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nuuskur said:Assume for a contradiction [itex]\sigma (V,V')[/itex] is metrisable. The Banach space [itex]V'[/itex] is infinite dimensional. Since [itex]\sigma (V,V')[/itex] is a metrisable locally convex topology, its neighborhood basis of zero is generated by a sequence of seminorms [itex]p_{\varphi _n}[/itex], where [itex]\varphi _n\in V', n\in\mathbb N[/itex]. Wo.l.o.g this basis can be expressed as
[tex] S_{n} := \bigcap _{k=1}^n \varphi _k^{-1} (B(0,1)),\quad n\in\mathbb N.[/tex]
Take [itex]\varphi \in V'[/itex]. Fix [itex]\varepsilon >0[/itex]. Due to continuity w.r.t [itex]\sigma (V,V')[/itex] we have [itex]S_{N_\varepsilon} \subseteq \varphi ^{-1}(B(0,\varepsilon))[/itex] for some [itex]N_\varepsilon\in\mathbb N[/itex]. Put [itex]N := \min _\varepsilon N_\varepsilon[/itex]. Then [itex]x\in \bigcap _{k=1}^N \mathrm{Ker}\varphi _k[/itex] implies [itex]x\in \mathrm{Ker}\varphi[/itex]. Equivalently, [itex]\varphi \in \mathrm{span}(\varphi _1,\ldots, \varphi _N)[/itex]. Thus, [itex]V'[/itex] admits a countable spanning set, which is impossible. Therefore, [itex]\sigma (V,V')[/itex] cannot be metrisable.
This is what I got so far, but my expertise here is lacking to say the least, if you've any skills here please correct what I've got (or anybody really) as Topology is really new to me, thanks.fresh_42 said:Summary:: Functional Analysis, Topology, Differential Geometry, Analysis, Physics
Authors: Math_QED (MQ), Infrared (IR), Wrobel (WR), fresh_42 (FR).
9. Let ##(X,d)## be a compact metric space and ##f:X\to X## be a mapping onto. Assume that ##d(f(x),f(y))\le d(x,y),\quad \forall x,y\in X.## Show that ##d(f(x),f(y))= d(x,y),\quad \forall x,y\in X.## (WR)
sure it is continuous ,moreover it is Lipschitzbenorin said:ork: is continuous by Munkres' Topology Theorem 21.1, pg 129 which
It does work. I don't really understand your objection, though. Similarly, one could ask why you would work with the following if some other method is also sufficient. I think it's apples and oranges. I might be wrong.Math_QED said:I guess the idea is correct, but it is unclear to me why you work with the ##\epsilon## and the minimum? Doesn't the following work instead?
Let ##\varphi \in V^*##. Then there exists ##n## with ##S_n = \bigcap_{k=1}^n \varphi_k^{-1}(B(0,1)) \subseteq \varphi^{-1}(B(0,1))##. This implies that ##\bigcap_{k=1}^n \ker \varphi_k \subseteq \ker \varphi##: indeed if ##\varphi_k(x)=0## for ##k=1, \dots, n##, then also ##\varphi_k(tx)=0## for all ##t\in \Bbb{R}## and thus ##tx\in S_n\subseteq \varphi^{-1}(B(0,1))##, so that ##t\varphi(x) \in B(0,1)##. Since this holds for all ##t \in \Bbb{R}##, this forces ##\varphi(x)=0##. You then can conclude like you did.
I think it is non-trivial that you can choose the basis like you did: I agree that the topology ##\sigma(V,V')## is generated by the seminorms ##\{p_f: f \in V^*\}##. But then the following two questions remain:
(1) How does metrizability imply that you can choose ##(f_n)_n## such that the family of seminorms ##\{p_{f_n}: n \geq 1\}## still generate the topology? (Provide proof or a reference).
(2) Why can we choose the basis in this particular form: i.e. as inverse images of the unit ball?
12. Given a positive integer in decimal representation without zeros. We build a new integer by concatenation of the number of even digits, the number of odd digits, and the number of all digits (the sum of the former two). Then we proceed with that number.
Determine whether this algorithm always comes to a halt. What is or should be the criterion to stop?
I had a more formal argument in mind, but ok. I think you mistyped 013. Also I guess is a bit thin. And you could have actually answered the questions. However, these are only formal deficits.etotheipi said:I don't really know if this is what you're after, but for any given integer with 4 or more digits there will be either at least 2 even digits or at least 2 odd digits, and the next pass of the algorithm will always reduce the length of that string by at least one digit. You can just keep doing this until you get down to 3 digits, which are either
##\{\text{even}, \text{even}, \text{even}\} \implies 303 \implies 123##
##\{\text{even}, \text{even}, \text{odd}\} \implies 213 \implies 123##
##\{\text{even}, \text{odd}, \text{odd}\} \implies 123##
##\{\text{odd}, \text{odd}, \text{odd}\} \implies 013 \implies 123##
And I guess if you start off with an integer with 1 or 2 digits, the next pass gives you a 3 digit number and we're back to the above.
please provide detailsnuuskur said:Take a sequence of functions with norm in and with pairwise disjoint support. For instance, pick a sequence of pairwise disjoint intervals in and pick a function whose support is that interval. The linear span of this sequence is dense in : match the sequence with the canonical basis in .
wrobel said:I have already stuck at here:
please provide details
nuuskur said:By assumption is complemented in a dual Banach space.
wrobel said:ok
please explain the next step:
Alright, I'm recharged now.nuuskur said:Remark. Formally, the terminology is ".. is a complemented subspace of ..", but I'm used to saying " .. is complemented in ..".
Let a closed subspace [itex]K\subseteq X^*[/itex] be complemented in [itex]X^*[/itex]. In other words, there exist continuous maps [itex]\alpha : K \to X^*[/itex] and [itex]\beta : X^* \to K[/itex] such that [itex]\beta\circ \alpha = \mathrm{id}_{K}[/itex]. Denote [itex]j_X :X\to X^{**}[/itex] the canonical embedding, then we have a projection [itex]j_{K}\circ\beta\circ (j_X)^*\circ\alpha ^{**}[/itex] onto [itex]j_K(K)\cong K[/itex].
In which dual space c_0 is complemented? By which assumption?nuuskur said:By assumption is complemented in a dual Banach space.
The assumption is [itex]C[0,1][/itex] (which is separable) is isomorphic to a dual Banach space [itex]X^*[/itex]. By Sobczyk's theorem [itex]c_0[/itex] is complemented in [itex]X^* \cong C[0,1][/itex].wrobel said:In which dual space c_0 is complemented? By which assumption?