Ramsey's Theorem

by aoum, Apr 1, 2025, 11:26 PM

Ramsey's Theorem: Order in Chaos

1. Introduction

Ramsey’s Theorem is a fundamental result in combinatorics that asserts the inevitability of order within sufficiently large structures. It states that in any large enough system, patterns and regularity must emerge, no matter how chaotically the system is constructed. This theorem is a cornerstone of Ramsey theory, which studies conditions under which order must appear in mathematical objects.

2. The Basic Form of Ramsey’s Theorem

The simplest version of Ramsey’s Theorem applies to graphs. It states that for any integer $r$ , there exists a number $R(r)$ such that if the edges of a complete graph with at least $R(r)$ vertices are colored in two colors (say, red and blue), there will always be a monochromatic complete subgraph of size $r$ . In mathematical terms:

Theorem (Graph Ramsey Theorem): For every integer $r \geq 2$ , there exists a smallest integer $R(r)$ such that any red-blue coloring of the edges of the complete graph $K_{R(r)}$ contains a monochromatic complete subgraph $K_r$ .

For example:

$R(2) = 2$ , since any two connected vertices form a monochromatic $K_2$ .
$R(3) = 6$ , meaning that in any red-blue edge-coloring of a complete graph with 6 vertices, there is always a monochromatic triangle ( $K_3$ ).
Higher values of $R(r)$ grow rapidly and are difficult to compute exactly.

3. Proof of the Basic Case: $R(3) = 6$

To prove that $R(3) = 6$ , we consider a complete graph with 6 vertices where every edge is colored either red or blue. We must show that there exists a monochromatic triangle.

Consider any vertex $v$ . It has 5 edges connecting it to other vertices, and these edges must be colored in some combination of red and blue. By the pigeonhole principle, at least 3 of these edges must be the same color (say, red). Let these edges connect $v$ to vertices $A$ , $B$ , and $C$ .

If any of the edges $AB$ , $BC$ , or $CA$ is also red, we have a red triangle.
If none of them is red, they must all be blue, forming a blue triangle.

Thus, in any coloring of $K_6$ , there must be a monochromatic $K_3$ , proving $R(3) = 6$ .

4. The General Form of Ramsey’s Theorem

Ramsey’s theorem can be extended to more than two colors and larger cliques:

Theorem (General Ramsey Theorem): For any integers $r_1, r_2, \dots, r_k$ , there exists a number $R(r_1, r_2, \dots, r_k)$ such that for any edge-coloring of a complete graph with at least $R(r_1, r_2, \dots, r_k)$ vertices using $k$ colors, there is always a monochromatic complete subgraph of size $r_i$ in some color.

This implies that no matter how the edges are colored, some structured subgraph must appear.

5. Bounds on Ramsey Numbers

Ramsey numbers grow very fast and are difficult to compute. The best known bounds include:

$\displaystyle 2^{r/2} \leq R(r) \leq 4^r$ .
For small values:
$R(4) = 18, \quad R(5) = 43, \quad R(6) \text{ is unknown but estimated to be between } 102 \text{ and } 165.$

6. Proof Technique: The Probabilistic Method

One of the most powerful tools in Ramsey theory is the probabilistic method. Consider an $n$ -vertex graph where each edge is randomly colored red or blue. Using probability, one can show that for sufficiently large $n$ , no monochromatic clique of a given size exists with positive probability, giving lower bounds for Ramsey numbers.

7. Applications of Ramsey’s Theorem

Ramsey’s Theorem has applications in:

Graph Theory: Understanding unavoidable substructures in graphs.
Number Theory: The Erdős–Szekeres theorem on sequences.
Theoretical Computer Science: Computational complexity and logic.
Physics: Phase transitions and pattern formation.
Combinatorial Geometry: Finding structure in high-dimensional spaces.

8. Conclusion

Ramsey’s Theorem guarantees that large enough structures always contain ordered substructures, no matter how disorderly they appear. It is a deep result with applications in many areas of mathematics and theoretical computer science. The study of Ramsey numbers remains an open problem, with only a few exact values known.

References

Wikipedia: Ramsey's Theorem
MathWorld: Ramsey's Theorem
Graham, R. L., Rothschild, B. L., & Spencer, J. H. Ramsey Theory (1990).

Ramsey s Theorem

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by zhenghua, Apr 10, 2025, 1:27 AM
Are you asking to contribute or to be notified whenever a post is published?
by aoum, Apr 10, 2025, 12:20 AM
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The first few posts for April are out!
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Sure! I understand that it would be quite a bit to take in.
by aoum, Apr 1, 2025, 11:08 PM
No, but it is a lot to take in. Also, could you do the Gamma Function next?
by HacheB2031, Apr 1, 2025, 3:04 AM
Am I going too fast? Would you like me to slow down?
by aoum, Mar 31, 2025, 11:34 PM
Seriously, how do you make these so fast???
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by aoum, Mar 29, 2025, 12:31 AM
That's all right.
by aoum, Mar 28, 2025, 10:46 PM
sorry i couldn't contribute, was working on my own blog and was sick, i'll try to contribute more
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I think it would also be cool if you did a problem of the day every day, as I see from today's problem.
by jocaleby1, Mar 5, 2025, 1:13 AM
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Yeah, keep on making these "lectures"
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Ramsey's Theorem

by aoum, Apr 1, 2025, 11:26 PM

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