A question on unit norm elements of $\ell^2 \setminus \bigcup_{0<p<2 }\ell^p$

Question

Let $A\subset \ell^2$ consist of all $x\in \ell^2$ with $|x|_2=1$ which does not belong to any $\ell^p$ for all $0<p<2$.

Note that $A$ is non-empty with a Baire category argument.

I am interested in (somewhat) distribution and configuration of $A$ and its complement in the unit sphere $S$ of $\ell^2$.

Note that $S\setminus A$ is path connected.

Is $S\setminus A$ a contractible space?

What can be said about connected components of $A$? In particular can one find at least one non constant curve?

Note: I was thinking to a possible density of $A$ in the sphere, or to a possible measure of $A$ as a subset of sphere. Note that density of a subset $A$ at a point $p$ of a metric space with measure $\mu$ is the limit $\frac{\mu(A\cap B_\epsilon)}{\mu (B_{\epsilon})}$ as $\epsilon$ goes to 0. ($B_\epsilon$ is the ball around $p$).

But I realized that the measure theory on infinite Banach spaces is a technical matter:

What is known about the Gaussian measure of the unit ball in a Hilbert Space?

What is the 'right' definition of zero measure subsets of Banach spaces?

Invariant probability on a unit ball of a Banach space

https://math.stackexchange.com/questions/75932/measure-on-hilbert-space

Answer 1

Umm, $A$ is path-connected and it is fairly simple -- just change the coordinates one by one. Say we want to go from $u\in A$ to $v\in A$. On $[0, \frac{1}{2}]$ change linearly $u_1$ to $v_1$, then on $[\frac{1}{2}, \frac{2}{3}]$ change linearly $u_2$ to $v_2$ and so on. The only slight issue is that we are leaving the sphere, but just consider $v(t) = u(t)/||u(t)||$, then $v(0) = u, v(1) = v$, and $v(t)\notin \ell^p$ for all $0 < p < 2$ and all $0\le t < 1$ since $v(t)$ is equal to $u$ up to finitely many coordinates and a multiplication by a constant, and $u\notin \ell^p$ for all $0 < p < 2$, and for $t = 1$ we have $v(t) = v\notin \ell^p, 0 < p < 2$ as well.

The only thing that is a tiny bit not obvious is continuity of $v(t)$ at $t = 1$, but this follows since for any vector $w\in \ell^2$ and any $\epsilon > 0$ there exists $N(w, \epsilon)$ such that $\sum_{n > N} |w_n|^2 < \epsilon$.

Answer 2

For the first question, yes, $S \setminus A$ is contractible. Rewrite the standard basis so that it is indexed by $\mathbb{Z}$. Let $U$ be the bilateral shift. Then $U$ is an isomorphism on $\ell^p$ for any $0 < p \leq 2$. Recall, from this paper, that $\varphi(x) = \frac{1}{2}(1 - \|x\|)e_0 + U(x)$ is a homeomorphism from the unit ball of $\ell^2$ onto itself without fixed point. From the geometric description of $\varphi$, contained in the proof of Theorem 1 of the cited paper, and using the facts that $e_0 \in \ell^p$ and $U$ is an isomorphism of $\ell^p$ for all $0 < p < 2$, it is not hard to see that $\varphi$ restricts to a homeomorphism from the unit ball of $\bigcup_{0 < p < 2} \ell^p$ (under the $\ell^2$ norm) to itself. Then $\psi$, which sends $x$ to the point at which the ray from $\varphi(x)$ to $x$ meets the unit sphere, is a retraction from the unit ball of $\bigcup_{0 < p < 2} \ell^p$ onto the unit sphere of $\bigcup_{0 < p < 2} \ell^p$ (i.e., $S \setminus A$). Thus, $S \setminus A$ is contractible, as $\Phi(x, t) = \psi(tx)$ is a homotopy between a constant map and the identity map on $S \setminus A$.

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On second thought, I decided to still write down my approach to proving $A$ is path-connected despite Aleksei's wonderful (and simpler) answer, to ensure there is one complete answer.

For any $x \in A$, denote $x_e$ to be the part of $x$ supported on even indices and $x_o$ to be the part of $x$ supported on odd indices. Let $x, y \in A$. We first show that there is a path from $x$ to $x'$ in $A$, and from $y$ to $y'$ in $A$, s.t. $x'$ and $y'$ have disjoint supports.

Since $x \notin \bigcup_{0 < p < 2} \ell^p$, we must have at least one of $x_e$ and $x_o$ is not in $\bigcup_{0 < p < 2} \ell^p$ either. The same holds for $y$. If $x_e \notin \bigcup_{0 < p < 2} \ell^p$ and $y_o \notin \bigcup_{0 < p < 2} \ell^p$, then simply let $x' = \frac{x_e}{\|x_e\|}$. Now define,

$$f(t)_n = \begin{cases} x_n &, \text{ if }n\text{ is even}\\ (1 - t)x_n &, \text{ if }n\text{ is odd} \end{cases}$$

$$g(t) = \frac{f(t)}{\|f(t)\|}$$

It is then easy to verify that $g$ is a path from $x$ to $x'$ in $A$. Similarly, there is a path from $y$ to $y' = \frac{y_o}{\|y_o\|}$ in $A$. Clearly, $x'$ and $y'$ have disjoint supports. Similar arguments also apply when $x_o \notin \bigcup_{0 < p < 2} \ell^p$ and $y_e \notin \bigcup_{0 < p < 2} \ell^p$.

Now, consider when $x_o \notin \bigcup_{0 < p < 2} \ell^p$ and $y_o \notin \bigcup_{0 < p < 2} \ell^p$. The point here is we can first rotate $x$ to $x''$ s.t. $(x'')_e \notin \bigcup_{0 < p < 2} \ell^p$, then apply the result of the previous paragraph. This can be easily achieved by,

$$f(t)_n = \begin{cases} \cos(\frac{\pi}{2}t)x_n + \sin(\frac{\pi}{2}t)x_{n+1} &, \text{ if }n\text{ is odd}\\ -\sin(\frac{\pi}{2}t)x_{n-1} + \cos(\frac{\pi}{2}t)x_n &, \text{ if }n\text{ is even} \end{cases}$$

Then set $x'' = f(1)$. Since $(x'')_e$ is simply $x_o$ shifted one index forward, we have $(x'')_e \notin \bigcup_{0 < p < 2} \ell^p$. $f(t)$ is simply rotation in each pair of adjacent coordinates, so it preserves the $\ell^2$ norm. Any rotation matrix is also both bounded below and above under $\ell^p$ norm for any $0 < p < 2$, so as $x \notin \bigcup_{0 < p < 2} \ell^p$, $f(t) \notin \bigcup_{0 < p < 2} \ell^p$ either for any $t$. Thus, $f(t)$ is indeed a path in $A$. Now apply the result in the previous paragraph to reach the desired conclusion. The case where $x_e \notin \bigcup_{0 < p < 2} \ell^p$ and $y_e \notin \bigcup_{0 < p < 2} \ell^p$ can be proved similarly.

Now, it suffices to show that for $x, y \in A$ with disjoint supports, they can be connected by a path. Such a path is simply given by,

$$f(t) = \frac{tx + (1 - t)y}{\|tx + (1 - t)y\|}$$