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This is a very abstract question, I hope this is appropriate.
Suppose $T$ is some claim over some infinite set $A$, for example, let $A$ be the set of all loopless planar graphs, and $T$ be the claim "for every element $a \in A$, the chromatic number of $a$'s dual graph is $\leq 4$" (this is known as "Four-color Theorem"); or, let $A = \mathbb{N}$, and $T$ be the claim "there are no 3 elements $x, y, z \in A$ such that $x^5 + y^5 =z^5$" (a specific case of Fermat's last theorem).
In the first example, it is possible to prove the claim $T$ by testing some claim $T'$ over finite set $A' \subset A$, see proof by computer section. This is done by a series of reductions, showing that if all the elements in some finite set satisfy a property, then the (original) claim holds.
In some sense, mathematical induction is similar: we test a claim on finite set ("the base case"), then proving $a_n \rightarrow a_{n+1}$, which shows the claim is correct for all space.

Are there more known cases like that? i.e. proving (a combinatorial) claim by reduction to finite cases?

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    $\begingroup$ I think that this is a very interesting question, but I think it doesn't fit the MO mission of focussed questions with a definite answer. MO has some tolerance for big-list questions, so maybe it would be appropriate if made community wiki. (You can do this by flagging your own post for moderator attention, if you agree.) $\endgroup$
    – LSpice
    Commented Sep 13, 2019 at 15:22
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    $\begingroup$ There are certainly a lot of proofs which are vaguely similar to the Four Colour Theorem; search for 'discharging method' which is a (the most common but certainly not the only) way to reduce a general graph problem to a finite set of cases to check. For a rather different example, in some sense Helfgott's proof of the weak Goldbach conjecture is of this form: he reduces the problem to checking finitely many cases and then does the check. I think this is an example of what you don't want to see (because without the finite check Helfgott still proves something; that's not true for 4CT). $\endgroup$
    – user36212
    Commented Sep 13, 2019 at 15:44
  • $\begingroup$ Since I am no expert I leave this as a comment rather than an answer. The proof of the Poincare conjecture comes to mind which -as described here (see the section: Transparencies), is based on reduction of different manifolds to a finite set of well-defined ones. $\endgroup$
    – polfosol
    Commented Sep 14, 2019 at 16:03

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Doron Zeilberger has beat the drum rather enthusiastically for this style of argument; see for example his paper The C-finite Ansatz. M. D. Hirschhorn has a paper entitled A Proof in the Spirit of Zeilberger of an Amazing Identity of Ramanujan in which he says,

In this paper I show that in order to prove Ramanujan's statement it is sufficient to check just the first seven cases, and then I do so.

More controversially, Zeilberger goes further and champions the notion of a "semi-rigorous proof," saying that even if we don't have a fully rigorous proof that the finitely many cases we have checked imply the general case, often the finitely many cases are "good enough." However, even if you don't agree with Zeilberger's attitude toward semi-rigorous proofs, he and his collaborators have many examples of fully rigorous proofs of the type you are looking for.

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    $\begingroup$ In some sense, Zeilberger either always proves statements by reduction to finite sets (depending on your interpretation) because he is an ultrafinitist and, in particular, he firmly rejects the very notion of infinity. For instance, see this opinion piece. $\endgroup$
    – ferrari
    Commented Sep 14, 2019 at 3:59
  • $\begingroup$ @ferrari, I don't mean to pick on a typo, but I wonder if I'm missing something. Is the word 'either' really intended in the sentence "… Zeilberger either always proves statements by reduction to finite sets …"? $\endgroup$
    – LSpice
    Commented Sep 23, 2019 at 16:29
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    $\begingroup$ @LSpice, you're right; I was going to write that he either always does or never does depending on your interpretation. He rejects the notion of infinity, so your initial set of interest would be finite anyways from his point of view... $\endgroup$
    – ferrari
    Commented Feb 29, 2020 at 2:04
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The 15 and 290 theorems are of this form. For example, the 15 theorem says that if a positive definite quadratic form with integer matrix represents all positive integers up to 15, then it represents all positive integers.

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It is very common, when finding solutions to Diophantine equations, to use Baker's method of linear forms in logarithms to reduce the problem to a finite computation (that is, to find an upper bound for the solutions).

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For the sake of completeness, let me mention the direction which is opposite to the OP's Question.

There are combinatorial optimizations problems which deal with a finite (but large) input set at the start, and the point is to optimize a real function over the input. Such problems are often messy.

Then, some time ago, Hungarian mathematicians started to embed the input set into a Euclidean n-space, and they'd extend the said function to a linear or convex function over the convex hull of the input. Since the optimum over the whole hull is reached at a vertex then... etc.

We see that sometimes situations which are strictly finite (looking for an exact answer) get hm-reduced to infinite situations.

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In 1972, I have developed a general theory of isometric embeddings of finite metric spaces into finite-dimensional Banach spaces, in particular, the injective case, i.e. into metrically injective spaces $\mathbb R^n$ with metrics given by $\max$. An announcement has appeared a couple of years later in AMS Notices. One of the theorems fits the present thread:

For every natural $k\ n$, there is an EXPLICIT natural constant $\mu(k\ n)$ such that the following two statements are equivalent:

(i) every $k$-element metric space can be isometrically embedded into $\mathbb R^n$ with the distance given by $\max$;

(ii) every $k$-element metric space with integer distances and of diameter ${\leq} \mu(k\ n)$ can be isometrically embedded into subspace $\{0\ \ldots\ \mu(k, n)\}^n$ of $\mathbb R^n$ with the distance given by $\max$.

For each natural $\ n,\ $ there exists a maximal $\ u(n)=k\ $ as above; and also $\ U(n)\ $ similar to $\ u(n)\ $ but for ALL $n$-dimensional Banach spaces TOGETHER (for each fixed dimension $\ n).\ $ Then in the non-trivial case of $\ n \geq 2\ $ we get

$$ n+2 \leq u(n) \leq U(n) \leq \left\lceil\frac{3\cdot n}2\right\rceil + 1 $$

We see from (i)+(ii) that finding $u(n)$ has been reduced to a finite computation.

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    $\begingroup$ I notice all the extra spaces around the mathematical symbols, and I find them distracting. $\endgroup$
    – user44143
    Commented Sep 14, 2019 at 21:24
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    $\begingroup$ Actually the lower bound $n+2$ may be replaced by $n+C$ for any constant $C$ and large enough $n$, see our paper with Stolyarov abd Zatitskiy in Mathematika 56 (1), 135-139, (2010) $\endgroup$ Commented Sep 14, 2019 at 21:29
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    $\begingroup$ @MattF., there are trade-offs. Overall, I feel that the advantage of extra space is significant (sure, people get used to somethings hence they react against changes). However, occasionally, one could use TeX "\," instead of "\ ". $\endgroup$
    – Wlod AA
    Commented Sep 23, 2019 at 12:10
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    $\begingroup$ @WlodAA it relies on Ramsey numbers for hypergraphs, so we are not proud of the bound at all, and did not even write it explicitly. Some iterated logarithm. $\endgroup$ Commented Sep 23, 2019 at 13:25
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    $\begingroup$ Here is a pdf drive.google.com/file/d/135Q9Ems_qfAMsk-ueE1mFMDnxRUec127/… $\endgroup$ Commented Sep 23, 2019 at 13:32
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Hales' proof of the Kepler conjecture:

"... he embarked on a research program to systematically apply linear programming methods to find a lower bound on the value of this function for each one of a set of over 5,000 different configurations of spheres. If a lower bound (for the function value) could be found for every one of these configurations that was greater than the value of the function for the cubic close packing arrangement, then the Kepler conjecture would be proved. To find lower bounds for all cases involved solving about 100,000 linear programming problems." [Wikipedia]

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    $\begingroup$ But see this MO question for a discussion of whether it's reasonable to think of the proof as reducing the theorem to a finite computation, which is then carried out. $\endgroup$ Commented Sep 15, 2019 at 13:59
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For a somewhat different class of examples, there are some problems in differential topology that can be solved with bordism:

  1. First, show that the quantity you want to compute is a bordism invariant, i.e. a group homomorphism from the appropriate bordism group to an abelian group.
  2. Then, determine a finite list of generators of the bordism group. (This step is typically the most difficult.)
  3. Check on the generators.

Thus a problem that a priori is about an incredibly large number of manifolds and must be checked in generality is reduced to a finite set of cases.

Here are some examples.

  • In dimension 4, the Hirzebruch signature theorem states that if $M$ is a closed, oriented 4-manifold, the first Pontrjagin number of $M$ is three times the signature $\sigma(M)$ of its intersection form. One proves this by showing that both $\sigma(M)$ and $p_1(M)$ are oriented bordism invariants, and that the bordism group $\Omega_4^{\mathrm{SO}}\cong\mathbb Z$, generated by the class of $\mathbb{CP}^2$. It then suffices to compute $\sigma(\mathbb{CP}^2)=1$ and $p_1(\mathbb{CP}^2)=3$.
  • Rokhlin's theorem, that the signature of a closed, spin 4-manifold is divisible by 16, can be proven in a similar way: $\Omega_4^{\mathrm{Spin}}\cong\mathbb Z$, and the class of the K3 surface is a generator. Then one computes $\sigma(\mathrm{K3}) = -16$. (However, this isn't the standard proof.)
  • An application to mathematical physics: while we don't know rigorously what a quantum field theory is, physical arguments suggest that it should come with data of an anomaly, which generally determines a bordism invariant in one dimension higher. Anomaly cancellation involves proving this bordism invariant vanishes, which can be checked on a set of generators. For example, a recent paper of Freed and Hopkins applies this to M-theory.
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    $\begingroup$ of course, this was also the original approach to the atiyah-singer index theorem, encapsulating hirzebruch and rokhlin... $\endgroup$
    – mme
    Commented Sep 14, 2019 at 21:47
  • $\begingroup$ @MikeMiller oh -- I didn't realize the heat kernel proof was't the original! $\endgroup$ Commented Sep 14, 2019 at 23:41

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