

Introduction

Let $(T_{n})_{n\in \mathbb {N} }$ be a sequence of linear operators on the Banach space $X$ . Consider the statement that $(T_{n})_{n\in \mathbb {N} }$ converges to some operator $T$ on $X$ . This could have several different meanings:

If $\|T_{n}-T\|\to 0$ , that is, the operator norm of $T_{n}-T$ (the supremum of $\|T_{n}x-Tx\|_{X}$ , where $x$ ranges over the unit ball in $X$ ) converges to 0, we say that $T_{n}\to T$ in the uniform operator topology.
If $T_{n}x\to Tx$ for all $x\in X$ , then we say $T_{n}\to T$ in the strong operator topology.
Finally, suppose that for all $x \in X$ we have $T_{n}x\to Tx$ in the weak topology of $X$ . This means that $F(T_{n}x)\to F(Tx)$ for all continuous linear functionals $F$ on $X$ . In this case we say that $T_{n}\to T$ in the weak operator topology.

List of topologies on B(H)

Diagram of relations among topologies on the space $B(X)$ of bounded operators

There are many topologies that can be defined on $B(X)$ besides the ones used above; most are at first only defined when $X = H$ is a Hilbert space, even though in many cases there are appropriate generalisations. The topologies listed below are all locally convex, which implies that they are defined by a family of seminorms.

In analysis, a topology is called strong if it has many open sets and weak if it has few open sets, so that the corresponding modes of convergence are, respectively, strong and weak. (In topology proper, these terms can suggest the opposite meaning, so strong and weak are replaced with, respectively, fine and coarse.) The diagram on the right is a summary of the relations, with the arrows pointing from strong to weak.

If $H$ is a Hilbert space, the linear space of Hilbert space operators $B(X)$ has a (unique) predual $B(H)_{*}$ , consisting of the trace class operators, whose dual is $B(X)$ . The seminorm $p w (x)$ for w positive in the predual is defined to be $B(w, x * x) 1/2$ .

If $B$ is a vector space of linear maps on the vector space $A$ , then $σ(A, B)$ is defined to be the weakest topology on $A$ such that all elements of $B$ are continuous.

The norm topology or uniform topology or uniform operator topology is defined by the usual norm ||x|| on $B(H)$ . It is stronger than all the other topologies below.
The weak (Banach space) topology is $σ(B(H), B(H) *)$ , in other words the weakest topology such that all elements of the dual $B(H) *$ are continuous. It is the weak topology on the Banach space $B(H)$ . It is stronger than the ultraweak and weak operator topologies. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
The Mackey topology or Arens-Mackey topology is the strongest locally convex topology on $B(H)$ such that the dual is $B(H) *$ , and is also the uniform convergence topology on $Bσ(B(H) *$ , $B(H)$ -compact convex subsets of $B(H) *$ . It is stronger than all topologies below.
The σ-strong-^* topology or ultrastrong-^* topology is the weakest topology stronger than the ultrastrong topology such that the adjoint map is continuous. It is defined by the family of seminorms $p w (x)$ and $p w (x *)$ for positive elements $w$ of $B(H) *$ . It is stronger than all topologies below.
The σ-strong topology or ultrastrong topology or strongest topology or strongest operator topology is defined by the family of seminorms $p w (x)$ for positive elements $w$ of $B(H) *$ . It is stronger than all the topologies below other than the strong^* topology. Warning: in spite of the name "strongest topology", it is weaker than the norm topology.)
The σ-weak topology or ultraweak topology or weak-^* operator topology or weak-* topology or weak topology or $σ(B(H), B(H) *$ ) topology is defined by the family of seminorms |(w, x)| for elements w of $B(H) *$ . It is stronger than the weak operator topology. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
The strong-^* operator topology or strong-^* topology is defined by the seminorms ||x(h)|| and ||x^*(h)|| for $h \in H$ . It is stronger than the strong and weak operator topologies.
The strong operator topology (SOT) or strong topology is defined by the seminorms ||x(h)|| for $h \in H$ . It is stronger than the weak operator topology.
The weak operator topology (WOT) or weak topology is defined by the seminorms |(x(h₁), h₂)| for $h 1, h 2 \in H$ . (Warning: the weak Banach space topology, the weak operator topology, and the ultraweak topology are all sometimes called the weak topology, but they are different.)

Relations between the topologies

The continuous linear functionals on $B(H)$ for the weak, strong, and strong^* (operator) topologies are the same, and are the finite linear combinations of the linear functionals (xh₁, h₂) for $h 1, h 2 \in H$ . The continuous linear functionals on $B(H)$ for the ultraweak, ultrastrong, ultrastrong^* and Arens-Mackey topologies are the same, and are the elements of the predual $B(H) *$ .

By definition, the continuous linear functionals in the norm topology are the same as those in the weak Banach space topology. This dual is a rather large space with many pathological elements.

On norm bounded sets of $B(H)$ , the weak (operator) and ultraweak topologies coincide. This can be seen via, for instance, the Banach–Alaoglu theorem. For essentially the same reason, the ultrastrong topology is the same as the strong topology on any (norm) bounded subset of $B(H)$ . Same is true for the Arens-Mackey topology, the ultrastrong^*, and the strong^* topology.

In locally convex spaces, closure of convex sets can be characterized by the continuous linear functionals. Therefore, for a convex subset $K$ of $B(H)$ , the conditions that $K$ be closed in the ultrastrong^*, ultrastrong, and ultraweak topologies are all equivalent and are also equivalent to the conditions that for all $r > 0$ , $K$ has closed intersection with the closed ball of radius $r$ in the strong^*, strong, or weak (operator) topologies.

The norm topology is metrizable and the others are not; in fact they fail to be first-countable. However, when $H$ is separable, all the topologies above are metrizable when restricted to the unit ball (or to any norm-bounded subset).

Topology to use

The most commonly used topologies are the norm, strong, and weak operator topologies. The weak operator topology is useful for compactness arguments, because the unit ball is compact by the Banach–Alaoglu theorem. The norm topology is fundamental because it makes $B(H)$ into a Banach space, but it is too strong for many purposes; for example, $B(H)$ is not separable in this topology. The strong operator topology could be the most commonly used.

The ultraweak and ultrastrong topologies are better-behaved than the weak and strong operator topologies, but their definitions are more complicated, so they are usually not used unless their better properties are really needed. For example, the dual space of $B(H)$ in the weak or strong operator topology is too small to have much analytic content.

The adjoint map is not continuous in the strong operator and ultrastrong topologies, while the strong* and ultrastrong* topologies are modifications so that the adjoint becomes continuous. They are not used very often.

The Arens–Mackey topology and the weak Banach space topology are relatively rarely used.

To summarize, the three essential topologies on $B(H)$ are the norm, ultrastrong, and ultraweak topologies. The weak and strong operator topologies are widely used as convenient approximations to the ultraweak and ultrastrong topologies. The other topologies are relatively obscure.

References

Functional analysis, by Reed and Simon, ISBN 0-12-585050-6
Theory of Operator Algebras I, by M. Takesaki (especially chapter II.2) ISBN 3-540-42248-X

@@ Line 1: / Line 1: @@
+{{Short description|Topologies on the set of operators on a Hilbert space}}
-In [[mathematics]], the requirements of [[functional analysis]] mean there are several standard [[topology|topologies]] which are given to the algebra ''B''(''H'') of [[bounded linear operator]]s on a [[Hilbert space]] ''H''.
+In the [[mathematics|mathematical]] field of [[functional analysis]] there are several standard [[topology|topologies]] which are given to the algebra {{math|B(''X'')}} of [[bounded linear operator]]s on a [[Banach space]] {{mvar|X}}.
-==Introduction==
+== Introduction ==
-Let {''T''<sub>''n''</sub>} be a sequence of linear operators on the Hilbert space ''H''.  Consider the statement that ''T''<sub>''n''</sub> converges to some operator ''T'' in ''H''.This could have several different meanings:
+Let <math>(T_n)_{n \in \mathbb N}</math> be a sequence of linear operators on the Banach space {{mvar|X}}. Consider the statement that <math>(T_n)_{n \in \N}</math> converges to some operator {{mvar|T}} on {{mvar|X}}.
+This could have several different meanings:
-* If <math>\|T_n - T\| \to 0</math>, that is, the supremum of ''T''<sub>''n''</sub>''x'' - ''T'' ''x'' converges to 0, where ''x'' ranges over the [[unit ball]] in ''H'', we say that <math>T_n \to T</math> in the '''uniform operator topology'''.
+* If <math>\|T_n - T\| \to 0</math>, that is, the [[operator norm]] of <math>T_n - T</math> (the supremum of <math>\| T_n x - T x \|_X</math>, where {{mvar|x}} ranges over the [[unit ball]] in {{mvar|X}} ) converges to 0, we say that <math>T_n \to T</math> in the '''[[uniform operator topology]]'''.
-* If <math>T_n x \to Tx</math> for all ''x'' in ''H'', then we say <math>T_n \to T</math> in the '''strong operator topology'''.
+* If <math>T_n x \to Tx</math> for all <math>x \in X</math>, then we say <math>T_n \to T</math> in the '''[[strong operator topology]]'''.
-* Finally, suppose <math>T_n x \to Tx</math> in the [[weak topology]] of ''H''.  This means that <math>F(T_n x) \to F(T x)</math> for all [[linear functionals]] ''F'' on ''H''.  In this case we say that <math>T_n \to T</math> in the '''weak operator topology'''.
+* Finally, suppose that for all {{math|''x'' ∈ ''X''}} we have <math>T_n x \to Tx</math> in the [[weak topology]] of {{mvar|X}}. This means that <math>F(T_n x) \to F(T x)</math> for all continuous linear functionals {{mvar|F}} on {{mvar|X}}. In this case we say that <math>T_n \to T</math> in the '''[[weak operator topology]]'''.
+== List of topologies on B(''H'') ==
-All of these notions make sense and are useful for a [[Banach space]] in place of the Hilbert space ''H''.
-==List of topologies on ''B''(''H'')==
+[[Image:Optop.svg|right|thumb|Diagram of relations among topologies on the space {{math|B(''X'')}} of bounded operators]]
-There are many topologies that can be defined on ''B''(''H'') besides the ones used above.  These topologies are all locally convex, which implies that they are defined by a family of [[seminorm]]s.
+There are many topologies that can be defined on {{math|B(''X'')}} besides the ones used above; most are at first only defined when {{math|1=''X'' = ''H''}} is a Hilbert space, even though in many cases there are appropriate generalisations.
+The topologies listed below are all locally convex, which implies that they are defined by a family of [[seminorm]]s.
+In analysis, a topology is called strong if it has many open sets and weak if it has few open sets, so that the corresponding modes of convergence are, respectively, strong and weak.
-The [[Banach space]] ''B''(''H'') has a (unique) [[predual]] ''B''(''H'')<sub>*</sub>,
+(In topology proper, these terms can suggest the opposite meaning, so strong and weak are replaced with, respectively, fine and coarse.)
-consisting of the trace class operators, whose dual is ''B''(''H''). The  seminorm ''p''<sub>''w''</sub>(''x'')  for ''w'' positive in the predual is defined to be
+The diagram on the right is a summary of the relations, with the arrows pointing from strong to weak.
-(''w'', ''x<sup>*</sup>x'')<sup>1/2</sup>.
-If ''B'' is a vector space of linear maps on the vector space ''A'', then σ(''A'', ''B'') is defined to be the weakest topology on ''A'' such that all elements of ''B'' are continuous.
+If {{mvar|H}} is a Hilbert space, the linear space of [[Hilbert space]] operators {{math|B(''X'')}} has a (unique) [[predual]] <math>B(H)_*</math>,
+consisting of the trace class operators, whose dual is {{math|B(''X'')}}.
+The seminorm {{math|''p''<sub>''w''</sub>(''x'')}} for ''w'' positive in the predual is defined to be
+{{math|B(''w'', ''x<sup>*</sup>x'')<sup>1/2</sup>}}.
+If {{mvar|B}} is a vector space of linear maps on the vector space {{mvar|A}}, then {{math|σ(''A'', ''B'')}} is defined to be the weakest topology on {{mvar|A}} such that all elements of {{mvar|B}} are continuous.
-*The '''[[norm topology]]''' or '''uniform topology''' or '''uniform operator topology'''  is defined by the usual norm ||''x''|| on ''B''(''H''). It is stronger than all the other topologies below.
-*The '''[[weak topology|weak (Banach space) topology]]'''  is σ(''B''(''H''), ''B''(''H'')<sup>*</sup>), in other words the weakest topology such that all elements of the dual ''B''(''H'')<sup>*</sup> are continuous. It is the weak topology on the Banach space ''B''(''H''). It is stronger than the ultraweak and weak operator topologies. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
-*The '''[[Mackey topology]]''' or '''Arens-Mackey topology''' is the strongest locally convex topology on ''B''(''H'') such that the dual is ''B''(''H'')<sub>*</sub>, and is also the uniform convergence topology on σ(''B''(''H'')<sub>*</sub>, ''B''(''H'')-compact convex subsets of ''B''(''H'')<sub>*</sub>. It is stronger than all topologies below.
-*The '''σ-strong<sup>*</sup> topology''' or '''ultrastrong<sup>*</sup> topology'''  is the weakest topology stronger than the ultrastrong topology such that the adjoint map is continuous. It is defined by the family of seminorms ''p''<sub>''w''</sub>(''x'') and ''p''<sub>''w''</sub>(''x''<sup>*</sup>) for positive elements ''w'' of ''B''(''H'')<sub>*</sub>. It is stronger than all topologies below.
-*The '''σ-strong topology''' or '''[[ultrastrong topology]]''' or '''strongest  topology''' or '''strongest  operator topology''' is defined by the family of seminorms ''p''<sub>''w''</sub>(''x'') for positive elements ''w'' of ''B''(''H'')<sub>*</sub>. It is stronger than all the topologies below other than the strong<sup>*</sup> topology. Warning: in spite of the name "strongest topology", it is weaker than the norm topology.)
-*The '''σ-weak topology''' or '''ultraweak topology''' or '''[[weak-star operator topology|weak<sup>*</sup> operator topology]]''' or '''weak * topology''' or '''weak topology''' or '''σ(''B''(''H''), ''B''(''H'')<sub>*</sub>) topology''' is defined by the family of seminorms |(''w'', ''x'')| for elements ''w'' of ''B''(''H'')<sub>*</sub>. It is stronger than the weak operator topology. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
-*The '''strong<sup>*</sup> operator topology'''  or '''strong<sup>*</sup> topology''' is defined by the seminorms ||''x''(''h'')|| and ||''x''<sup>*</sup>(''h'')|| for ''h'' in ''H''. It is stronger than the strong and weak operator topologies.
-*The '''[[strong operator topology]]''' (SOT) or '''strong topology''' is defined by the seminorms ||''x''(''h'')|| for ''h'' in ''H''. It is stronger than the  weak operator topology.
-*The '''[[weak operator topology]]''' (WOT) or '''weak topology''' is defined by the seminorms |(''x''(''h''<sub>1</sub>), ''h''<sub>2</sub>)| for ''h''<sub>1</sub> and ''h''<sub>2</sub> in ''H''. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
+* The '''[[norm topology]]''' or '''uniform topology''' or '''uniform operator topology''' is defined by the usual norm ||''x''|| on {{math|B(''H'')}}. It is stronger than all the other topologies below.
-==Relations between the topologies==
+* The '''[[Weak topology|weak (Banach space) topology]]''' is {{math|σ(B(''H''), B(''H'')<sup>*</sup>)}}, in other words the weakest topology such that all elements of the dual {{math|B(''H'')<sup>*</sup>}} are continuous. It is the weak topology on the Banach space {{math|B(''H'')}}. It is stronger than the ultraweak and weak operator topologies. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
+* The '''[[Mackey topology]]''' or '''Arens-Mackey topology''' is the strongest locally convex topology on {{math|B(''H'')}} such that the dual is {{math|B(''H'')<sub>*</sub>}}, and is also the uniform convergence topology on {{math|Bσ(B(''H'')<sub>*</sub>}}, {{math|B(''H'')}}-compact convex subsets of {{math|B(''H'')<sub>*</sub>}}. It is stronger than all topologies below.
+* The '''σ-strong-<sup>*</sup> topology''' or '''ultrastrong-<sup>*</sup> topology''' is the weakest topology stronger than the ultrastrong topology such that the adjoint map is continuous. It is defined by the family of seminorms {{math|''p''<sub>''w''</sub>(''x'')}} and {{math|''p''<sub>''w''</sub>(''x''<sup>*</sup>)}} for positive elements {{mvar|w}} of {{math|B(''H'')<sub>*</sub>}}. It is stronger than all topologies below.
+*The '''σ-strong topology''' or '''[[ultrastrong topology]]''' or '''strongest topology''' or '''strongest operator topology''' is defined by the family of seminorms {{math|''p''<sub>''w''</sub>(''x'')}} for positive elements {{mvar|w}} of {{math|B(''H'')<sub>*</sub>}}. It is stronger than all the topologies below other than the strong<sup>*</sup> topology. Warning: in spite of the name "strongest topology", it is weaker than the norm topology.)
+*The '''σ-weak topology''' or '''ultraweak topology''' or '''[[weak-star operator topology|weak-<sup>*</sup> operator topology]]''' or '''weak-* topology''' or '''weak topology''' or '''{{math|σ(B(''H''), B(''H'')<sub>*</sub>}}) topology''' is defined by the family of seminorms |(''w'', ''x'')| for elements ''w'' of {{math|B(''H'')<sub>*</sub>}}. It is stronger than the weak operator topology. (Warning: the weak Banach space topology and the weak operator topology and the ultraweak topology are all sometimes called the weak topology, but they are different.)
+* The '''[[Strong-* operator topology|strong-<sup>*</sup> operator topology]]''' or '''strong-<sup>*</sup> topology''' is defined by the seminorms ||''x''(''h'')|| and ||''x''<sup>*</sup>(''h'')|| for {{math|''h'' ∈ ''H''}}. It is stronger than the strong and weak operator topologies.
+* The '''[[strong operator topology]]''' (SOT) or '''strong topology''' is defined by the seminorms ||''x''(''h'')|| for {{math|''h'' ∈ ''H''}}. It is stronger than the weak operator topology.
+* The '''[[weak operator topology]]''' (WOT) or '''weak topology''' is defined by the seminorms |(''x''(''h''<sub>1</sub>), ''h''<sub>2</sub>)| for {{math|''h''<sub>1</sub>, ''h''<sub>2</sub> ∈ ''H''}}. (Warning: the weak Banach space topology, the weak operator topology, and the ultraweak topology are all sometimes called the weak topology, but they are different.)
+== Relations between the topologies ==
-The continuous linear functionals on ''B''(''H'') for the weak, strong, and strong<sup>*<sup> (operator) topologies are the same, and are the finite linear combinations of the linear functionals
-(x''h''<sub>1</sub>, ''h''<sub>2</sub>) for ''h''<sub>1</sub>, ''h''<sub>2</sub> in ''H''. The continuous linear functionals on ''B''(''H'') for the ultraweak, ultrastrong, ultrastrong<sup>*<sup> and Arens-Mackey topologies are the same, and are the elements of
-the predual ''B''(''H'')<sub>*</sub>. The continuous linear functions in the norm topology
-form a rather large space with many pathological elements.
-On any (norm) bounded subset of ''B''(''H''), the Arens-Mackey topology, the ultrastrong<sup>*</sup>, and  the strong<sup>*</sup> topology are the same.
+The continuous linear functionals on {{math|B(''H'')}} for the weak, strong, and strong<sup>*</sup> (operator) topologies are the same, and are the finite linear combinations of the linear functionals
+(x''h''<sub>1</sub>, ''h''<sub>2</sub>) for {{math|''h''<sub>1</sub>, ''h''<sub>2</sub> ∈ ''H''}}.
-On any (norm) bounded subset of ''B''(''H'') the ultrastrong
+The continuous linear functionals on {{math|B(''H'')}} for the ultraweak, ultrastrong, ultrastrong<sup>*</sup> and Arens-Mackey topologies are the same, and are the elements of the predual {{math|B(''H'')<sub>*</sub>}}.
-topology is the same as the strong topology. On any (norm) bounded subset of ''B''(''H'')  the ultraweak topology is the same as the weak (operator) topology.
+By definition, the continuous linear functionals in the norm topology are the same as those in the weak Banach space topology.
-For a [[convex set|convex]] subset ''K'' of ''B''(''H''), the conditions that
+This dual is a rather large space with many pathological elements.
-''K'' be closed in the ultrastrong<sup>*</sup>, ultrastrong, and ultraweak topologies are all equivalent, and are also equivalent to the conditions that
-for all ''x'', ''K'' has closed intersection with the closed ball of radius ''x'' in the strong<sup>*</sup>, strong, or weak (operator) topologies.
-The closed unit ball of ''B''(''H'') is compact in the weak (operator) and ultraweak topologies.
+On norm bounded sets of {{math|B(''H'')}}, the weak (operator) and ultraweak topologies coincide. This can be seen via, for instance, the [[Banach–Alaoglu theorem]].
+For essentially the same reason, the ultrastrong
+topology is the same as the strong topology on any (norm) bounded subset of {{math|B(''H'')}}.
+Same is true for the Arens-Mackey topology, the ultrastrong<sup>*</sup>, and the strong<sup>*</sup> topology.
+In locally convex spaces, closure of convex sets can be characterized by the continuous linear functionals. Therefore, for a [[convex set|convex]] subset {{mvar|K}} of {{math|B(''H'')}}, the conditions that {{mvar|K}} be closed in the ultrastrong<sup>*</sup>, ultrastrong, and ultraweak topologies are all equivalent and are also equivalent to the conditions that
-The norm topology is metrizable and the others are not. However, when ''H'' is separable, all the topologies above are metrizable when restricted to the unit ball (or to any norm-bounded subset).
+for all {{math|''r'' > 0}}, {{mvar|K}} has closed intersection with the closed ball of radius {{mvar|r}} in the strong<sup>*</sup>, strong, or weak (operator) topologies.
+The norm topology is metrizable and the others are not; in fact they fail to be [[first-countable]].
-==Which topology should I use?==
+However, when {{mvar|H}} is separable, all the topologies above are metrizable when restricted to the unit ball (or to any norm-bounded subset).
+== Topology to use ==
-The most commonly used topologies are the norm, strong, and weak topologies. The weak topology is useful for compactness arguments as the unit ball is compact. The norm topology makes ''B''(''H'') into a Banach space, but is too strong for many purposes (for example, ''B''(''H'') is not separable in this topology). The strong topology is a sort of general purpose topology and probably the most commonly used.
+The most commonly used topologies are the norm, strong, and weak operator topologies.
-The ultraweak and ultrastrong topologies are better in some ways than the weak and strong topologies, but their definitions are more complicated, so they are usually not used unless their better properties are really needed. For example, the dual space of ''B''(''H'') in the weak or strong topologies is usually too small.
+The weak operator topology is useful for compactness arguments, because the unit ball is compact by the [[Banach–Alaoglu theorem]].
+The norm topology is fundamental because it makes {{math|B(''H'')}} into a Banach space, but it is too strong for many purposes; for example, {{math|B(''H'')}} is not separable in this topology.
+The strong operator topology could be the most commonly used.
-The adjoint map is not continuous in the strong and ultrastrong topologies, and the strong<sup>*</sup> and ultrastrong<sup>*</sup> topologies are modifications so that the adjoint becomes continuous. They are not used very often.
+The ultraweak and ultrastrong topologies are better-behaved than the weak and strong operator topologies, but their definitions are more complicated, so they are usually not used unless their better properties are really needed.
+For example, the dual space of {{math|B(''H'')}} in the weak or strong operator topology is too small to have much analytic content.
+The adjoint map is not continuous in the strong operator and ultrastrong topologies, while the strong* and ultrastrong* topologies are modifications so that the adjoint becomes continuous. They are not used very often.
-The Arens-Mackey topology and the weak Banach space topology are very rarely used.
+The Arens–Mackey topology and the weak Banach space topology are relatively rarely used.
-To summarize, the three essential topologies are the norm, ultrastrong, and ultraweak topologies, and it is rarely necessary to use any other topology. The weak and strong topologies are widely used as cheap approximations to the ultraweak and ultrastrong topologies, and the remaining topologies are of little practical importance.
+To summarize, the three essential topologies on {{math|B(''H'')}} are the norm, ultrastrong, and ultraweak topologies.
+The weak and strong operator topologies are widely used as convenient approximations to the ultraweak and ultrastrong topologies. The other topologies are relatively obscure.
 == See also ==
-* [[Topology]]
-* [[Hilbert space]]
-* [[Bounded operator]]
+* {{annotated link|Bounded operator}}
-==References==
+* {{annotated link|Continuous linear operator}}
-*''Functional analysis'',by Reed and Simon, ISBN 0-12-585050-6
+* {{annotated link|Hilbert space}}
-*''Theory of Operator Algebras I'', by M. Takesaki (especially chapter II.2) ISBN 3-540-42248-X
+* {{annotated link|List of topologies}}
+* {{annotated link|Modes of convergence}}
+* {{annotated link|Norm (mathematics)}}
+* {{annotated link|Topologies on spaces of linear maps}}
+* {{annotated link|Vague topology}}
+* {{annotated link|Weak convergence (Hilbert space)}}
+== References ==
+* ''Functional analysis'', by Reed and Simon, {{ISBN|0-12-585050-6}}
+* ''Theory of Operator Algebras I'', by M. Takesaki (especially chapter II.2) {{ISBN|3-540-42248-X}}
+{{Banach spaces}}
+{{Hilbert space}}
+{{Duality and spaces of linear maps}}
+{{Functional analysis}}
+{{Topological vector spaces}}
+[[Category:Functional analysis]]
+[[Category:Topological vector spaces]]
 [[Category:Topology of function spaces|*]]

v t e Banach space topics
Types of Banach spaces	Asplund Banach list Banach lattice Grothendieck Hilbert Inner product space Polarization identity (Polynomially) Reflexive Riesz L-semi-inner product (B Strictly Uniformly) convex Uniformly smooth (Injective Projective) Tensor product (of Hilbert spaces)
Banach spaces are:	Barrelled Complete F-space Fréchet tame Locally convex Seminorms/Minkowski functionals Mackey Metrizable Normed norm Quasinormed Stereotype
Function space Topologies	Banach–Mazur compactum Dual Dual space Dual norm Operator Ultraweak Weak polar operator Strong polar operator Ultrastrong Uniform convergence
Linear operators	Adjoint Bilinear form operator sesquilinear (Un)Bounded Closed Compact on Hilbert spaces (Dis)Continuous Densely defined Fredholm kernel operator Hilbert–Schmidt Functionals positive Pseudo-monotone Normal Nuclear Self-adjoint Strictly singular Trace class Transpose Unitary
Operator theory	Banach algebras C-algebras Operator space Spectrum C-algebra radius Spectral theory of ODEs Spectral theorem Polar decomposition Singular value decomposition
Theorems	Anderson–Kadec Banach–Alaoglu Banach–Mazur Banach–Saks Banach–Schauder (open mapping) Banach–Steinhaus (Uniform boundedness) Bessel's inequality Cauchy–Schwarz inequality Closed graph Closed range Eberlein–Šmulian Freudenthal spectral Gelfand–Mazur Gelfand–Naimark Goldstine Hahn–Banach hyperplane separation Kakutani fixed-point Krein–Milman Lomonosov's invariant subspace Mackey–Arens Mazur's lemma M. Riesz extension Parseval's identity Riesz's lemma Riesz representation Robinson-Ursescu Schauder fixed-point
Analysis	Abstract Wiener space Banach manifold bundle Bochner space Convex series Differentiation in Fréchet spaces Derivatives Fréchet Gateaux functional holomorphic quasi Integrals Bochner Dunford Gelfand–Pettis regulated Paley–Wiener weak Functional calculus Borel continuous holomorphic Measures Lebesgue Projection-valued Vector Weakly / Strongly measurable function
Types of sets	Absolutely convex Absorbing Affine Balanced/Circled Bounded Convex Convex cone (subset) Convex series related ((cs, lcs)-closed, (cs, bcs)-complete, (lower) ideally convex, (Hx), and (Hwx)) Linear cone (subset) Radial Radially convex/Star-shaped Symmetric Zonotope
Subsets / set operations	Affine hull (Relative) Algebraic interior (core) Bounding points Convex hull Extreme point Interior Linear span Minkowski addition Polar (Quasi) Relative interior
Examples	Absolute continuity AC $ba(\Sigma )$ c space Banach coordinate BK Besov $B_{p,q}^{s}(\mathbb {R} )$ Birnbaum–Orlicz Bounded variation BV Bs space Continuous C(K) with K compact Hausdorff Hardy H^p Hilbert H Morrey–Campanato $L^{\lambda ,p}(\Omega )$ ℓ^p $\ell ^{\infty }$ L^p $L^{\infty }$ weighted Schwartz $S\left(\mathbb {R} ^{n}\right)$ Segal–Bargmann F Sequence space Sobolev W^k,p Sobolev inequality Triebel–Lizorkin Wiener amalgam $W(X,L^{p})$
Applications	Differential operator Finite element method Mathematical formulation of quantum mechanics Ordinary Differential Equations (ODEs) Validated numerics

v t e Hilbert spaces
Basic concepts	Adjoint Inner product and L-semi-inner product Hilbert space and Prehilbert space Orthogonal complement Orthonormal basis
Main results	Bessel's inequality Cauchy–Schwarz inequality Riesz representation
Other results	Hilbert projection theorem Parseval's identity Polarization identity (Parallelogram law)
Maps	Compact operator on Hilbert space Densely defined Hermitian form Hilbert–Schmidt Normal Self-adjoint Sesquilinear form Trace class Unitary
Examples	Cⁿ(K) with K compact & n<∞ Segal–Bargmann F

v t e Duality and spaces of linear maps
Basic concepts	Dual space Dual system Dual topology Duality Operator topologies Polar set Polar topology Topologies on spaces of linear maps
Topologies	Norm topology Dual norm Ultraweak/Weak-* Weak polar operator in Hilbert spaces Mackey Strong dual polar topology operator Ultrastrong
Main results	Banach–Alaoglu Mackey–Arens
Maps	Transpose of a linear map
Subsets	Saturated family Total set
Other concepts	Biorthogonal system

v t e Topological vector spaces (TVSs)
Basic concepts	Banach space Completeness Continuous linear operator Linear functional Fréchet space Linear map Locally convex space Metrizability Operator topologies Topological vector space Vector space
Main results	Anderson–Kadec Banach–Alaoglu Closed graph theorem F. Riesz's Hahn–Banach (hyperplane separation Vector-valued Hahn–Banach) Open mapping (Banach–Schauder) Bounded inverse Uniform boundedness (Banach–Steinhaus)
Maps	Bilinear operator form Linear map Almost open Bounded Continuous Closed Compact Densely defined Discontinuous Topological homomorphism Functional Linear Bilinear Sesquilinear Norm Seminorm Sublinear function Transpose
Types of sets	Absolutely convex/disk Absorbing/Radial Affine Balanced/Circled Banach disks Bounding points Bounded Complemented subspace Convex Convex cone (subset) Linear cone (subset) Extreme point Pre-compact/Totally bounded Prevalent/Shy Radial Radially convex/Star-shaped Symmetric
Set operations	Affine hull (Relative) Algebraic interior (core) Convex hull Linear span Minkowski addition Polar (Quasi) Relative interior
Types of TVSs	Asplund B-complete/Ptak Banach (Countably) Barrelled BK-space (Ultra-) Bornological Brauner Complete Convenient (DF)-space Distinguished F-space FK-AK space FK-space Fréchet tame Fréchet Grothendieck Hilbert Infrabarreled Interpolation space K-space LB-space LF-space Locally convex space Mackey (Pseudo)Metrizable Montel Quasibarrelled Quasi-complete Quasinormed (Polynomially Semi-) Reflexive Riesz Schwartz Semi-complete Smith Stereotype (B Strictly Uniformly) convex (Quasi-) Ultrabarrelled Uniformly smooth Webbed With the approximation property
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