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Edit: Here's a more down-to-earth, and somewhat weakened, but I believe still nontrivial, version of the main theorem.

Prototypical nonconvex spaces are $\ell^p$-spaces for $0<p<1$, say $\ell^p(\mathbb N)$ with norm $||(x_n)_n|| = \sum_n |x_n|^p$. This is in fact a projective object in the category of $p$-Banach spaces. However, it fails to be projective in the larger category of quasi-Banach spaces (by the Aoki--Rolewicz theorem, those are those complete topological vector spaces that admit a $q$-norm, i.e. are a $q$-Banach, for some $0<q\leq 1$), and in fact it has nontrivial self-extensions. However, Dustin Clausen and I proved that the smaller object $\ell^{p'}(\mathbb N)$ for $p'<p$ behaves like a projective object when tested against $p$-Banachs:

Theorem. Let $0<p'<p\leq 1$ and let $V$ be a $p$-Banach. Then, for the Yoneda-Ext groups in quasi-Banach spaces, $$ \mathrm{Ext}^i(\ell^{p'}(\mathbb N),V)=0$$ for all $i>0$.

The Yoneda-Ext group $\mathrm{Ext}^i$ classifies exact sequences with $i+2$ terms $$0\to V\to W_1\to\ldots\to W_i\to \ell^{p'}(\mathbb N)\to 0$$ where all $W_n$ are quasi-Banachs (but possibly only $q$-Banach for $q<p'$), up to a certain notion of equivalence. The case $i=1$ is a theorem of Kalton.

Nonconvexity means that many standard tools break down. The way Dustin Clausen and I overcame this problem here was to use the following simple

Proposition. Let $r=\tfrac 1{10^p}$ and let $C=\tfrac{10}{1-r}$. Then for all $x\in \mathbb R$, one has $$ |x|^p\leq \mathrm{inf}\{\sum_n |x_n| r^n\mid x_n\in \mathbb Z, \sum_n \tfrac{x_n}{10^n} = x\}\leq C|x|^p. $$

See Pavel's answer for a quick proof (for general $\tilde{r}=\tfrac 1{10}$).

What this proposition achieves is that it translates the nonconvex $|x|^p$ into the convex $|x_n|$ for discrete $x_n\in \mathbb Z$, at the various scales $10^{-n}$. Using this proposition, we were able to use convex geometry in a discretized setting to solve our problem.

Main Question: Are there any previous arguments of a similar sort, reducing a continuous nonconvex problem to a discrete convex problem on different scales?

Alternatively, I'd be very interested in a different approach to this theorem. (In the version we prove, we know even less about the nature of the intermediate $W_n$; so I'm not completely sure whether the whole complexity is preserved. However, a sanity check is that also for us, the $i=1$ case is significantly easier than $i>1$, and can be done by a direct attack.)

Below is the long, rambling, original question. I recommend reading the paragraph starting with "Say you want to travel from A to B" to get some intuition for what happens in the proposition.


Three months ago, I wrote the blog post Liquid Tensor Experiment, posing a challenge to verify a certain proof. The computer formalization is proceeding extremely well, I am really impressed by the efforts.

But this question is about the "human" part of that same proof: I think I still don't understand (or am just beginning to understand, with writing this question a key part of this) what is happening in our proof. I can roughly follow the proof line-by-line, but I don't have a real understanding for why it works, or am only slowly getting it. (I realize that this is an awkward thing to say about one's own proof. There's a reason I want a verification...)

Let me state the theorem in question. There are three inputs:

  1. The category of condensed abelian groups --- a version of topological abelian groups, but forming an abelian category --- in which this computation takes place. For an introduction to this, see the blog post. For the kind of "big picture" question I want to ask, it is however not very relevant.

  2. A $p$-Banach space $V$, for some $0<p\leq 1$. Recall that this is a complete normed real vector space $(V,||\cdot||)$ where the norm satisfies the usual triangle inequality, but the scaling behaviour $||ax||=|a|^p ||x||$ for $a\in \mathbb R$, $x\in V$. In particular, for $p<1$, these may be non-locally convex. A prototypical example are $\ell^p$-spaces; say $\ell^p(\mathbb N)$ with norm $||(x_n)_n|| = \sum_n |x_n|^p$.

  3. The space $\mathcal M_p(S)$ of $p$-measures on some profinite set $S$, where again $0<p\leq 1$. If $p=1$, this is the usual space of (signed Radon) measures on $S$, which we equip with the compactly generated weak-$\ast$-topology. In other words, $\mathcal M_1(S)$ is a rising union (with the colimit topology) of compact Hausdorff spaces $\mathcal M_1(S)_{\leq c}$ for $c\in \mathbb R_{\geq 0}$. Here, for finite $S$, one has $\mathcal M_p(S)=\mathbb R[S]$ the free $\mathbb R$-vector space on $S$ with the $\leq c$-subspace given by $\{(x_s)_{s\in S}\mid \sum_{s\in S} |x_s|\leq c\}$, and in general for a profinite $S=\varprojlim_i S_i$, one sets $$\mathcal M_1(S)_{\leq c} = \varprojlim_i \mathcal M_1(S_i)_{\leq c}.$$ For general $p$, one does the very same thing, replacing the $\ell^1$-norm with the $\ell^p$-norm. In other words, for finite sets $S$ we still have $\mathcal M_p(S)=\mathbb R[S]$, but the $\leq c$-subspace is given by $\{(x_s)_s\mid \sum_{s\in S} |x_s|^p\leq c\}$, then for profinite $S=\varprojlim_i S_i$ one takes $$\mathcal M_p(S)_{\leq c} = \varprojlim_i \mathcal M_p(S_i)_{\leq c}$$ and finally $\mathcal M_p(S)$ is the rising union of the $\mathcal M_p(S)_{\leq c}$. Just like one can define a space of signed Radon measures on any compact Hausdorff space $S$, the same is actually also true for the space of $p$-measures on $S$; one way to define it is to write $S=\tilde{S}/R$ as a quotient of a profinite set $S$ by a closed equivalence relation $R$, and then set $\mathcal M_p(S)=\mathcal M_p(\tilde{S})/\mathcal M_p(R)$. I do not really have a good direct definition of it. Also, for $p<1$, any element of $\mathcal M_p(S)$ is actually just a countable sum of Dirac measures, with $p$-summable coefficients; but the topology is more subtle.

Preliminary Question. What is some previous literature on this space of $p$-measures?

Now one can show that if $V$ is any $p$-Banach space, and $f: S\to V$ is any continuous map, then it extends uniquely to a map $\mathcal M_p(S)\to V$ of topological real vector spaces (which reduces to $f$ on Dirac measures). What we originally hoped for, for $p=1$ in fact, is that this uniqueness is true even "in the higher sense"; more precisely:

Is $\mathrm{Ext}^i(\mathcal M_p(S),V)=0$ for $i>0$?

It turns out that this is false: One can show that there are explicit $\mathrm{Ext}^1$-classes, first constructed by Ribe, coming from the entropy function. (I hadn't expected to run into the entropy functional any day soon...) In a first try, we then passed to measures of "bounded entropy", on which these extensions split; but they acquire new extensions of their own, leading to infinite regress. So one needs to replace $\mathcal M_p(S)$ by some space of measures distinctly smaller than $\mathcal M_p(S)$; for example $\mathcal M_{p'}(S)$ for $p'<p$.

This led Clausen and myself to conjecture, and eventually prove, the following theorem (which is the one for which I want a computer verification):

Theorem. If $0<p'<p\leq 1$ and $V$ is a $p$-Banach space, then $\mathrm{Ext}^i(\mathcal M_{p'}(S),V)=0$ for $i>0$.

This theorem is the basis for the "$p$-liquid analytic ring structure" on the reals; I refer you again to the blogpost for some discussion about this.

Basically, the intuition here is that if you have a $p'$-measure $\mu$, then you can split it into $N$ summands that are either Dirac measures, or are of $p'$-norm roughly $\tfrac 1N$ of the $p'$-norm of the original sequence; mapping to $V$, we know where the Dirac measures go, and the other terms have very small image in $V$, as the norm scales differently on $V$. Any such decomposition of $\mu$ can be thought of as a path connecting a given measure to Dirac measures. To see that higher Ext-groups vanish, one needs to see that for any two such paths, there is some homotopy connecting them, also being sufficiently small; and higher homotopies between those.

Unfortunately, this seems to be a bit tricky, as in a nonconvex shape, it is hard to find enough free room to move around: You cannot simply take the average of two maps if you want to keep track of bounds. So roughly, any such decomposition is like some valley in a function you would like to minimize, but now you have to connect different valleys without climbing too high; that's tricky.

The way we (inadvertently -- see the following comments) solved this issue is by passing to a discretization of the problem, where the discretized problem is convex. (Our original motivation for the discretization was in some sense of a purely technical sort, having to do with the nature of the category of condensed abelian groups; this motivation is explained in the blog post. Only recently, when in the formalization process a significant amount of convex geometry has to be formalized, did I realize that we're using convex geometry in a critical way, and that this is a much more profound reason for the discretization.)

More precisely, for some fixed radius $r$ with $0<r<1$, or let's in fact say $\tfrac 1{10}<r<1$, we consider the ring

$$\mathbb Z((T))_r = \{\sum a_n T^n\mid \sum |a_n| r^n<\infty\}$$

of arithmetic Laurent series with a certain convergence condition; in particular such sums converge for $0<|T|<r$. In particular, we can evaluate at $T=\tfrac 1{10}$ and get a surjection

$$\mathbb Z((T))_r\to \mathbb R: \sum a_n T^n\mapsto \sum \frac{a_n}{10^n}$$

in some sense recording decimal expansions of real numbers. The map is surjective, and the kernel is generated by $10T-1$.

Now for finite sets $S$, we can again endow the free module $\mathcal M(S,\mathbb Z((T))_r)=\mathbb Z((T))_r[S]$ with a "norm", by looking at the subspaces

$$\mathcal M(S,\mathbb Z((T))_r)_{\leq c} = \{\sum_{n,s} a_{n,s} T^n [s]\mid \sum_{n,s} |a_{n,s}| r^n\leq c\}.$$

In other words, we use the usual (convex) absolute value on $\mathbb Z$, and set $|T|=r$. This is naturally a (totally disconnected) compact Hausdorff space. Again, for profinite $S$ we can pass to the limit, and then get the space of measures

$$\mathcal M(S,\mathbb Z((T))_r) = \bigcup_c \mathcal M(S,\mathbb Z((T))_r)_{\leq c}$$

for general profinite sets $S$. (Again, one can also build a version for general compact Hausdorff $S$, passing to quotients.)

The key observation is the following (see Theorem 6.9 (2), Proposition 7.2 here):

Proposition. There is a canonical isomorphism $$\mathcal M(S,\mathbb Z((T))_r)/(10T-1)\cong \mathcal M_{p'}(S,\mathbb R),$$ where $0<p'<1$ is chosen so that $r=10^{-p'}$.

(More precisely, a unique functorial one compatible with Dirac measures.)

The key is that the left-hand side is convex but discretized, while the right-hand side is non-convex. To understand what is happening here, let me make an analogy:

Say you want to travel from A to B. The convex solution is to just take your car: The cost (as say measured in time) scales pretty much linearly in the distance, and you will simply take the shortest route. If you look at the region you can reach in a given time, you get some convex region -- essentially a circle. The nonconvex solution is to first walk to the bus station, then take the bus to the train station, then take the train to the airport, then fly, and finally reverse those steps. The set of points you can reach via this method in a given time is highly nonconvex. So you are taking steps of widely different scales (in the math: the different powers $T^n$ of $T$), but their cost (as measured in time, in the math: $|T^n|=r^n$) is not proportional to the scale ($T^n\mapsto 10^{-n}\in \mathbb R$). On the other hand, within each scale you would again take the shortest route. Each scale itself is discretized (most evidently in case of bus stations, train stations and airports).

So what we ended up doing is to prove the analogue of the desired theorem over $\mathbb Z((T))_r$ instead, see Theorem 9.1 here. It's a bit hard to summarize the argument and I don't have a clear sense of what's the key argument, but I currently believe it is precisely this reduction of a nonconvex problem to discrete convex problems on different scales. Now this kind of stuff is way out of my area of expertise, so I very naively wonder whether this is in fact a well-known technique, leading me to my

Main Question: Is the reduction of a nonconvex problem to a discrete convex problem (e.g. via using different scales) a well-known technique?

My traveling analogy makes me think the answer must evidently be "Yes", but I'd be happy to see some references. I'd be especially interested if there are any previous instances where questions on real functional analysis have been proved via passage to an arithmetic ring like $\mathbb Z((T))_r$, but all answers or pointers are most welcome.

Edit: Thanks for the comments so far! My naive googling about multiscale methods or so mostly lead me to very applied things. This is not bad, but I just wanted to remark that the method we use seems to be mostly of theoretical value -- a back-of-the-envelope calculation suggests that in our proof, under this analogy, the number of bus stations, train stations, and airports has to be roughly doubly exponential in some natural parameters that occur ;-). Now I believe there's also a lot of pure work using multiscale arguments, I just don't really know where to start looking.

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    $\begingroup$ The idea of using multiple scales to (numerically) solve a problem shows up in PDEs, where it is known as a "multigrid method". I'm don't know of an example where you start with a non-convex problem and then the discretizations become convex, so I can't give an example for your main question. However, there seems to be the same issue of searching for extrema in large and complicated space, and discretizing at different scales can help in this setting as well. $\endgroup$
    – Gabe K
    Mar 18, 2021 at 2:28
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    $\begingroup$ I don't know enough to comment directly on the mathematics, but both multiscale methods and efficient exploitation of convexity are very much part of the armory of "modern" harmonic analysts. I am reluctant to single out particular names for fear of miscrediting or "offending by omission" but I always think of this line of maths as inspired by work on the Kakeya problem and Stein's restriction conjecture $\endgroup$
    – Yemon Choi
    Mar 19, 2021 at 11:37
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    $\begingroup$ I'm surprised Terry Tao hasn't posted a definitive answer yet, I feel like he would be the perfect person to address you question... $\endgroup$ Mar 19, 2021 at 20:29
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    $\begingroup$ @SamHopkins: New rule: only one Fields medalists per post! (-: $\endgroup$ Mar 19, 2021 at 21:28
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    $\begingroup$ @HailongDao: Seems that the new rule didn't last too long... :-) $\endgroup$ Mar 22, 2021 at 19:12

3 Answers 3

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I was asked to answer this question. The people one really needs to ask here are the people in high-dimensional convex geometry/probability/statistics/computer science and metric geometry, but in any event, there are a couple things that the discussion in the post reminded me of:

  • Half-densities, which are basically formal square roots of densities (measures) that can be defined in a coordinate-free fashion, and are somewhat reminiscent of the space ${\mathcal M}_2(S)$ in the post (they are to $L^2(S)$ as ${\mathcal M}_1(S)$ is to $L^1(S)$). They play a role in geometric quantisation and the theory of Fourier integral operators. In principle one could take other fractional powers of densities to recover all of the ${\mathcal M}_p$ spaces, but the $p=1,2$ cases are the only ones that seem to be really useful in applications so far.

  • Chaining. This is a technique in which a metric space $(X,d)$ is analysed by considering, for each dyadic scale $2^{-n}$ (or $10^{-n}$, if you prefer), a $2^{-n}$-net ${\mathcal F}_n$, that is to say a maximal $2^{-n}$-separated subset of $X$ (in many applications $X$ will be totally bounded and so such nets will be finite). One can then approximate the distance between two points of the set by hopping through such nets. For instance if $F: X \to V$ is a continuous function taking values in a normed vector space and $X$ has diameter at most $1$ (say) then one can verify the bound $$ \sup_{x,y \in X} \|F(x)-F(y)\| \leq 2 \sum_{n=0}^\infty \sup_{a \in {\mathcal F}_n, b \in {\mathcal F}_{n+1}, d(a,b) \leq 2^{-n}} \|F(a)-F(b)\|$$ and the proof is basically applying your route-finding algorithm followed by the triangle inequality. This sort of estimate is particularly useful in probability theory to bound the suprema of random processes on a metric space; the basic incarnation of this is Dudley's inequality, and a powerful extension of this is Talagrand's generic chaining method (see, e.g., Section 2.5 of these lecture notes of van Handel).

  • Covering numbers of $\ell^p$ balls. There is an extensive literature on questions like how many $\ell^q$-balls of radius $\varepsilon$ are needed to cover the $\ell^p$ ball of radius one, which directly leads to bounding the size of the nets used in chaining arguments. Both the convex and non-convex cases have been considered, and one can often get decent bounds by using a discretisation strategy (though there are also more advanced tools available, such as the dual Sudakov inequality). Estimates on such covering numbers are used extensively in high dimensional statistics. Unfortunately I don't have a good introductory reference to this topic, but perhaps other readers can supply one.

  • Ultrametric skeletons. It turns out that under very general conditions, a metric space $(X,d)$ will contain a large subspace $X'$ (which often resembles a Cantor set with a tree-like structure) on which the metric is equivalent to an ultrametric; such "ultrametric skeletons" can be viewed as an efficient discretisation of the original space, and are useful in theoretical computer science. One drawback though is that one only gets this nice structure on the smaller space $X'$ and not on the original space $X$.

  • Major subsets. If one works with the weak $\ell^p$ norms $\| \|_{\ell^{p,\infty}(S)}$ instead of strong norms, then there is a nice partially convex description of such norms (up to constants) even when $0 < p < 1$: $$ \|f\|_{\ell^{p,\infty}(S)} \sim_p \sup_{E \subset S, 0 < |E| < \infty} \inf_{E' \subset E, |E'| \geq \frac{1}{2} |E|} |E|^{-1/p'} |\langle f, 1_{E'} \rangle|.$$ In other words, $f$ is bounded in $\ell^{p,\infty}$ if and only if, for any non-empty finite set $E$, there is a major subset $E'$ of $E$ - i.e., a subset of $E$ of at least half the cardinality - such that $\langle f, 1_{E'} \rangle = O( |E|^{1/p'} )$; see for instance Lemma 2.5 of Muscalu-Schlag. Here of course $p'$ is the dual exponent to $p$, $1/p+1/p'=1$. When $p > 1$ (so that $1/p'$ is positive) the passage to the major subset is not needed and one can just take $E'=E$, making the right-hand side completely convex. But for $p \leq 1$ the need to remove an exceptional minor subset is needed (consider for instance the basic example $S = {\bf N}$, $f(n) = n^{-1/p}$). This characterisation of weak $\ell^p$ interacts very well with Calderon-Zygmund theory (in which one is always discarding various small exceptional sets) and also with real interpolation methods which can often upgrade weak $\ell^p$ estimates to strong $\ell^p$ estimates (at the cost of modifying $p$ slightly).

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    $\begingroup$ Terry, are you sure it wasn't the 100-point bounty? (-: $\endgroup$ Mar 22, 2021 at 18:49
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    $\begingroup$ Thanks a lot! I need to read up more about those, but at least on first sight, they all seem a little different, with probably Dudley's inequality coming the closest; but I'm still missing this key feeling of this reduction of continuous nonconvexity to discrete convexity (paradoxical as it may seem). I wished I was able to articulate more clearly what our theorem on vanishing of Ext-groups is about so that somebody who actually understands the real numbers can have a shot at trying to prove it, hopefully connecting it to more standard mathematics... $\endgroup$ Mar 22, 2021 at 20:45
  • $\begingroup$ Is the ultrametric skeleton related to the following construction: the Stone space associated to the Boolean algebra of the clopen subsets of a topological space? This is related to "non-archimedean Gelfand transform". $\endgroup$
    – Z. M
    Apr 5, 2021 at 18:57
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I will start with a reformulation of the Proposition in the question in terms that are easier to digest for analysts.

Proposition: let $0<\tilde{r}<r<1$ and $0<p<1$ be such that $\tilde{r}^{p}=r$. Then, for any $a\in\mathbb{R}$, we have $$ |a|^{p} \leq \inf \{ \sum_{n\in\mathbb{Z}} |a_{n}| r^{n} : a_{n}\in\mathbb{Z}, a=\sum_{n\in\mathbb{Z}} a_{n} \tilde{r}^{n} \text{ converges absolutely} \} \leq \frac{1+1/\tilde{r}}{1-r} |a|^{p}. $$ Proof: First inequality: If $a_{n}$ are as described on the RHS, then, by (reverse) Minkowski's inequlaity, we have $$ |\sum_{n\in\mathbb{Z}} a_{n} \tilde{r}^{n}|^{p} \leq \sum_{n\in\mathbb{Z}} |a_{n} \tilde{r}^{n}|^{p} = \sum_{n\in\mathbb{Z}} |a_{n}|^{p} r^{n} \leq \sum_{n\in\mathbb{Z}} |a_{n}| r^{n}. $$ Second inequality: Let $N_{0}\in\mathbb{Z}$ be the smallest integer such that $|a| \geq \tilde{r}^{N_{0}}$. Choose $a_{n}$ for $n\geq N_{0}$ in ascending order. Given $a_{N_{0}},\dotsc,a_{N-1}$, choose $a_{N}\in\mathbb{Z}$ such that $$ |\sum_{n=N_{0}}^{N} a_{n} \tilde{r}^{n} - a| < \tilde{r}^{N}. $$

By the choice of $a_{n}$'s, it follows that $|a_{N} \tilde{r}^{N}| \leq \tilde{r}^{N-1} + \tilde{r}^{N}$, which implies $|a_{N}| \leq 1+1/\tilde{r}$ for all $N$ (more careful choice would give $|a_{N}| \leq 1/\tilde{r}$). For this choice of $a_{n}$'s, we obtain $$ \sum_{n\in\mathbb{Z}} |a_{n}| r^{n} \leq (1+1/\tilde{r}) \sum_{n\geq N_{0}} r^{n} = (1+1/\tilde{r}) \frac{r^{N_{0}}}{1-r} = \frac{1+1/\tilde{r}}{1-r} (\tilde{r}^{N_{0}})^{p} \leq \frac{1+1/\tilde{r}}{1-r} |a|^{p}. $$

This feels very similar to Rademacher-Menshov type arguments, in which maximal estimates are reduced to square function estimates. I can recommend Section 3 in Allison Lewko and Mark Lewko, Estimates for the Square Variation of Partial Sums of Fourier Series and their Rearrangements (JFA 262 (2012) doi:10.1016/j.jfa.2011.12.007, arXiv:1106.0871) as an example of such argument.

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Update: I just noticed that in the comment section, a similar approach in non-convex optimization has been mentioned and Peter has responded. So this answer may not be relevant.

The following comment may seem too far-fetched, but I'm writing it for whatever it's worth. I cannot post a comment as a guest, so I'll post it as an answer.

In the field of Polynomial Optimization (whose goal is to find the global optimum of a real polynomial subject to some polynomial constraints), the moment-SOS approach solves such a problem (which is a continuous non-convex problem) by solving a sequence of SDPs (semidefinite programming problems, which are convex) of different, increasing scale. The SDPs are continuous convex problems, but like LPs (linear programming problems), one might argue that SDP can be viewed as some kind of combinatorial/discrete problem. For example, one of the optimal solutions of SDP must be an extreme point of the feasible domain and simplex-like methods can be used to solve SDPs (although interior point methods are usually more efficient). The moment-SOS approach relies on Putinar’s Positivstellensatz (which roughly says that if a polynomial is positive on a semi-algebraic set then some sum of squares (SOS) formula must hold) and the fact that testing the existence of SOS formula (with bounded degree) is equivalent to solving some SDP. In this approach the degree (of SOS polynomials) is the scale parameter. A quick introduction is https://www.princeton.edu/~aaa/Public/Presentations/CDC_2016_Lasserre

Very very roughly, I think this fits the pattern of reducing a non-convex continuous problem to a discrete convex problem (via using different scales), although it might not be the kind of technique you are looking for.

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