Is $L^p(\mathbb{R}) \setminus 0$ contractible? My intuition says that the answer is yes, but I'm afraid that this is based on thinking of this as somehow similar to a limit of $\mathbb{R}^n \setminus 0$ as n approaches $\infty$, which is of course nonsense. In any case, every contraction I've tried ends up making some function pass through $0$.
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Here is something really cheap and dirty. Let $p<+\infty$. Take $g=\frac{1}{1+x^2}$. Then $f(x,t)=e^{-(1+|x|)t/(1-t)}f(x)$ ($0\le t\le 1$) is a continuous contraction of Let's make it more interesting without making it more abstract. Can we find a uniformly continuous (both in space and time, as usual) contraction of the unit ball in $L^p$ without the center to a point? |
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Here is a simple proof for case of a Hilbert space $V$. Since $V$ minus the origin deformation retracts onto the unit sphere $S^\infty$, it suffices to show that $S^\infty$ is contractible, and that will follow if we can show that $S^\infty$ is a deformation retract of the unit disk. Below is a simple proof of that fact taken from my book "Critical Point Theory and Submanifold Geometry". (I have an old paper called "On the Homotopy Theory of Infinite Dimensional Manifolds" that proves much more general results of this nature. It appeared in vol.3 of Topology (1966).) Proposition. If $D^\infty$ is the closed unit disk in an infinite dimensional Hilbert space $V$, and $S^\infty=\partial D^\infty$ is the unit sphere in $V$, then there is a deformation retraction of $D^\infty$ onto $S^\infty$. Proof. Since $D^\infty$ is convex, it will suffice to show that there is a retraction of $D^\infty$ onto $S^\infty$. Now recall the standard proof of the Brouwer Fixed Point Theorem. If there were a fixed point free map $h:D^n\to D^n$ it would imply the existence of a deformation retraction $r$ of $D^n$ onto $S^{n-1}$; namely $r(x)$ is the point where the ray from $h(x)$ to $x$ meets $S^{n-1}$. If $n<\infty$ this would contradict the fact that $H_n(D^n,S^{n-1})=Z$, so there can be no such retraction and hence no such fix point free map. But when $n=\infty$ we will see that such a fixed point free map does exist, and hence so does the retraction $r$. This will be a consequence of two simple lemmas. Lemma 1. $D^\infty$ has a closed subspace homeomorphic to $R$. Proof Let ${e_n}$ be an orthonormal basis for $V$ indexed by $Z$, and define $F:R \to D^\infty$ by $F(t)=\cos({1\over2}(t-n)\pi)e_n +\sin({1\over2}(t-n)\pi)e_{n+1}$ for $n\le t \le n+1$. It is easily checked that $F$ is a homeomorphism of $R$ into $D^\infty$ with closed image. QED Lemma 2. If a normal space $X$ has a closed subspace $A$ homeomorphic to $R$ then it admits a fixed point free map $H:X\to X$. Proof. Since $A$ is homeomorphic to $R$ it admits a fixed point free map $h:A\to A$, corresponding to say translation by $1$ in $R$. Since $A$ is closed in $X$ and $X$ is normal, by the Tietze Extension Theorem $h$ can be extended to a continuous map $H:X\to A$, and we may regard $H$ as a map $H:X\to X$. If $x\in A$ then $x\not=h(x)=H(x)$, while if $x\in X\setminus A$ then, since $H(x)\in A$, again $H(x)\not=x$. QED |
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According to mathscinet, the results of Anderson given in "Topological properties of the Hilbert cube and the infinite product of open intervals" Trans. Amer. Math. Soc. 126 1967 200--216, and "Hilbert space is homeomorphic to the countable infinite product of lines" Bull. Amer. Math. Soc. 72 1966 515--519 show that all infinite dimensional separable Frechet spaces are homeomorphic, and that removing any countable union of compact sets from such a space leaves the homeomorphism type unchanged. |
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An infinite dimensional Banach space is homeomorphic to itself minus a point. Maybe R.D. Anderson or V. Klee proved this. |
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