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Combinatorics

March 10, 2023

Not to be confused with Combinatoriality.
"Combinatorial" redirects here. For combinatorial logic in computer science, see Combinatorial logic.

Combinatorics is an area of mathematics primarily concerned with counting, both as a means and an end in obtaining results, and certain properties of finite structures. It is closely related to many other areas of mathematics and has many applications ranging from logic to statistical physics and from evolutionary biology to computer science.

Combinatorics is well known for the breadth of the problems it tackles. Combinatorial problems arise in many areas of pure mathematics, notably in algebra, probability theory, topology, and geometry,[1] as well as in its many application areas. Many combinatorial questions have historically been considered in isolation, giving an ad hoc solution to a problem arising in some mathematical context. In the later twentieth century, however, powerful and general theoretical methods were developed, making combinatorics into an independent branch of mathematics in its own right.[2] One of the oldest and most accessible parts of combinatorics is graph theory, which by itself has numerous natural connections to other areas. Combinatorics is used frequently in computer science to obtain formulas and estimates in the analysis of algorithms.

A mathematician who studies combinatorics is called a combinatorialist.

Definition

The full scope of combinatorics is not universally agreed upon.[3] According to H.J. Ryser, a definition of the subject is difficult because it crosses so many mathematical subdivisions.[4] Insofar as an area can be described by the types of problems it addresses, combinatorics is involved with:

  • the enumeration (counting) of specified structures, sometimes referred to as arrangements or configurations in a very general sense, associated with finite systems,
  • the existence of such structures that satisfy certain given criteria,
  • the construction of these structures, perhaps in many ways, and
  • optimization: finding the "best" structure or solution among several possibilities, be it the "largest", "smallest" or satisfying some other optimality criterion.

Leon Mirsky has said: "combinatorics is a range of linked studies which have something in common and yet diverge widely in their objectives, their methods, and the degree of coherence they have attained."[5] One way to define combinatorics is, perhaps, to describe its subdivisions with their problems and techniques. This is the approach that is used below. However, there are also purely historical reasons for including or not including some topics under the combinatorics umbrella.[6] Although primarily concerned with finite systems, some combinatorial questions and techniques can be extended to an infinite (specifically, countable) but discrete setting.

History

 
An example of change ringing (with six bells), one of the earliest nontrivial results in graph theory.
Main article: History of combinatorics

Basic combinatorial concepts and enumerative results appeared throughout the ancient world. In the 6th century BCE, ancient Indian physician Sushruta asserts in Sushruta Samhita that 63 combinations can be made out of 6 different tastes, taken one at a time, two at a time, etc., thus computing all 26 − 1 possibilities. Greek historian Plutarch discusses an argument between Chrysippus (3rd century BCE) and Hipparchus (2nd century BCE) of a rather delicate enumerative problem, which was later shown to be related to Schröder–Hipparchus numbers.[7][8][9] Earlier, in the Ostomachion, Archimedes (3rd century BCE) may have considered the number of configurations of a tiling puzzle,[10] while combinatorial interests possibly were present in lost works by Apollonius.[11][12]

In the Middle Ages, combinatorics continued to be studied, largely outside of the European civilization. The Indian mathematician Mahāvīra (c. 850) provided formulae for the number of permutations and combinations,[13][14] and these formulas may have been familiar to Indian mathematicians as early as the 6th century CE.[15] The philosopher and astronomer Rabbi Abraham ibn Ezra (c. 1140) established the symmetry of binomial coefficients, while a closed formula was obtained later by the talmudist and mathematician Levi ben Gerson (better known as Gersonides), in 1321.[16] The arithmetical triangle—a graphical diagram showing relationships among the binomial coefficients—was presented by mathematicians in treatises dating as far back as the 10th century, and would eventually become known as Pascal's triangle. Later, in Medieval England, campanology provided examples of what is now known as Hamiltonian cycles in certain Cayley graphs on permutations.[17][18]

During the Renaissance, together with the rest of mathematics and the sciences, combinatorics enjoyed a rebirth. Works of Pascal, Newton, Jacob Bernoulli and Euler became foundational in the emerging field. In modern times, the works of J.J. Sylvester (late 19th century) and Percy MacMahon (early 20th century) helped lay the foundation for enumerative and algebraic combinatorics. Graph theory also enjoyed an increase of interest at the same time, especially in connection with the four color problem.

In the second half of the 20th century, combinatorics enjoyed a rapid growth, which led to establishment of dozens of new journals and conferences in the subject.[19] In part, the growth was spurred by new connections and applications to other fields, ranging from algebra to probability, from functional analysis to number theory, etc. These connections shed the boundaries between combinatorics and parts of mathematics and theoretical computer science, but at the same time led to a partial fragmentation of the field.

Approaches and subfields of combinatorics

Enumerative combinatorics

 
Five binary trees on three vertices, an example of Catalan numbers.
Main article: Enumerative combinatorics

Enumerative combinatorics is the most classical area of combinatorics and concentrates on counting the number of certain combinatorial objects. Although counting the number of elements in a set is a rather broad mathematical problem, many of the problems that arise in applications have a relatively simple combinatorial description. Fibonacci numbers is the basic example of a problem in enumerative combinatorics. The twelvefold way provides a unified framework for counting permutations, combinations and partitions.

Analytic combinatorics

Main article: Analytic combinatorics

Analytic combinatorics concerns the enumeration of combinatorial structures using tools from complex analysis and probability theory. In contrast with enumerative combinatorics, which uses explicit combinatorial formulae and generating functions to describe the results, analytic combinatorics aims at obtaining asymptotic formulae.

Partition theory

Main article: Partition theory

Partition theory studies various enumeration and asymptotic problems related to integer partitions, and is closely related to q-series, special functions and orthogonal polynomials. Originally a part of number theory and analysis, it is now considered a part of combinatorics or an independent field. It incorporates the bijective approach and various tools in analysis and analytic number theory and has connections with statistical mechanics. Partitions can be graphically visualized with Young diagrams or Ferrers diagrams. They occur in a number of branches of mathematics and physics, including the study of symmetric polynomials and of the symmetric group and in group representation theory in general.

Graph theory

Main article: Graph theory

Graphs are fundamental objects in combinatorics. Considerations of graph theory range from enumeration (e.g., the number of graphs on n vertices with k edges) to existing structures (e.g., Hamiltonian cycles) to algebraic representations (e.g., given a graph G and two numbers x and y, does the Tutte polynomial TG(x,y) have a combinatorial interpretation?). Although there are very strong connections between graph theory and combinatorics, they are sometimes thought of as separate subjects.[20] While combinatorial methods apply to many graph theory problems, the two disciplines are generally used to seek solutions to different types of problems.

Design theory

Main article: Combinatorial design

Design theory is a study of combinatorial designs, which are collections of subsets with certain intersection properties. Block designs are combinatorial designs of a special type. This area is one of the oldest parts of combinatorics, such as in Kirkman's schoolgirl problem proposed in 1850. The solution of the problem is a special case of a Steiner system, which systems play an important role in the classification of finite simple groups. The area has further connections to coding theory and geometric combinatorics.

Combinatorial design theory can be applied to the area of design of experiments. Some of the basic theory of combinatorial designs originated in the statistician Ronald Fisher's work on the design of biological experiments. Modern applications are also found in a wide gamut of areas including finite geometry, tournament scheduling, lotteries, mathematical chemistry, mathematical biology, algorithm design and analysis, networking, group testing and cryptography.[21]

Finite geometry

Main article: Finite geometry

Finite geometry is the study of geometric systems having only a finite number of points. Structures analogous to those found in continuous geometries (Euclidean plane, real projective space, etc.) but defined combinatorially are the main items studied. This area provides a rich source of examples for design theory. It should not be confused with discrete geometry (combinatorial geometry).

Order theory

 
Hasse diagram of the powerset of {x,y,z} ordered by inclusion.
Main article: Order theory

Order theory is the study of partially ordered sets, both finite and infinite. It provides a formal framework for describing statements such as "this is less than that" or "this precedes that". Various examples of partial orders appear in algebra, geometry, number theory and throughout combinatorics and graph theory. Notable classes and examples of partial orders include lattices and Boolean algebras.

Matroid theory

Main article: Matroid theory

Matroid theory abstracts part of geometry. It studies the properties of sets (usually, finite sets) of vectors in a vector space that do not depend on the particular coefficients in a linear dependence relation. Not only the structure but also enumerative properties belong to matroid theory. Matroid theory was introduced by Hassler Whitney and studied as a part of order theory. It is now an independent field of study with a number of connections with other parts of combinatorics.

Extremal combinatorics

Main article: Extremal combinatorics

Extremal combinatorics studies how large or how small a collection of finite objects (numbers, graphs, vectors, sets, etc.) can be, if it has to satisfy certain restrictions. Much of extremal combinatorics concerns classes of set systems; this is called extremal set theory. For instance, in an n-element set, what is the largest number of k-element subsets that can pairwise intersect one another? What is the largest number of subsets of which none contains any other? The latter question is answered by Sperner's theorem, which gave rise to much of extremal set theory.

The types of questions addressed in this case are about the largest possible graph which satisfies certain properties. For example, the largest triangle-free graph on 2n vertices is a complete bipartite graph Kn,n. Often it is too hard even to find the extremal answer f(n) exactly and one can only give an asymptotic estimate.

Ramsey theory is another part of extremal combinatorics. It states that any sufficiently large configuration will contain some sort of order. It is an advanced generalization of the pigeonhole principle.

Probabilistic combinatorics

Main article: Probabilistic method

In probabilistic combinatorics, the questions are of the following type: what is the probability of a certain property for a random discrete object, such as a random graph? For instance, what is the average number of triangles in a random graph? Probabilistic methods are also used to determine the existence of combinatorial objects with certain prescribed properties (for which explicit examples might be difficult to find) by observing that the probability of randomly selecting an object with those properties is greater than 0. This approach (often referred to as the probabilistic method) proved highly effective in applications to extremal combinatorics and graph theory. A closely related area is the study of finite Markov chains, especially on combinatorial objects. Here again probabilistic tools are used to estimate the mixing time.[clarification needed]

Often associated with Paul Erdős, who did the pioneering work on the subject, probabilistic combinatorics was traditionally viewed as a set of tools to study problems in other parts of combinatorics. The area recently grew to become an independent field of combinatorics.

Algebraic combinatorics

 
Young diagram of a partition (5,4,1).
Main article: Algebraic combinatorics

Algebraic combinatorics is an area of mathematics that employs methods of abstract algebra, notably group theory and representation theory, in various combinatorial contexts and, conversely, applies combinatorial techniques to problems in algebra. Algebraic combinatorics has come to be seen more expansively as an area of mathematics where the interaction of combinatorial and algebraic methods is particularly strong and significant. Thus the combinatorial topics may be enumerative in nature or involve matroids, polytopes, partially ordered sets, or finite geometries. On the algebraic side, besides group and representation theory, lattice theory and commutative algebra are common.

Combinatorics on words

 
Construction of a Thue–Morse infinite word.
Main article: Combinatorics on words

Combinatorics on words deals with formal languages. It arose independently within several branches of mathematics, including number theory, group theory and probability. It has applications to enumerative combinatorics, fractal analysis, theoretical computer science, automata theory, and linguistics. While many applications are new, the classical Chomsky–Schützenberger hierarchy of classes of formal grammars is perhaps the best-known result in the field.

Geometric combinatorics

Main article: Geometric combinatorics

Geometric combinatorics is related to convex and discrete geometry. It asks, for example, how many faces of each dimension a convex polytope can have. Metric properties of polytopes play an important role as well, e.g. the Cauchy theorem on the rigidity of convex polytopes. Special polytopes are also considered, such as permutohedra, associahedra and Birkhoff polytopes. Combinatorial geometry is a historical name for discrete geometry.

It includes a number of subareas such as polyhedral combinatorics (the study of faces of convex polyhedra), convex geometry (the study of convex sets, in particular combinatorics of their intersections), and discrete geometry, which in turn has many applications to computational geometry. The study of regular polytopes, Archimedean solids, and kissing numbers is also a part of geometric combinatorics. Special polytopes are also considered, such as the permutohedron, associahedron and Birkhoff polytope.

Topological combinatorics

 
Splitting a necklace with two cuts.
Main article: Topological combinatorics

Combinatorial analogs of concepts and methods in topology are used to study graph coloring, fair division, partitions, partially ordered sets, decision trees, necklace problems and discrete Morse theory. It should not be confused with combinatorial topology which is an older name for algebraic topology.

Arithmetic combinatorics

Main article: Arithmetic combinatorics

Arithmetic combinatorics arose out of the interplay between number theory, combinatorics, ergodic theory, and harmonic analysis. It is about combinatorial estimates associated with arithmetic operations (addition, subtraction, multiplication, and division). Additive number theory (sometimes also called additive combinatorics) refers to the special case when only the operations of addition and subtraction are involved. One important technique in arithmetic combinatorics is the ergodic theory of dynamical systems.

Infinitary combinatorics

Main article: Infinitary combinatorics

Infinitary combinatorics, or combinatorial set theory, is an extension of ideas in combinatorics to infinite sets. It is a part of set theory, an area of mathematical logic, but uses tools and ideas from both set theory and extremal combinatorics. Some of the things studied include continuous graphs and trees, extensions of Ramsey's theorem, and Martin's axiom. Recent developments concern combinatorics of the continuum[22] and combinatorics on successors of singular cardinals.[23]

Gian-Carlo Rota used the name continuous combinatorics[24] to describe geometric probability, since there are many analogies between counting and measure.

Related fields

 
Kissing spheres are connected to both coding theory and discrete geometry.

Combinatorial optimization

Combinatorial optimization is the study of optimization on discrete and combinatorial objects. It started as a part of combinatorics and graph theory, but is now viewed as a branch of applied mathematics and computer science, related to operations research, algorithm theory and computational complexity theory.

Coding theory

Coding theory started as a part of design theory with early combinatorial constructions of error-correcting codes. The main idea of the subject is to design efficient and reliable methods of data transmission. It is now a large field of study, part of information theory.

Discrete and computational geometry

Discrete geometry (also called combinatorial geometry) also began as a part of combinatorics, with early results on convex polytopes and kissing numbers. With the emergence of applications of discrete geometry to computational geometry, these two fields partially merged and became a separate field of study. There remain many connections with geometric and topological combinatorics, which themselves can be viewed as outgrowths of the early discrete geometry.

Combinatorics and dynamical systems

Combinatorial aspects of dynamical systems is another emerging field. Here dynamical systems can be defined on combinatorial objects. See for example graph dynamical system.

Combinatorics and physics

There are increasing interactions between combinatorics and physics, particularly statistical physics. Examples include an exact solution of the Ising model, and a connection between the Potts model on one hand, and the chromatic and Tutte polynomials on the other hand.

See also

Notes

  1. ^ Björner and Stanley, p. 2
  2. ^ Lovász, László (1979). Combinatorial Problems and Exercises. North-Holland. ISBN 9780821842621. from the original on 2021-04-16. Retrieved 2021-03-23. In my opinion, combinatorics is now growing out of this early stage.
  3. ^ Pak, Igor. "What is Combinatorics?". from the original on 17 October 2017. Retrieved 1 November 2017.
  4. ^ Ryser 1963, p. 2
  5. ^ Mirsky, Leon (1979), "Book Review" (PDF), Bulletin of the American Mathematical Society, New Series, 1: 380–388, doi:10.1090/S0273-0979-1979-14606-8, (PDF) from the original on 2021-02-26, retrieved 2021-02-04
  6. ^ Rota, Gian Carlo (1969). Discrete Thoughts. Birkhaüser. p. 50. doi:10.1007/978-0-8176-4775-9. ISBN 978-0-8176-4775-9. ... combinatorial theory has been the mother of several of the more active branches of today's mathematics, which have become independent ... . The typical ... case of this is algebraic topology (formerly known as combinatorial topology)
  7. ^ Acerbi, F. (2003). "On the shoulders of Hipparchus". Archive for History of Exact Sciences. 57 (6): 465–502. doi:10.1007/s00407-003-0067-0. S2CID 122758966. from the original on 2022-01-23. Retrieved 2021-03-12.
  8. ^ Stanley, Richard P.; "Hipparchus, Plutarch, Schröder, and Hough", American Mathematical Monthly 104 (1997), no. 4, 344–350.
  9. ^ Habsieger, Laurent; Kazarian, Maxim; Lando, Sergei (1998). "On the Second Number of Plutarch". The American Mathematical Monthly. 105 (5): 446. doi:10.1080/00029890.1998.12004906.
  10. ^ Netz, R.; Acerbi, F.; Wilson, N. "Towards a reconstruction of Archimedes' Stomachion". Sciamvs. 5: 67–99. from the original on 2021-04-16. Retrieved 2021-03-12.
  11. ^ Hogendijk, Jan P. (1986). "Arabic Traces of Lost Works of Apollonius". Archive for History of Exact Sciences. 35 (3): 187–253. doi:10.1007/BF00357307. ISSN 0003-9519. JSTOR 41133783. S2CID 121613986. from the original on 2021-04-18. Retrieved 2021-03-26.
  12. ^ Huxley, G. (1967). "Okytokion". Greek, Roman, and Byzantine Studies. 8 (3): 203. from the original on 2021-04-16. Retrieved 2021-03-26.
  13. ^ O'Connor, John J.; Robertson, Edmund F., "Combinatorics", MacTutor History of Mathematics archive, University of St Andrews
  14. ^ Puttaswamy, Tumkur K. (2000). "The Mathematical Accomplishments of Ancient Indian Mathematicians". In Selin, Helaine (ed.). Mathematics Across Cultures: The History of Non-Western Mathematics. Netherlands: Kluwer Academic Publishers. p. 417. ISBN 978-1-4020-0260-1. from the original on 2021-04-16. Retrieved 2015-11-15.
  15. ^ Biggs, Norman L. (1979). "The Roots of Combinatorics". Historia Mathematica. 6 (2): 109–136. doi:10.1016/0315-0860(79)90074-0.
  16. ^ Maistrov, L.E. (1974), Probability Theory: A Historical Sketch, Academic Press, p. 35, ISBN 978-1-4832-1863-2, from the original on 2021-04-16, retrieved 2015-01-25. (Translation from 1967 Russian ed.)
  17. ^ White, Arthur T. (1987). "Ringing the Cosets". The American Mathematical Monthly. 94 (8): 721–746. doi:10.1080/00029890.1987.12000711.
  18. ^ White, Arthur T. (1996). "Fabian Stedman: The First Group Theorist?". The American Mathematical Monthly. 103 (9): 771–778. doi:10.1080/00029890.1996.12004816.
  19. ^ See Journals in Combinatorics and Graph Theory 2021-02-17 at the Wayback Machine
  20. ^ Sanders, Daniel P.; 2-Digit MSC Comparison 2008-12-31 at the Wayback Machine
  21. ^ Stinson 2003, pg.1
  22. ^ Andreas Blass, Combinatorial Cardinal Characteristics of the Continuum, Chapter 6 in Handbook of Set Theory, edited by Matthew Foreman and Akihiro Kanamori, Springer, 2010
  23. ^ Eisworth, Todd (2010), Foreman, Matthew; Kanamori, Akihiro (eds.), "Successors of Singular Cardinals", Handbook of Set Theory, Dordrecht: Springer Netherlands, pp. 1229–1350, doi:10.1007/978-1-4020-5764-9_16, ISBN 978-1-4020-4843-2, retrieved 2022-08-27
  24. ^ "Continuous and profinite combinatorics" (PDF). (PDF) from the original on 2009-02-26. Retrieved 2009-01-03.

References

  • Björner, Anders; and Stanley, Richard P.; (2010); A Combinatorial Miscellany
  • Bóna, Miklós; (2011); A Walk Through Combinatorics (3rd Edition). ISBN 978-981-4335-23-2, 978-981-4460-00-2
  • Graham, Ronald L.; Groetschel, Martin; and Lovász, László; eds. (1996); Handbook of Combinatorics, Volumes 1 and 2. Amsterdam, NL, and Cambridge, MA: Elsevier (North-Holland) and MIT Press. ISBN 0-262-07169-X
  • Lindner, Charles C.; and Rodger, Christopher A.; eds. (1997); Design Theory, CRC-Press; 1st. edition (1997). ISBN 0-8493-3986-3.
  • Riordan, John (2002) [1958], An Introduction to Combinatorial Analysis, Dover, ISBN 978-0-486-42536-8
  • Ryser, Herbert John (1963), Combinatorial Mathematics, The Carus Mathematical Monographs(#14), The Mathematical Association of America
  • Stanley, Richard P. (1997, 1999); Enumerative Combinatorics, Volumes 1 and 2, Cambridge University Press. ISBN 0-521-55309-1, 0-521-56069-1
  • Stinson, Douglas R. (2003), Combinatorial Designs: Constructions and Analysis, New York: Springer, ISBN 0-387-95487-2
  • van Lint, Jacobus H.; and Wilson, Richard M.; (2001); A Course in Combinatorics, 2nd Edition, Cambridge University Press. ISBN 0-521-80340-3

External links

  • "Combinatorial analysis", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
  • Combinatorial Analysis – an article in Encyclopædia Britannica Eleventh Edition
  • Combinatorics, a MathWorld article with many references.
  • Combinatorics, from a MathPages.com portal.
  • The Hyperbook of Combinatorics, a collection of math articles links.
  • The Two Cultures of Mathematics by W.T. Gowers, article on problem solving vs theory building.
  • "Glossary of Terms in Combinatorics"
  • List of Combinatorics Software and Databases

March 10, 2023
combinatorics, confused, with, combinatoriality, combinatorial, redirects, here, combinatorial, logic, computer, science, combinatorial, logic, this, article, includes, list, general, references, lacks, sufficient, corresponding, inline, citations, please, hel. Not to be confused with Combinatoriality Combinatorial redirects here For combinatorial logic in computer science see Combinatorial logic This article includes a list of general references but it lacks sufficient corresponding inline citations Please help to improve this article by introducing more precise citations July 2022 Learn how and when to remove this template message Combinatorics is an area of mathematics primarily concerned with counting both as a means and an end in obtaining results and certain properties of finite structures It is closely related to many other areas of mathematics and has many applications ranging from logic to statistical physics and from evolutionary biology to computer science Combinatorics is well known for the breadth of the problems it tackles Combinatorial problems arise in many areas of pure mathematics notably in algebra probability theory topology and geometry 1 as well as in its many application areas Many combinatorial questions have historically been considered in isolation giving an ad hoc solution to a problem arising in some mathematical context In the later twentieth century however powerful and general theoretical methods were developed making combinatorics into an independent branch of mathematics in its own right 2 One of the oldest and most accessible parts of combinatorics is graph theory which by itself has numerous natural connections to other areas Combinatorics is used frequently in computer science to obtain formulas and estimates in the analysis of algorithms A mathematician who studies combinatorics is called a combinatorialist Contents 1 Definition 2 History 3 Approaches and subfields of combinatorics 3 1 Enumerative combinatorics 3 2 Analytic combinatorics 3 3 Partition theory 3 4 Graph theory 3 5 Design theory 3 6 Finite geometry 3 7 Order theory 3 8 Matroid theory 3 9 Extremal combinatorics 3 10 Probabilistic combinatorics 3 11 Algebraic combinatorics 3 12 Combinatorics on words 3 13 Geometric combinatorics 3 14 Topological combinatorics 3 15 Arithmetic combinatorics 3 16 Infinitary combinatorics 4 Related fields 4 1 Combinatorial optimization 4 2 Coding theory 4 3 Discrete and computational geometry 4 4 Combinatorics and dynamical systems 4 5 Combinatorics and physics 5 See also 6 Notes 7 References 8 External linksDefinition EditThe full scope of combinatorics is not universally agreed upon 3 According to H J Ryser a definition of the subject is difficult because it crosses so many mathematical subdivisions 4 Insofar as an area can be described by the types of problems it addresses combinatorics is involved with the enumeration counting of specified structures sometimes referred to as arrangements or configurations in a very general sense associated with finite systems the existence of such structures that satisfy certain given criteria the construction of these structures perhaps in many ways and optimization finding the best structure or solution among several possibilities be it the largest smallest or satisfying some other optimality criterion Leon Mirsky has said combinatorics is a range of linked studies which have something in common and yet diverge widely in their objectives their methods and the degree of coherence they have attained 5 One way to define combinatorics is perhaps to describe its subdivisions with their problems and techniques This is the approach that is used below However there are also purely historical reasons for including or not including some topics under the combinatorics umbrella 6 Although primarily concerned with finite systems some combinatorial questions and techniques can be extended to an infinite specifically countable but discrete setting History Edit An example of change ringing with six bells one of the earliest nontrivial results in graph theory Main article History of combinatorics Basic combinatorial concepts and enumerative results appeared throughout the ancient world In the 6th century BCE ancient Indian physician Sushruta asserts in Sushruta Samhita that 63 combinations can be made out of 6 different tastes taken one at a time two at a time etc thus computing all 26 1 possibilities Greek historian Plutarch discusses an argument between Chrysippus 3rd century BCE and Hipparchus 2nd century BCE of a rather delicate enumerative problem which was later shown to be related to Schroder Hipparchus numbers 7 8 9 Earlier in the Ostomachion Archimedes 3rd century BCE may have considered the number of configurations of a tiling puzzle 10 while combinatorial interests possibly were present in lost works by Apollonius 11 12 In the Middle Ages combinatorics continued to be studied largely outside of the European civilization The Indian mathematician Mahavira c 850 provided formulae for the number of permutations and combinations 13 14 and these formulas may have been familiar to Indian mathematicians as early as the 6th century CE 15 The philosopher and astronomer Rabbi Abraham ibn Ezra c 1140 established the symmetry of binomial coefficients while a closed formula was obtained later by the talmudist and mathematician Levi ben Gerson better known as Gersonides in 1321 16 The arithmetical triangle a graphical diagram showing relationships among the binomial coefficients was presented by mathematicians in treatises dating as far back as the 10th century and would eventually become known as Pascal s triangle Later in Medieval England campanology provided examples of what is now known as Hamiltonian cycles in certain Cayley graphs on permutations 17 18 During the Renaissance together with the rest of mathematics and the sciences combinatorics enjoyed a rebirth Works of Pascal Newton Jacob Bernoulli and Euler became foundational in the emerging field In modern times the works of J J Sylvester late 19th century and Percy MacMahon early 20th century helped lay the foundation for enumerative and algebraic combinatorics Graph theory also enjoyed an increase of interest at the same time especially in connection with the four color problem In the second half of the 20th century combinatorics enjoyed a rapid growth which led to establishment of dozens of new journals and conferences in the subject 19 In part the growth was spurred by new connections and applications to other fields ranging from algebra to probability from functional analysis to number theory etc These connections shed the boundaries between combinatorics and parts of mathematics and theoretical computer science but at the same time led to a partial fragmentation of the field Approaches and subfields of combinatorics EditEnumerative combinatorics Edit Five binary trees on three vertices an example of Catalan numbers Main article Enumerative combinatorics Enumerative combinatorics is the most classical area of combinatorics and concentrates on counting the number of certain combinatorial objects Although counting the number of elements in a set is a rather broad mathematical problem many of the problems that arise in applications have a relatively simple combinatorial description Fibonacci numbers is the basic example of a problem in enumerative combinatorics The twelvefold way provides a unified framework for counting permutations combinations and partitions Analytic combinatorics Edit Main article Analytic combinatorics Analytic combinatorics concerns the enumeration of combinatorial structures using tools from complex analysis and probability theory In contrast with enumerative combinatorics which uses explicit combinatorial formulae and generating functions to describe the results analytic combinatorics aims at obtaining asymptotic formulae Partition theory Edit A plane partition Main article Partition theory Partition theory studies various enumeration and asymptotic problems related to integer partitions and is closely related to q series special functions and orthogonal polynomials Originally a part of number theory and analysis it is now considered a part of combinatorics or an independent field It incorporates the bijective approach and various tools in analysis and analytic number theory and has connections with statistical mechanics Partitions can be graphically visualized with Young diagrams or Ferrers diagrams They occur in a number of branches of mathematics and physics including the study of symmetric polynomials and of the symmetric group and in group representation theory in general Graph theory Edit Petersen graph Main article Graph theory Graphs are fundamental objects in combinatorics Considerations of graph theory range from enumeration e g the number of graphs on n vertices with k edges to existing structures e g Hamiltonian cycles to algebraic representations e g given a graph G and two numbers x and y does the Tutte polynomial TG x y have a combinatorial interpretation Although there are very strong connections between graph theory and combinatorics they are sometimes thought of as separate subjects 20 While combinatorial methods apply to many graph theory problems the two disciplines are generally used to seek solutions to different types of problems Design theory Edit Main article Combinatorial design Design theory is a study of combinatorial designs which are collections of subsets with certain intersection properties Block designs are combinatorial designs of a special type This area is one of the oldest parts of combinatorics such as in Kirkman s schoolgirl problem proposed in 1850 The solution of the problem is a special case of a Steiner system which systems play an important role in the classification of finite simple groups The area has further connections to coding theory and geometric combinatorics Combinatorial design theory can be applied to the area of design of experiments Some of the basic theory of combinatorial designs originated in the statistician Ronald Fisher s work on the design of biological experiments Modern applications are also found in a wide gamut of areas including finite geometry tournament scheduling lotteries mathematical chemistry mathematical biology algorithm design and analysis networking group testing and cryptography 21 Finite geometry Edit Main article Finite geometry Finite geometry is the study of geometric systems having only a finite number of points Structures analogous to those found in continuous geometries Euclidean plane real projective space etc but defined combinatorially are the main items studied This area provides a rich source of examples for design theory It should not be confused with discrete geometry combinatorial geometry Order theory Edit Hasse diagram of the powerset of x y z ordered by inclusion Main article Order theory Order theory is the study of partially ordered sets both finite and infinite It provides a formal framework for describing statements such as this is less than that or this precedes that Various examples of partial orders appear in algebra geometry number theory and throughout combinatorics and graph theory Notable classes and examples of partial orders include lattices and Boolean algebras Matroid theory Edit Main article Matroid theory Matroid theory abstracts part of geometry It studies the properties of sets usually finite sets of vectors in a vector space that do not depend on the particular coefficients in a linear dependence relation Not only the structure but also enumerative properties belong to matroid theory Matroid theory was introduced by Hassler Whitney and studied as a part of order theory It is now an independent field of study with a number of connections with other parts of combinatorics Extremal combinatorics Edit Main article Extremal combinatoricsExtremal combinatorics studies how large or how small a collection of finite objects numbers graphs vectors sets etc can be if it has to satisfy certain restrictions Much of extremal combinatorics concerns classes of set systems this is called extremal set theory For instance in an n element set what is the largest number of k element subsets that can pairwise intersect one another What is the largest number of subsets of which none contains any other The latter question is answered by Sperner s theorem which gave rise to much of extremal set theory The types of questions addressed in this case are about the largest possible graph which satisfies certain properties For example the largest triangle free graph on 2n vertices is a complete bipartite graph Kn n Often it is too hard even to find the extremal answer f n exactly and one can only give an asymptotic estimate Ramsey theory is another part of extremal combinatorics It states that any sufficiently large configuration will contain some sort of order It is an advanced generalization of the pigeonhole principle Probabilistic combinatorics Edit Self avoiding walk in a square grid graph Main article Probabilistic method In probabilistic combinatorics the questions are of the following type what is the probability of a certain property for a random discrete object such as a random graph For instance what is the average number of triangles in a random graph Probabilistic methods are also used to determine the existence of combinatorial objects with certain prescribed properties for which explicit examples might be difficult to find by observing that the probability of randomly selecting an object with those properties is greater than 0 This approach often referred to as the probabilistic method proved highly effective in applications to extremal combinatorics and graph theory A closely related area is the study of finite Markov chains especially on combinatorial objects Here again probabilistic tools are used to estimate the mixing time clarification needed Often associated with Paul Erdos who did the pioneering work on the subject probabilistic combinatorics was traditionally viewed as a set of tools to study problems in other parts of combinatorics The area recently grew to become an independent field of combinatorics Algebraic combinatorics Edit Young diagram of a partition 5 4 1 Main article Algebraic combinatorics Algebraic combinatorics is an area of mathematics that employs methods of abstract algebra notably group theory and representation theory in various combinatorial contexts and conversely applies combinatorial techniques to problems in algebra Algebraic combinatorics has come to be seen more expansively as an area of mathematics where the interaction of combinatorial and algebraic methods is particularly strong and significant Thus the combinatorial topics may be enumerative in nature or involve matroids polytopes partially ordered sets or finite geometries On the algebraic side besides group and representation theory lattice theory and commutative algebra are common Combinatorics on words Edit Construction of a Thue Morse infinite word Main article Combinatorics on words Combinatorics on words deals with formal languages It arose independently within several branches of mathematics including number theory group theory and probability It has applications to enumerative combinatorics fractal analysis theoretical computer science automata theory and linguistics While many applications are new the classical Chomsky Schutzenberger hierarchy of classes of formal grammars is perhaps the best known result in the field Geometric combinatorics Edit An icosahedron Main article Geometric combinatorics Geometric combinatorics is related to convex and discrete geometry It asks for example how many faces of each dimension a convex polytope can have Metric properties of polytopes play an important role as well e g the Cauchy theorem on the rigidity of convex polytopes Special polytopes are also considered such as permutohedra associahedra and Birkhoff polytopes Combinatorial geometry is a historical name for discrete geometry It includes a number of subareas such as polyhedral combinatorics the study of faces of convex polyhedra convex geometry the study of convex sets in particular combinatorics of their intersections and discrete geometry which in turn has many applications to computational geometry The study of regular polytopes Archimedean solids and kissing numbers is also a part of geometric combinatorics Special polytopes are also considered such as the permutohedron associahedron and Birkhoff polytope Topological combinatorics Edit Splitting a necklace with two cuts Main article Topological combinatorics Combinatorial analogs of concepts and methods in topology are used to study graph coloring fair division partitions partially ordered sets decision trees necklace problems and discrete Morse theory It should not be confused with combinatorial topology which is an older name for algebraic topology Arithmetic combinatorics Edit Main article Arithmetic combinatorics Arithmetic combinatorics arose out of the interplay between number theory combinatorics ergodic theory and harmonic analysis It is about combinatorial estimates associated with arithmetic operations addition subtraction multiplication and division Additive number theory sometimes also called additive combinatorics refers to the special case when only the operations of addition and subtraction are involved One important technique in arithmetic combinatorics is the ergodic theory of dynamical systems Infinitary combinatorics Edit Main article Infinitary combinatorics Infinitary combinatorics or combinatorial set theory is an extension of ideas in combinatorics to infinite sets It is a part of set theory an area of mathematical logic but uses tools and ideas from both set theory and extremal combinatorics Some of the things studied include continuous graphs and trees extensions of Ramsey s theorem and Martin s axiom Recent developments concern combinatorics of the continuum 22 and combinatorics on successors of singular cardinals 23 Gian Carlo Rota used the name continuous combinatorics 24 to describe geometric probability since there are many analogies between counting and measure Related fields Edit Kissing spheres are connected to both coding theory and discrete geometry Combinatorial optimization Edit Combinatorial optimization is the study of optimization on discrete and combinatorial objects It started as a part of combinatorics and graph theory but is now viewed as a branch of applied mathematics and computer science related to operations research algorithm theory and computational complexity theory Coding theory Edit Coding theory started as a part of design theory with early combinatorial constructions of error correcting codes The main idea of the subject is to design efficient and reliable methods of data transmission It is now a large field of study part of information theory Discrete and computational geometry Edit Discrete geometry also called combinatorial geometry also began as a part of combinatorics with early results on convex polytopes and kissing numbers With the emergence of applications of discrete geometry to computational geometry these two fields partially merged and became a separate field of study There remain many connections with geometric and topological combinatorics which themselves can be viewed as outgrowths of the early discrete geometry Combinatorics and dynamical systems Edit Combinatorial aspects of dynamical systems is another emerging field Here dynamical systems can be defined on combinatorial objects See for example graph dynamical system Combinatorics and physics Edit There are increasing interactions between combinatorics and physics particularly statistical physics Examples include an exact solution of the Ising model and a connection between the Potts model on one hand and the chromatic and Tutte polynomials on the other hand See also Edit Mathematics portalCombinatorial biology Combinatorial chemistry Combinatorial data analysis Combinatorial game theory Combinatorial group theory Discrete mathematics List of combinatorics topics Phylogenetics Polynomial method in combinatoricsNotes Edit Bjorner and Stanley p 2 Lovasz Laszlo 1979 Combinatorial Problems and Exercises North Holland ISBN 9780821842621 Archived from the original on 2021 04 16 Retrieved 2021 03 23 In my opinion combinatorics is now growing out of this early stage Pak Igor What is Combinatorics Archived from the original on 17 October 2017 Retrieved 1 November 2017 Ryser 1963 p 2 Mirsky Leon 1979 Book Review PDF Bulletin of the American Mathematical Society New Series 1 380 388 doi 10 1090 S0273 0979 1979 14606 8 archived PDF from the original on 2021 02 26 retrieved 2021 02 04 Rota Gian Carlo 1969 Discrete Thoughts Birkhauser p 50 doi 10 1007 978 0 8176 4775 9 ISBN 978 0 8176 4775 9 combinatorial theory has been the mother of several of the more active branches of today s mathematics which have become independent The typical case of this is algebraic topology formerly known as combinatorial topology Acerbi F 2003 On the shoulders of Hipparchus Archive for History of Exact Sciences 57 6 465 502 doi 10 1007 s00407 003 0067 0 S2CID 122758966 Archived from the original on 2022 01 23 Retrieved 2021 03 12 Stanley Richard P Hipparchus Plutarch Schroder and Hough American Mathematical Monthly 104 1997 no 4 344 350 Habsieger Laurent Kazarian Maxim Lando Sergei 1998 On the Second Number of Plutarch The American Mathematical Monthly 105 5 446 doi 10 1080 00029890 1998 12004906 Netz R Acerbi F Wilson N Towards a reconstruction of Archimedes Stomachion Sciamvs 5 67 99 Archived from the original on 2021 04 16 Retrieved 2021 03 12 Hogendijk Jan P 1986 Arabic Traces of Lost Works of Apollonius Archive for History of Exact Sciences 35 3 187 253 doi 10 1007 BF00357307 ISSN 0003 9519 JSTOR 41133783 S2CID 121613986 Archived from the original on 2021 04 18 Retrieved 2021 03 26 Huxley G 1967 Okytokion Greek Roman and Byzantine Studies 8 3 203 Archived from the original on 2021 04 16 Retrieved 2021 03 26 O Connor John J Robertson Edmund F Combinatorics MacTutor History of Mathematics archive University of St Andrews Puttaswamy Tumkur K 2000 The Mathematical Accomplishments of Ancient Indian Mathematicians In Selin Helaine ed Mathematics Across Cultures The History of Non Western Mathematics Netherlands Kluwer Academic Publishers p 417 ISBN 978 1 4020 0260 1 Archived from the original on 2021 04 16 Retrieved 2015 11 15 Biggs Norman L 1979 The Roots of Combinatorics Historia Mathematica 6 2 109 136 doi 10 1016 0315 0860 79 90074 0 Maistrov L E 1974 Probability Theory A Historical Sketch Academic Press p 35 ISBN 978 1 4832 1863 2 archived from the original on 2021 04 16 retrieved 2015 01 25 Translation from 1967 Russian ed White Arthur T 1987 Ringing the Cosets The American Mathematical Monthly 94 8 721 746 doi 10 1080 00029890 1987 12000711 White Arthur T 1996 Fabian Stedman The First Group Theorist The American Mathematical Monthly 103 9 771 778 doi 10 1080 00029890 1996 12004816 See Journals in Combinatorics and Graph Theory Archived 2021 02 17 at the Wayback Machine Sanders Daniel P 2 Digit MSC Comparison Archived 2008 12 31 at the Wayback Machine Stinson 2003 pg 1 Andreas Blass Combinatorial Cardinal Characteristics of the Continuum Chapter 6 in Handbook of Set Theory edited by Matthew Foreman and Akihiro Kanamori Springer 2010 Eisworth Todd 2010 Foreman Matthew Kanamori Akihiro eds Successors of Singular Cardinals Handbook of Set Theory Dordrecht Springer Netherlands pp 1229 1350 doi 10 1007 978 1 4020 5764 9 16 ISBN 978 1 4020 4843 2 retrieved 2022 08 27 Continuous and profinite combinatorics PDF Archived PDF from the original on 2009 02 26 Retrieved 2009 01 03 References EditBjorner Anders and Stanley Richard P 2010 A Combinatorial Miscellany Bona Miklos 2011 A Walk Through Combinatorics 3rd Edition ISBN 978 981 4335 23 2 978 981 4460 00 2 Graham Ronald L Groetschel Martin and Lovasz Laszlo eds 1996 Handbook of Combinatorics Volumes 1 and 2 Amsterdam NL and Cambridge MA Elsevier North Holland and MIT Press ISBN 0 262 07169 X Lindner Charles C and Rodger Christopher A eds 1997 Design Theory CRC Press 1st edition 1997 ISBN 0 8493 3986 3 Riordan John 2002 1958 An Introduction to Combinatorial Analysis Dover ISBN 978 0 486 42536 8 Ryser Herbert John 1963 Combinatorial Mathematics The Carus Mathematical Monographs 14 The Mathematical Association of America Stanley Richard P 1997 1999 Enumerative Combinatorics Volumes 1 and 2 Cambridge University Press ISBN 0 521 55309 1 0 521 56069 1 Stinson Douglas R 2003 Combinatorial Designs Constructions and Analysis New York Springer ISBN 0 387 95487 2 van Lint Jacobus H and Wilson Richard M 2001 A Course in Combinatorics 2nd Edition Cambridge University Press ISBN 0 521 80340 3External links EditCombinatorics at Wikipedia s sister projects Definitions from Wiktionary Media from Commons Quotations from Wikiquote Textbooks from Wikibooks Combinatorial analysis Encyclopedia of Mathematics EMS Press 2001 1994 Combinatorial Analysis an article in Encyclopaedia Britannica Eleventh Edition Combinatorics a MathWorld article with many references Combinatorics from a MathPages com portal The Hyperbook of Combinatorics a collection of math articles links The Two Cultures of Mathematics by W T Gowers article on problem solving vs theory building Glossary of Terms in Combinatorics List of Combinatorics Software and Databases Retrieved from https en wikipedia org w index php title Combinatorics amp oldid 1142506872, wikipedia, wiki, book, books, library,

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