Functional Analysis/Topological vector spaces

(May 28, 2008)

A vector space endowed by a topology that makes translations (i.e., $x+y$ ) and dilations (i.e., $\alpha x$ ) continuous is called a topological vector space or TVS for short.

A subset $E$ of a TVS is said to be:

bounded if for every neighborhood $V$ of $0$ there exist $s>0$ such that $E\subset tV$ for every $t>s$
balanced if $\lambda E\subset E$ for every scalar $\lambda$ with $|\lambda |\leq 1$
convex if $\lambda _{1}x+\lambda _{2}y\in E$ for any $x,y\in E$ and any $\lambda _{1},\lambda _{2}\geq 0$ with $\lambda _{1}x+\lambda _{2}y=1$ .

1 Corollary $(s+t)E=sE+tE$ for any $s,t>0$ if and only if $E$ is convex.
Proof: Supposing $s+t=1$ we obtain $sx+ty\in E$ for all $x,y\in E$ . Conversely, if $E$ is convex,

{s \over s+t}x+{t \over s+t}y\in E

, or

sx+sy\in (s+t)E

for any

x,y\in E

.

Since $(s+t)E\subset sE+tE$ holds in general, the proof is complete. $\square$

Define $f(\lambda ,x)=\lambda x$ for scalars $\lambda$ , vectors $x$ . If $E$ is a balanced set, for any $|\lambda |\leq 1$ , by continuity,

f(\lambda ,{\overline {E}})\subset {\overline {f(\lambda ,E)}}\subset {\overline {E}}

.

Hence, the closure of a balanced set is again balanced. In the similar manner, if $E$ is convex, for $s,t>0$

f((s+t),{\overline {E}})={\overline {f((s+t),E)}}={\overline {sE+tE}}

,

meaning the closure of a convex set is again convex. Here the first equality holds since $f(\lambda ,\cdot )$ is injective if $\lambda \neq 0$ . Moreover, the interior of $E$ , denoted by $E^{\circ }$ , is also convex. Indeed, for $\lambda _{1},\lambda _{2}\geq 0$ with $\lambda _{1}+\lambda _{2}=1$

\lambda _{1}E^{\circ }+\lambda _{2}E^{\circ }\subset E

,

and since the left-hand side is open it is contained in $E^{\circ }$ . Finally, a subspace of a TVS is a subset that is simultaneously a linear subspace and a topological subspace. Let ${\mathcal {M}}$ be a subspace of a TVS. Then ${\overline {\mathcal {M}}}$ is a topological subspace, and it is stable under scalar multiplication, as shown by the argument similar to the above. Let $g(x,y)=x+y$ . If ${\mathcal {M}}$ is a subspace of a TVS, by continuity and linearity,

g({\overline {\mathcal {M}}},{\overline {\mathcal {M}}})\subset {\overline {g({\mathcal {M}},{\mathcal {M}})}}={\overline {\mathcal {M}}}

.

Hence, ${\overline {\mathcal {M}}}$ is a linear subspace. We conclude that the closure of a subspace is a subspace.

Let $V$ be a neighborhood of $0$ . By continuity there exists a $\delta >0$ and a neighborhood $W$ of $0$ such that:

f(\{\lambda ;|\lambda |<\delta \},W)\subset V

It follows that the set $\{\lambda ;|\lambda |<\delta \}W$ is a union of open sets, contained in $V$ and is balanced. In other words, every TVS admits a local base consisting of balanced sets.

1 Theorem Let ${\mathcal {X}}$ be a TVS, and $E\subset {\mathcal {X}}$ . The following are equivalent.

(i) $E$ is bounded.
(ii) Every countable subset of $E$ is bounded.
(iii) for every balanced neighborhood $V$ of $0$ there exists a $t>0$ such that $E\subset tV$ .

Proof: That (i) implies (ii) is clear. If (iii) is false, there exists a balanced neighborhood $V$ such that $E\not \subset nV$ for every $n=1,2,...$ . That is, there is a unbounded sequence $x_{1},x_{2},...$ in $E$ . Finally, to show that (iii) implies (i), let $U$ be a neighborhood of 0, and $V$ be a balanced open set with $0\in V\subset U$ . Choose $t$ so that $E\subset tV$ , using the hypothesis. Then for any $s>t$ , we have:

E\subset tV=s{t \over s}V\subset sV\subset sU

$\square$

1 Corollary Every Cauchy sequence and every compact set in a TVS are bounded.
Proof: If the set is not bounded, it contains a sequence that is not Cauchy and does not have a convergent subsequence. $\square$

1 Lemma Let $f$ be a linear operator between TVSs. If $f(V)$ is bounded for some neighborhood $V$ of $0$ , then $f$ is continuous.
$\square$

6 Theorem Let $f$ be a linear functional on a TVS ${\mathcal {X}}$ .

(i) $f$ has either closed or dense kernel.
(ii) $f$ is continuous if and only if $\operatorname {ker} f$ is closed.

Proof: To show (i), suppose the kernel of $f$ is not closed. That means: there is a $y$ which is in the closure of $\operatorname {ker} f$ but $f(y)\neq 0$ . For any $x\in {\mathcal {X}}$ , $x-{f(x) \over f(y)}y$ is in the kernel of $f$ . This is to say, every element of ${\mathcal {X}}$ is a linear combination of $y$ and some other element in $\operatorname {ker}$ . Thus, $\operatorname {ker} f$ is dense. (ii) If $f$ is continuous, $\operatorname {ker} f=f^{-1}(\{0\})$ is closed. Conversely, suppose $\operatorname {ker} f$ is closed. Since $f$ is continuous when $f$ is identically zero, suppose there is a point $y$ with $f(y)=1$ . Then there is a balanced neighborhood $V$ of $0$ such that $y+V\subset (\operatorname {ker} f)^{c}$ . It then follows that $\sup _{V}|f|<1$ . Indeed, suppose $|f(x)|\geq 1$ . Then

y-{x \over f(x)}\in \operatorname {ker} (f)\cap (y+V)

if

x\in V

, which is a contradiction.

The continuity of $f$ now follows from the lemma. $\square$

6 Theorem Let ${\mathcal {X}}$ be a TVS and ${\mathcal {M}}\subset {\mathcal {X}}$ its subspace. Suppose:

{\mathcal {M}}

is dense

\Longleftrightarrow

z\in {\mathcal {X}}^{*}=0

in

{\mathcal {M}}

implies

z=0

in

{\mathcal {X}}

.

(Note this is the conclusion of Corollary 2.something) Then every continuous linear function $f$ on a subspace ${\mathcal {M}}$ of ${\mathcal {X}}$ extends to an element of ${\mathcal {X}}^{*}$ .
Proof: We essentially repeat the proof of Theorem 3.8. So, let ${\mathcal {M}}$ be the kernel of $f$ , which is closed, and we may assume ${\mathcal {M}}\neq {\mathcal {X}}$ . Thus, by hypothesis, we can find $g\in {\mathcal {X}}^{*}$ such that: $g=0$ in $M$ , but $g(p)\neq 0$ for some point $p$ outside $M$ . By Lemma 1.6, $g=\lambda f$ for some scalar $\lambda$ . Since both $f$ and $g$ do not vanish at $p$ , $\lambda ={g(p) \over f(p)}\neq 0$ . $\square$

Lemma Let $V_{0},V_{1},...$ be a sequence of subsets of a a linear space containing $0$ such that $V_{n+1}+V_{n+1}\subset V_{n}$ for every $n\geq 0$ . If $x\in V_{n_{1}}+...+V_{n_{k}}$ and $2^{-n_{1}}+...+2^{-n_{k}}\leq 2^{-m}$ , then $x\in V_{m}$ .
Proof: We shall prove the lemma by induction over $k$ . The basic case $k=1$ holds since $V_{n}\subset V_{n}+V_{n}$ for every $n$ . Thus, assume that the lemma has been proven until $k-1$ . First, suppose $n_{1},...,n_{k}$ are not all distinct. By permutation, we may then assume that $n_{1}=n_{2}$ . It then follows:

x\in V_{n_{1}}+V_{n_{2}}+...+V_{n_{k}}\subset V_{n_{2}-1}+...+V_{n_{k}}

and

2^{-n_{1}}+...2^{-n_{k}}=2^{-(n_{2}-1)}+...+2^{-n_{k}}\leq 2^{m}

.

The inductive hypothesis now gives: $x\in V_{m}$ . Next, suppose $n_{1},...,n_{k}$ are all distinct. Again by permutation, we may assume that $n_{1}<n_{2}<...n_{k}$ . Since no carry-over occurs then and $m<n_{1}$ , $m+1<n_{2}$ and so:

2^{-n_{2}}+...+2^{-n_{k}}\leq 2^{-(m+1)}

.

Hence, by inductive hypothesis, $x\in V_{n_{1}}+V_{m+1}\subset V_{m}$ . $\square$

1 Theorem Let ${\mathcal {X}}$ be a TVS.

(i) If ${\mathcal {X}}$ is Hausdorff and has a countable local base, ${\mathcal {X}}$ is metrizable with the metric $d$ such that

$d(x,y)=d(x+z,y+z)$ and $d(\lambda x,0)\leq d(x,0)$ for every $|\lambda |\leq 1$

(ii) For every neighborhood $V\subset {\mathcal {X}}$ of $0$ , there is a continuous function $g$ such that

$g(0)=0$ , $g=1$ on $V^{c}$ and $g(x+y)\leq g(x)+g(y)$ for any $x,y$ .

Proof: To show (ii), let $V_{0},V_{1},...$ be a sequence of neighborhoods of $0$ satisfying the condition in the lemma and $V=V_{0}$ . Define $g=1$ on $V^{c}$ and $g(x)=\inf\{2^{-n_{1}}+...+2^{-n_{k}};x\in V_{n_{1}}+...+V_{n_{k}}\}$ for every $x\in V$ . To show the triangular inequality, we may assume that $g(x)$ and $g(y)$ are both $<1$ , and thus suppose $x\in V_{n_{1}}+...+V_{n_{k}}$ and $y\in V_{m_{1}}+...+V_{m_{j}}$ . Then

x+y\in V_{n_{1}}+...+V_{n_{k}}+V_{m_{1}}+...+V_{m_{j}}

Thus, $g(x+y)\leq 2^{-n_{1}}+...+2^{-n_{k}}+2^{-m_{1}}+...+2^{-m_{j}}$ . Taking inf over all such $n_{1},...,n_{k}$ we obtain:

g(x+y)\leq g(x)+2^{-m_{1}}+...+2^{-m_{j}}

and do the same for the rest we conclude $g(x+y)\leq g(x)+g(y)$ . This proves (ii) since $g$ is continuous at $0$ and it is then continuous everywhere by the triangular inequality. Now, to show (i), choose a sequence of balanced sets $V_{0},V_{1},...$ that is a local base, satisfies the condition in the lemma and is such that $V_{0}={\mathcal {X}}$ . As above, define $f(x)=\inf\{2^{-n_{1}}+...+2^{-n_{k}};x\in V_{n_{1}}+...+V_{n_{k}}\}$ for each $x\in {\mathcal {X}}$ . For the same reason as before, the triangular inequality holds. Clearly, $f(0)=0$ . If $f(x)\leq 2^{-m}$ , then there are $n_{1},...,n_{k}$ such that $2^{-n_{1}}+...+2^{-n_{k}}\leq 2^{-m}$ and $x\in V_{n_{1}}+...+V_{n_{k}}$ . Thus, $x\in V_{m}$ by the lemma. In particular, if $f(x)\leq 2^{-m}$ for "every" $m$ , then $x=0$ since ${\mathcal {X}}$ is Hausdorff. Since $V_{n}$ are balanced, if $|\lambda |\leq 1$ ,

\lambda x\in V_{n_{1}}+...+V_{n_{k}}

for every

n_{1},...,n_{k}

with

x\in V_{n_{1}}+...+V_{n_{k}}

.

That means $f(\lambda x)\leq f(x)$ , and in particular $f(x)=f(-(-x))\leq f(-x)\leq f(x)$ . Defining $d(x,y)=f(x-y)$ will complete the proof of (i). In fact, the properties of $f$ we have collected shows the function $d$ is a metric with the desired properties. The lemma then shows that given any $m$ , $\{x;f(x)<\delta \}\subset V_{m}$ for some $\delta \leq 2^{m}$ . That is, the sets $\{x;f(x)<\delta \}$ over $\delta >0$ forms a local base for the original topology. $\square$

The second property of $d$ in (i) implies that open ball about the origin in terms of this $d$ is balanced, and when ${\mathcal {X}}$ has a countable local base consisting of convex sets it can be strengthened to: $d(\lambda x,y)\leq \lambda d(x,y)$ , which implies open balls about the origin are convex. Indeed, if $x,y\in V_{n_{1}}+...+V_{n_{k}}$ , and if $\lambda _{1}\geq 0$ and $\lambda _{2}\geq 0$ with $\lambda _{1}+\lambda _{2}$ , then

\lambda _{1}x+\lambda _{2}y\in V_{n_{1}}+...+V_{n_{k}}

since the sum of convex sets is again convex. This is to say,

f(\lambda _{1}x+\lambda _{2}y)\leq \min\{f(x),f(y)\}\leq {f(x)+f(y) \over 2}

and by iteration and continuity it can be shown that $f(\lambda x)\leq \lambda f(x)$ for every $|\lambda |\leq 1$ .

Corollary For every neighborhood $V$ of some point $x$ , there is a neighborhood of $x$ with ${\overline {W}}\subset V$
Proof: Since we may assume that $x=0$ , take $W=\{x;g(x)<2^{-1}\}$ . $\square$

Corollary If every finite set of a TVS ${\mathcal {X}}$ is closed, ${\mathcal {X}}$ is Hausdorff.
Proof: Let $x,y$ be given. By the preceding corollary we find an open set $V\subset {\overline {V}}\subset \{y\}^{c}$ containing $x$ . $\square$

A TVS with a local base consisting of convex sets is said to be locally convex. Since in this book we will never study non-Hausdorff locally convex spaces, we shall assume tacitly that every finite subset of every locally convex is closed, hence Hausdorff in view of Theorem something.

Lemma Let ${\mathcal {X}}$ be locally convex. The convex hull of a bounded set is bounded.

Given a sequence $p_{n}$ of semi-norms, define: