Auxiliary normed space

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In functional analysis, a branch of mathematics, two methods of constructing normed spaces from disks were systematically employed by Alexander Grothendieck to define nuclear operators and nuclear spaces.^[1] One method is used if the disk ${\displaystyle D}$ is bounded: in this case, the auxiliary normed space is ${\displaystyle \mathrm{span}D}$ with norm $${\displaystyle p_D(x):=\underset{x\in rD,r>0}{\inf }r.}$$ The other method is used if the disk ${\displaystyle D}$ is absorbing: in this case, the auxiliary normed space is the quotient space ${\displaystyle X/p_D^{-1}(0).}$ If the disk is both bounded and absorbing then the two auxiliary normed spaces are canonically isomorphic (as topological vector spaces and as normed spaces).

Induced by a bounded disk – Banach disks

Throughout this article, ${\displaystyle X}$ will be a real or complex vector space (not necessarily a TVS, yet) and ${\displaystyle D}$ will be a disk in ${\displaystyle X.}$

Seminormed space induced by a disk

Let ${\displaystyle X}$ will be a real or complex vector space. For any subset ${\displaystyle D}$ of ${\displaystyle X,}$ the Minkowski functional of ${\displaystyle D}$ defined by:

• If ${\displaystyle D=\varnothing }$ then define ${\displaystyle p_{\varnothing }(x):\{0\}\to [0,\mathrm{\infty })}$ to be the trivial map ${\displaystyle p_{\varnothing }=0}$^[2] and it will be assumed that ${\displaystyle \mathrm{span}\varnothing =\{0\}.}$^{[note 1]}
• If ${\displaystyle D\ne \varnothing }$ and if ${\displaystyle D}$ is absorbing in ${\displaystyle \mathrm{span}D}$ then denote the Minkowski functional of ${\displaystyle D}$ in ${\displaystyle \mathrm{span}D}$ by $${\displaystyle p_D:\mathrm{span}D\to [0,\mathrm{\infty })}$$ where for all ${\displaystyle x\in \mathrm{span}D,}$ this is defined by $${\displaystyle p_D(x):=\underset{}{\inf }\{r:x\in rD,r>0\}.}$$

Let ${\displaystyle X}$ will be a real or complex vector space. For any subset ${\displaystyle D}$ of ${\displaystyle X}$ such that the Minkowski functional ${\displaystyle p_D}$ is a seminorm on ${\displaystyle \mathrm{span}D,}$ let ${\displaystyle X_D}$ denote $${\displaystyle X_D:=(\mathrm{span}D,p_D)}$$ which is called the seminormed space induced by ${\displaystyle D,}$ where if ${\displaystyle p_D}$ is a norm then it is called the normed space induced by ${\displaystyle D.}$ Assumption (Topology): ${\displaystyle X_D=\mathrm{span}D}$ is endowed with the seminorm topology induced by ${\displaystyle p_D,}$ which will be denoted by ${\displaystyle {\tau }_D}$ or ${\displaystyle {\tau }_{p_D}}$ Importantly, this topology stems entirely from the set ${\displaystyle D,}$ the algebraic structure of ${\displaystyle X,}$ and the usual topology on ${\displaystyle \mathbb{ℝ}}$ (since ${\displaystyle p_D}$ is defined using only the set ${\displaystyle D}$ and scalar multiplication). This justifies the study of Banach disks and is part of the reason why they play an important role in the theory of nuclear operators and nuclear spaces. The inclusion map ${\displaystyle {\mathrm{In}}_D:X_D\to X}$ is called the canonical map.^[1] Suppose that ${\displaystyle D}$ is a disk. Then $\mathrm{span}D={\bigcup }_{n=1}^{\mathrm{\infty }}nD$ so that ${\displaystyle D}$ is absorbing in ${\displaystyle \mathrm{span}D,}$ the linear span of ${\displaystyle D.}$ The set ${\displaystyle \{rD:r>0\}}$ of all positive scalar multiples of ${\displaystyle D}$ forms a basis of neighborhoods at the origin for a locally convex topological vector space topology ${\displaystyle {\tau }_D}$ on ${\displaystyle \mathrm{span}D.}$ The Minkowski functional of the disk ${\displaystyle D}$ in ${\displaystyle \mathrm{span}D}$ guarantees that ${\displaystyle p_D}$ is well-defined and forms a seminorm on ${\displaystyle \mathrm{span}D.}$^[3] The locally convex topology induced by this seminorm is the topology ${\displaystyle {\tau }_D}$ that was defined before.

Banach disk definition

A bounded disk ${\displaystyle D}$ in a topological vector space ${\displaystyle X}$ such that ${\displaystyle (X_D,p_D)}$ is a Banach space is called a Banach disk, infracomplete, or a bounded completant in ${\displaystyle X.}$ If its shown that ${\displaystyle (\mathrm{span}D,p_D)}$ is a Banach space then ${\displaystyle D}$ will be a Banach disk in any TVS that contains ${\displaystyle D}$ as a bounded subset. This is because the Minkowski functional ${\displaystyle p_D}$ is defined in purely algebraic terms. Consequently, the question of whether or not ${\displaystyle (X_D,p_D)}$ forms a Banach space is dependent only on the disk ${\displaystyle D}$ and the Minkowski functional ${\displaystyle p_D,}$ and not on any particular TVS topology that ${\displaystyle X}$ may carry. Thus the requirement that a Banach disk in a TVS ${\displaystyle X}$ be a bounded subset of ${\displaystyle X}$ is the only property that ties a Banach disk's topology to the topology of its containing TVS ${\displaystyle X.}$

Properties of disk induced seminormed spaces

Bounded disks The following result explains why Banach disks are required to be bounded.

Hausdorffness The space ${\displaystyle (X_D,p_D)}$ is Hausdorff if and only if ${\displaystyle p_D}$ is a norm, which happens if and only if ${\displaystyle D}$ does not contain any non-trivial vector subspace.^[6] In particular, if there exists a Hausdorff TVS topology on ${\displaystyle X}$ such that ${\displaystyle D}$ is bounded in ${\displaystyle X}$ then ${\displaystyle p_D}$ is a norm. An example where ${\displaystyle X_D}$ is not Hausdorff is obtained by letting ${\displaystyle X={\mathbb{ℝ}}^2}$ and letting ${\displaystyle D}$ be the ${\displaystyle x}$-axis. Convergence of nets Suppose that ${\displaystyle D}$ is a disk in ${\displaystyle X}$ such that ${\displaystyle X_D}$ is Hausdorff and let ${\displaystyle x_{\bullet }={\left(x_i\right)}_{i\in I}}$ be a net in ${\displaystyle X_D.}$ Then ${\displaystyle x_{\bullet }\to 0}$ in ${\displaystyle X_D}$ if and only if there exists a net ${\displaystyle r_{\bullet }={\left(r_i\right)}_{i\in I}}$ of real numbers such that ${\displaystyle r_{\bullet }\to 0}$ and ${\displaystyle x_i\in r_{i}D}$ for all ${\displaystyle i}$; moreover, in this case it will be assumed without loss of generality that ${\displaystyle r_i\ge 0}$ for all ${\displaystyle i.}$ Relationship between disk-induced spaces If ${\displaystyle C\subseteq D\subseteq X}$ then ${\displaystyle \mathrm{span}C\subseteq \mathrm{span}D}$ and ${\displaystyle p_D\le p_C}$ on ${\displaystyle \mathrm{span}C,}$ so define the following continuous^[5] linear map: If ${\displaystyle C}$ and ${\displaystyle D}$ are disks in ${\displaystyle X}$ with ${\displaystyle C\subseteq D}$ then call the inclusion map ${\displaystyle {\mathrm{In}}_C^D:X_C\to X_D}$ the canonical inclusion of ${\displaystyle X_C}$ into ${\displaystyle X_D.}$ In particular, the subspace topology that ${\displaystyle \mathrm{span}C}$ inherits from ${\displaystyle (X_D,p_D)}$ is weaker than ${\displaystyle (X_C,p_C)}$'s seminorm topology.^[5] The disk as the closed unit ball The disk ${\displaystyle D}$ is a closed subset of ${\displaystyle (X_D,p_D)}$ if and only if ${\displaystyle D}$ is the closed unit ball of the seminorm ${\displaystyle p_D}$; that is, ${\displaystyle D=\{x\in \mathrm{span}D:p_D(x)\le 1\}.}$ If ${\displaystyle D}$ is a disk in a vector space ${\displaystyle X}$ and if there exists a TVS topology ${\displaystyle \tau }$ on ${\displaystyle \mathrm{span}D}$ such that ${\displaystyle D}$ is a closed and bounded subset of ${\displaystyle (\mathrm{span}D,\tau ),}$ then ${\displaystyle D}$ is the closed unit ball of ${\displaystyle (X_D,p_D)}$ (that is, ${\displaystyle D=\{x\in \mathrm{span}D:p_D(x)\le 1\}}$ ) (see footnote for proof).^{[note 2]}

Sufficient conditions for a Banach disk

The following theorem may be used to establish that ${\displaystyle (X_D,p_D)}$ is a Banach space. Once this is established, ${\displaystyle D}$ will be a Banach disk in any TVS in which ${\displaystyle D}$ is bounded.

Note that even if ${\displaystyle D}$ is not a bounded and sequentially complete subset of any Hausdorff TVS, one might still be able to conclude that ${\displaystyle (X_D,p_D)}$ is a Banach space by applying this theorem to some disk ${\displaystyle K}$ satisfying $${\displaystyle \{x\in \mathrm{span}D:p_D(x)<1\}\subseteq K\subseteq \{x\in \mathrm{span}D:p_D(x)\le 1\}}$$ because ${\displaystyle p_D=p_K.}$ The following are consequences of the above theorem:

• A sequentially complete bounded disk in a Hausdorff TVS is a Banach disk.^[5]
• Any disk in a Hausdorff TVS that is complete and bounded (e.g. compact) is a Banach disk.^[8]
• The closed unit ball in a Fréchet space is sequentially complete and thus a Banach disk.^[5]

Suppose that ${\displaystyle D}$ is a bounded disk in a TVS ${\displaystyle X.}$

• If ${\displaystyle L:X\to Y}$ is a continuous linear map and ${\displaystyle B\subseteq X}$ is a Banach disk, then ${\displaystyle L(B)}$ is a Banach disk and ${\displaystyle L{|}_{X_B}:X_B\to L\left(X_B\right)}$ induces an isometric TVS-isomorphism ${\displaystyle Y_{L(B)}\cong X_B/(X_B\cap \ker L).}$

Properties of Banach disks

Let ${\displaystyle X}$ be a TVS and let ${\displaystyle D}$ be a bounded disk in ${\displaystyle X.}$ If ${\displaystyle D}$ is a bounded Banach disk in a Hausdorff locally convex space ${\displaystyle X}$ and if ${\displaystyle T}$ is a barrel in ${\displaystyle X}$ then ${\displaystyle T}$ absorbs ${\displaystyle D}$ (that is, there is a number ${\displaystyle r>0}$ such that ${\displaystyle D\subseteq rT.}$^[4] If ${\displaystyle U}$ is a convex balanced closed neighborhood of the origin in ${\displaystyle X}$ then the collection of all neighborhoods ${\displaystyle rU,}$ where ${\displaystyle r>0}$ ranges over the positive real numbers, induces a topological vector space topology on ${\displaystyle X.}$ When ${\displaystyle X}$ has this topology, it is denoted by ${\displaystyle X_U.}$ Since this topology is not necessarily Hausdorff nor complete, the completion of the Hausdorff space ${\displaystyle X/p_U^{-1}(0)}$ is denoted by ${\displaystyle \overline{X_U}}$ so that ${\displaystyle \overline{X_U}}$ is a complete Hausdorff space and ${\displaystyle p_U(x):=\underset{x\in rU,r>0}{\inf }r}$ is a norm on this space making ${\displaystyle \overline{X_U}}$ into a Banach space. The polar of ${\displaystyle U,}$ ${\displaystyle U^{\circ },}$ is a weakly compact bounded equicontinuous disk in ${\displaystyle X^{\prime }}$ and so is infracomplete. If ${\displaystyle X}$ is a metrizable locally convex TVS then for every bounded subset ${\displaystyle B}$ of ${\displaystyle X,}$ there exists a bounded disk ${\displaystyle D}$ in ${\displaystyle X}$ such that ${\displaystyle B\subseteq X_D,}$ and both ${\displaystyle X}$ and ${\displaystyle X_D}$ induce the same subspace topology on ${\displaystyle B.}$^[5]

Induced by a radial disk – quotient

Suppose that ${\displaystyle X}$ is a topological vector space and ${\displaystyle V}$ is a convex balanced and radial set. Then ${\displaystyle \{\frac{1}{n}V:n=1,2,\dots \}}$ is a neighborhood basis at the origin for some locally convex topology ${\displaystyle {\tau }_V}$ on ${\displaystyle X.}$ This TVS topology ${\displaystyle {\tau }_V}$ is given by the Minkowski functional formed by ${\displaystyle V,}$ ${\displaystyle p_V:X\to \mathbb{ℝ},}$ which is a seminorm on ${\displaystyle X}$ defined by ${\displaystyle p_V(x):=\underset{x\in rV,r>0}{\inf }r.}$ The topology ${\displaystyle {\tau }_V}$ is Hausdorff if and only if ${\displaystyle p_V}$ is a norm, or equivalently, if and only if ${\displaystyle X/p_V^{-1}(0)=\{0\}}$ or equivalently, for which it suffices that ${\displaystyle V}$ be bounded in ${\displaystyle X.}$ The topology ${\displaystyle {\tau }_V}$ need not be Hausdorff but ${\displaystyle X/p_V^{-1}(0)}$ is Hausdorff. A norm on ${\displaystyle X/p_V^{-1}(0)}$ is given by ${\displaystyle \Vert x+X/p_V^{-1}(0)\Vert :=p_V(x),}$ where this value is in fact independent of the representative of the equivalence class ${\displaystyle x+X/p_V^{-1}(0)}$ chosen. The normed space ${\displaystyle (X/p_V^{-1}(0),\Vert \cdot \Vert )}$ is denoted by ${\displaystyle X_V}$ and its completion is denoted by ${\displaystyle \overline{X_V}.}$ If in addition ${\displaystyle V}$ is bounded in ${\displaystyle X}$ then the seminorm ${\displaystyle p_V:X\to \mathbb{ℝ}}$ is a norm so in particular, ${\displaystyle p_V^{-1}(0)=\{0\}.}$ In this case, we take ${\displaystyle X_V}$ to be the vector space ${\displaystyle X}$ instead of ${\displaystyle X/\{0\}}$ so that the notation ${\displaystyle X_V}$ is unambiguous (whether ${\displaystyle X_V}$ denotes the space induced by a radial disk or the space induced by a bounded disk).^[1] The quotient topology ${\displaystyle {\tau }_Q}$ on ${\displaystyle X/p_V^{-1}(0)}$ (inherited from ${\displaystyle X}$'s original topology) is finer (in general, strictly finer) than the norm topology.

Canonical maps

The canonical map is the quotient map ${\displaystyle q_V:X\to X_V=X/p_V^{-1}(0),}$ which is continuous when ${\displaystyle X_V}$ has either the norm topology or the quotient topology.^[1] If ${\displaystyle U}$ and ${\displaystyle V}$ are radial disks such that ${\displaystyle U\subseteq V}$ then ${\displaystyle p_U^{-1}(0)\subseteq p_V^{-1}(0)}$ so there is a continuous linear surjective canonical map ${\displaystyle q_{V,U}:X/p_U^{-1}(0)\to X/p_V^{-1}(0)=X_V}$ defined by sending ${\displaystyle x+p_U^{-1}(0)\in X_U=X/p_U^{-1}(0)}$ to the equivalence class ${\displaystyle x+p_V^{-1}(0),}$ where one may verify that the definition does not depend on the representative of the equivalence class ${\displaystyle x+p_U^{-1}(0)}$ that is chosen.^[1] This canonical map has norm ${\displaystyle \le 1}$^[1] and it has a unique continuous linear canonical extension to ${\displaystyle \overline{X_U}}$ that is denoted by ${\displaystyle \overline{g_{V,U}}:\overline{X_U}\to \overline{X_V}.}$ Suppose that in addition ${\displaystyle B\ne \varnothing }$ and ${\displaystyle C}$ are bounded disks in ${\displaystyle X}$ with ${\displaystyle B\subseteq C}$ so that ${\displaystyle X_B\subseteq X_C}$ and the inclusion ${\displaystyle {\mathrm{In}}_B^C:X_B\to X_C}$ is a continuous linear map. Let ${\displaystyle {\mathrm{In}}_B:X_B\to X,}$ ${\displaystyle {\mathrm{In}}_C:X_C\to X,}$ and ${\displaystyle {\mathrm{In}}_B^C:X_B\to X_C}$ be the canonical maps. Then ${\displaystyle {\mathrm{In}}_C={\mathrm{In}}_B^C\circ {\mathrm{In}}_C:X_B\to X_C}$ and ${\displaystyle q_V=q_{V,U}\circ q_U.}$^[1]

Induced by a bounded radial disk

Suppose that ${\displaystyle S}$ is a bounded radial disk. Since ${\displaystyle S}$ is a bounded disk, if ${\displaystyle D:=S}$ then we may create the auxiliary normed space ${\displaystyle X_D=\mathrm{span}D}$ with norm ${\displaystyle p_D(x):=\underset{x\in rD,r>0}{\inf }r}$; since ${\displaystyle S}$ is radial, ${\displaystyle X_S=X.}$ Since ${\displaystyle S}$ is a radial disk, if ${\displaystyle V:=S}$ then we may create the auxiliary seminormed space ${\displaystyle X/p_V^{-1}(0)}$ with the seminorm ${\displaystyle p_V(x):=\underset{x\in rV,r>0}{\inf }r}$; because ${\displaystyle S}$ is bounded, this seminorm is a norm and ${\displaystyle p_V^{-1}(0)=\{0\}}$ so ${\displaystyle X/p_V^{-1}(0)=X/\{0\}=X.}$ Thus, in this case the two auxiliary normed spaces produced by these two different methods result in the same normed space.

Duality

Suppose that ${\displaystyle H}$ is a weakly closed equicontinuous disk in ${\displaystyle X^{\prime }}$ (this implies that ${\displaystyle H}$ is weakly compact) and let $${\displaystyle U:=H^{\circ }=\{x\in X:|h(x)|\le 1\text{ for all }h\in H\}}$$ be the polar of ${\displaystyle H.}$ Because ${\displaystyle U^{\circ }=H^{\circ \circ }=H}$ by the bipolar theorem, it follows that a continuous linear functional ${\displaystyle f}$ belongs to ${\displaystyle X_H^{\prime }=\mathrm{span}H}$ if and only if ${\displaystyle f}$ belongs to the continuous dual space of ${\displaystyle (X,p_U),}$ where ${\displaystyle p_U}$ is the Minkowski functional of ${\displaystyle U}$ defined by ${\displaystyle p_U(x):=\underset{x\in rU,r>0}{\inf }r.}$^[9]

Related concepts

A disk in a TVS is called infrabornivorous^[5] if it absorbs all Banach disks. A linear map between two TVSs is called infrabounded^[5] if it maps Banach disks to bounded disks.

Fast convergence

A sequence ${\displaystyle x_{\bullet }={\left(x_i\right)}_{i=1}^{\mathrm{\infty }}}$ in a TVS ${\displaystyle X}$ is said to be fast convergent^[5] to a point ${\displaystyle x\in X}$ if there exists a Banach disk ${\displaystyle D}$ such that both ${\displaystyle x}$ and the sequence is (eventually) contained in ${\displaystyle \mathrm{span}D}$ and ${\displaystyle x_{\bullet }\to x}$ in ${\displaystyle (X_D,p_D).}$ Every fast convergent sequence is Mackey convergent.^[5]

See also

• Bornological space – Space where bounded operators are continuous
• Injective tensor product
• Locally convex topological vector space – A vector space with a topology defined by convex open sets
• Nuclear operator – Linear operator related to topological vector spaces
• Nuclear space – A generalization of finite-dimensional Euclidean spaces different from Hilbert spaces
• Initial topology – Coarsest topology making certain functions continuous
• Projective tensor product
• Schwartz topological vector space
• Tensor product of Hilbert spaces – Tensor product space endowed with a special inner product
• Topological tensor product – Tensor product constructions for topological vector spaces
• Ultrabornological space

Notes

References

Bibliography

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External links

• Nuclear space at ncatlab