Aaron Robertson (mathematician)

Aaron Robertson
Aaron Robertson
Born	Aaron Robertson; November 8, 1971 (age 52); Torrance, California, U.S.
Alma mater	University of Michigan (BS); Temple University (PhD);
	Scientific career
Fields	Mathematics ; Ramsey Theory ;
Institutions	Colgate University
Thesis	Some New Results in Ramsey Theory (1999)
Doctoral advisor	Doron Zeilberger

Last updated January 06, 2024

Aaron Robertson (born November 8, 1971) is an American mathematician who specializes in Ramsey theory. He is a professor at Colgate University.^[1]

Life and education

Aaron Robertson was born in Torrance, California, and moved with his parents to Midland, Michigan at the age of 4. He studied actuarial science as an undergraduate at the University of Michigan, and went on to graduate school in mathematics at Temple University in Philadelphia, where he was supervised by Doron Zeilberger. Robertson received his Ph.D. in 1999 with his thesis titled Some New Results in Ramsey Theory.^[2]

Following his Ph.D., Robertson became an assistant professor of mathematics at Colgate University, where he is currently a full professor.

Mathematical work

Robertson's work in mathematics since 1998 has consisted predominantly of topics related to Ramsey theory.

One of Robertson's earliest publications is a paper, co-authored with his supervisor Doron Zeilberger, which came out of his Ph.D. work. The authors prove that "the minimum number (asymptotically) of monochromatic Schur Triples that a 2-colouring of $[1,n]$ can have ${\textstyle n^{2}/22+O(n)}$ ".^[2]

After completing his dissertation, Robertson worked with 3-term arithmetic progressions where he found the best-known values that were close to each other and titled this piece New Lower Bounds for Some Multicolored Ramsey Numbers.^[3]

Another notable piece of Robertson's research is a paper co-authored with Doron Zeilberger and Herbert Wilf titled Permutation Patterns and Continued Fractions.^[4] In the paper, they "find a generating function for the number of (132)-avoiding permutations that have a given number of (123) patterns"^[4] with the result being "in the form of a continued fraction".^[4] Robertson's contribution to this specific paper includes discussion on permutations that avoid a certain pattern but contain others.

A notable paper Robertson wrote titled A Probalistic Threshold For Monochromatic Arithmetic Progressions^[5] explores the function $f_{r}(k)={\sqrt {k}}\cdot r^{k/2}$ (where $r\geq 2$ is fixed) and the r-colourings of $[1,n_{k}]=\{1,2,\ldots ,n_{k}\}$ . Robertson analyzes the threshold function for $k$ -term arithmetic progressions and improves the bounds found previously.

In 2004, Robertson and Bruce M. Landman published the book Ramsey Theory on the Integers, of which a second expanded edition appeared in 2014.^[6] The book introduced new topics such as rainbow Ramsey theory, an “inequality” version of Schur's theorem, monochromatic solutions of recurrence relations, Ramsey results involving both sums and products, monochromatic sets avoiding certain differences, Ramsey properties for polynomial progressions, generalizations of the Erdős–Ginzberg–Ziv theorem, and the number of arithmetic progressions under arbitrary colourings.

More recently, in 2021, Robertson published a book titled Fundamentals of Ramsey Theory.^[7] Robertson's goal in writing this book was to "help give an overview of Ramsey theory from several points of view, adding intuition and detailed proofs as we go, while being, hopefully, a bit gentler than most of the other books on Ramsey theory".^[7] Throughout the book, Robertson discusses several theorems including Ramsey's Theorem, Van der Waerden's Theorem, Rado's Theorem, and Hales–Jewett Theorem.

Related Research Articles

Ramsey theory, named after the British mathematician and philosopher Frank P. Ramsey, is a branch of the mathematical field of combinatorics that focuses on the appearance of order in a substructure given a structure of a known size. Problems in Ramsey theory typically ask a question of the form: "how big must some structure be to guarantee that a particular property holds?"

In combinatorics, Ramsey's theorem, in one of its graph-theoretic forms, states that one will find monochromatic cliques in any edge labelling (with colours) of a sufficiently large complete graph. To demonstrate the theorem for two colours (say, blue and red), let $r$ and $s$ be any two positive integers. Ramsey's theorem states that there exists a least positive integer $R (r, s)$ for which every blue-red edge colouring of the complete graph on $R (r, s)$ vertices contains a blue clique on $r$ vertices or a red clique on $s$ vertices. (Here $R (r, s)$ signifies an integer that depends on both $r$ and $s$ .)

Combinatorics is a branch of mathematics concerning the study of finite or countable discrete structures.

In arithmetic combinatorics, Szemerédi's theorem is a result concerning arithmetic progressions in subsets of the integers. In 1936, Erdős and Turán conjectured that every set of integers A with positive natural density contains a k-term arithmetic progression for every k. Endre Szemerédi proved the conjecture in 1975.

Rado's theorem is a theorem from the branch of mathematics known as Ramsey theory. It is named for the German mathematician Richard Rado. It was proved in his thesis, Studien zur Kombinatorik.

In mathematics, an alternating sign matrix is a square matrix of 0s, 1s, and −1s such that the sum of each row and column is 1 and the nonzero entries in each row and column alternate in sign. These matrices generalize permutation matrices and arise naturally when using Dodgson condensation to compute a determinant. They are also closely related to the six-vertex model with domain wall boundary conditions from statistical mechanics. They were first defined by William Mills, David Robbins, and Howard Rumsey in the former context.

Ben Joseph Green FRS is a British mathematician, specialising in combinatorics and number theory. He is the Waynflete Professor of Pure Mathematics at the University of Oxford.

In additive combinatorics a discipline within mathematics, Freiman's theorem is a central result which indicates the approximate structure of sets whose sumset is small. It roughly states that if $is small, then can be contained in a small generalized arithmetic progression.$

<span class="mw-page-title-main">Book (graph theory)</span>

In graph theory, a book graph may be any of several kinds of graph formed by multiple cycles sharing an edge.

Erdős' conjecture on arithmetic progressions, often referred to as the Erdős–Turán conjecture, is a conjecture in arithmetic combinatorics. It states that if the sum of the reciprocals of the members of a set A of positive integers diverges, then A contains arbitrarily long arithmetic progressions.

The Stanley–Wilf conjecture, formulated independently by Richard P. Stanley and Herbert Wilf in the late 1980s, states that the growth rate of every proper permutation class is singly exponential. It was proved by Adam Marcus and Gábor Tardos (2004) and is no longer a conjecture. Marcus and Tardos actually proved a different conjecture, due to Zoltán Füredi and Péter Hajnal (1992), which had been shown to imply the Stanley–Wilf conjecture by Klazar (2000).

Van der Waerden's theorem states that for any positive integers r and k there exists a positive integer N such that if the integers {1, 2, ..., N} are colored, each with one of r different colors, then there are at least k integers in arithmetic progression all of the same color. The smallest such N is the van der Waerden numberW(r, k).

Discrepancy of hypergraphs is an area of discrepancy theory.

In mathematics, arithmetic combinatorics is a field in the intersection of number theory, combinatorics, ergodic theory and harmonic analysis.

Folkman's theorem is a theorem in mathematics, and more particularly in arithmetic combinatorics and Ramsey theory. According to this theorem, whenever the natural numbers are partitioned into finitely many subsets, there exist arbitrarily large sets of numbers all of whose sums belong to the same subset of the partition. The theorem had been discovered and proved independently by several mathematicians, before it was named "Folkman's theorem", as a memorial to Jon Folkman, by Graham, Rothschild, and Spencer.

Leonid Mirsky was a Russian-British mathematician who worked in number theory, linear algebra, and combinatorics. Mirsky's theorem is named after him.

Ira Martin Gessel is an American mathematician, known for his work in combinatorics. He is a long-time faculty member at Brandeis University and resides in Arlington, Massachusetts.

<span class="mw-page-title-main">Salem–Spencer set</span> Progression-free set of numbers

In mathematics, and in particular in arithmetic combinatorics, a Salem-Spencer set is a set of numbers no three of which form an arithmetic progression. Salem–Spencer sets are also called 3-AP-free sequences or progression-free sets. They have also been called non-averaging sets, but this term has also been used to denote a set of integers none of which can be obtained as the average of any subset of the other numbers. Salem-Spencer sets are named after Raphaël Salem and Donald C. Spencer, who showed in 1942 that Salem–Spencer sets can have nearly-linear size. However a later theorem of Klaus Roth shows that the size is always less than linear.

In mathematics, structural Ramsey theory is a categorical generalisation of Ramsey theory, rooted in the idea that many important results of Ramsey theory have "similar" logical structures. The key observation is noting that these Ramsey-type theorems can be expressed as the assertion that a certain category has the Ramsey property.

Hunter Snevily (1956–2013) was an American mathematician with expertise and contributions in Set theory, Graph theory, Discrete geometry, and Ramsey theory on the integers.

References

↑ "Aaron Robertson | Colgate University". www.colgate.edu. Retrieved 2021-10-17.
1 2 Robertson, Aaron; Zeilberger, Doron (1998-03-25). "A 2-Coloring of $[1,N]$ can have $(1/22)N^2+O(N)$ Monochromatic Schur Triples, but not less!". The Electronic Journal of Combinatorics. 5: R19. doi: 10.37236/1357 . ISSN 1077-8926.
↑ Robertson, Aaron (1999). "New Lower Bounds for Some Multicolored Ramsey Numbers". The Electronic Journal of Combinatorics. 6: R3. doi: 10.37236/1435 . ISSN 1077-8926.
1 2 3 Robertson, Aaron; Wilf, Herbert S.; Zeilberger, Doron (1999-10-01). "Permutation Patterns and Continued Fractions". The Electronic Journal of Combinatorics. 6: R38. doi: 10.37236/1470 . ISSN 1077-8926.
↑ Robertson, Aaron (2016-01-01). "A probabilistic threshold for monochromatic arithmetic progressions". Journal of Combinatorial Theory . Series A. 137: 79–87. arXiv: 1206.2885 . doi: 10.1016/j.jcta.2015.08.003 . ISSN 0097-3165.
↑ Landman, Bruce M.; Robertson, Aaron (2014). Ramsey Theory on the Integers. Vol. 73 (2nd ed.). The Student Mathematical Library. doi:10.1090/stml/073. ISBN 978-1-4704-2000-0.
1 2 Robertson, Aaron (2021-06-18). Fundamentals of Ramsey Theory. Boca Raton: Chapman and Hall/CRC. doi:10.1201/9780429431418. ISBN 978-0-429-43141-8. S2CID 234866085.

External links

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[1] "Aaron Robertson | Colgate University". www.colgate.edu. Retrieved 2021-10-17.

[:0-2] 1 2 Robertson, Aaron; Zeilberger, Doron (1998-03-25). "A 2-Coloring of $[1,N]$ can have $(1/22)N^2+O(N)$ Monochromatic Schur Triples, but not less!". The Electronic Journal of Combinatorics. 5: R19. doi: 10.37236/1357 . ISSN 1077-8926.

[3] Robertson, Aaron (1999). "New Lower Bounds for Some Multicolored Ramsey Numbers". The Electronic Journal of Combinatorics. 6: R3. doi: 10.37236/1435 . ISSN 1077-8926.

[:1-4] 1 2 3 Robertson, Aaron; Wilf, Herbert S.; Zeilberger, Doron (1999-10-01). "Permutation Patterns and Continued Fractions". The Electronic Journal of Combinatorics. 6: R38. doi: 10.37236/1470 . ISSN 1077-8926.

[5] Robertson, Aaron (2016-01-01). "A probabilistic threshold for monochromatic arithmetic progressions". Journal of Combinatorial Theory . Series A. 137: 79–87. arXiv: 1206.2885 . doi: 10.1016/j.jcta.2015.08.003 . ISSN 0097-3165.

[:2-6] Landman, Bruce M.; Robertson, Aaron (2014). Ramsey Theory on the Integers. Vol. 73 (2nd ed.). The Student Mathematical Library. doi:10.1090/stml/073. ISBN 978-1-4704-2000-0.

[:3-7] 1 2 Robertson, Aaron (2021-06-18). Fundamentals of Ramsey Theory. Boca Raton: Chapman and Hall/CRC. doi:10.1201/9780429431418. ISBN 978-0-429-43141-8. S2CID 234866085.

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Aaron Robertson
Born	Aaron Robertson (1971-11-08) November 8, 1971 (age 52) Torrance, California, U.S.
Alma mater	University of Michigan (BS) Temple University (PhD)
Scientific career
Fields	Mathematics Ramsey Theory
Institutions	Colgate University
Thesis	Some New Results in Ramsey Theory (1999)
Doctoral advisor	Doron Zeilberger