Branches of Mathematics
Foundations
The term foundations is used to refer to the formulation and analysis of the language, axioms, and logical methods on which all of mathematics rests (see logic logic, the systematic study of valid inference. A distinction is drawn between logical validity and truth. Validity merely refers to formal properties of the process of inference.
..... Click the link for more information. ; symbolic logic symbolic logic or mathematical logic, formalized system of deductive logic, employing abstract symbols for the various aspects of natural language.
..... Click the link for more information. ). The scope and complexity of modern mathematics requires a very fine analysis of the formal language in which meaningful mathematical statements may be formulated and perhaps be proved true or false. Most apparent mathematical contradictions have been shown to derive from an imprecise and inconsistent use of language. A basic task is to furnish a set of axioms axiom, in mathematics and logic, general statement accepted without proof as the basis for logically deducing other statements (theorems). Examples of axioms used widely in mathematics are those related to equality (e.g.
..... Click the link for more information. effectively free of contradictions and at the same time rich enough to constitute a deductive source for all of modern mathematics. The modern axiom schemes proposed for this purpose are all couched within the theory of sets set, in mathematics, collection of entities, called elements of the set, that may be real objects or conceptual entities. Set theory not only is involved in many areas of mathematics but has important applications in other fields as well, e.g.
..... Click the link for more information. , originated by Georg Cantor, which now constitutes a universal mathematical language.
Algebra
Historically, algebra algebra, branch of mathematics concerned with operations on sets of numbers or other elements that are often represented by symbols. Algebra is a generalization of arithmetic and gains much of its power from dealing symbolically with elements and operations (such as
..... Click the link for more information. is the study of solutions of one or several algebraic equations, involving the polynomial polynomial, mathematical expression which is a finite sum, each term being a constant times a product of one or more variables raised to powers. With only one variable the general form of a polynomial is a0xn+a
..... Click the link for more information. functions of one or several variables. The case where all the polynomials have degree one (systems of linear equations) leads to linear algebra. The case of a single equation, in which one studies the roots of one polynomial, leads to field theory and to the so-called Galois theory. The general case of several equations of high degree leads to algebraic geometry, so named because the sets of solutions of such systems are often studied by geometric methods.
Modern algebraists have increasingly abstracted and axiomatized the structures and patterns of argument encountered not only in the theory of equations, but in mathematics generally. Examples of these structures include groups group, in mathematics, system consisting of a set of elements and a binary operation a+b defined for combining two elements such that the following requirements are satisfied: (1) The set is closed under the operation; i.e.
..... Click the link for more information. (first witnessed in relation to symmetry properties of the roots of a polynomial and now ubiquitous throughout mathematics), rings ring, in mathematics, system consisting of a set R of elements and two binary operations, such that addition makes R a commutative group and multiplication is associative and distributes over addition (see commutative law ; associative law ;
..... Click the link for more information. (of which the integers, or whole numbers, constitute a basic example), and fields field, in algebra, set of elements (usually numbers) that may be combined under the operations of addition and multiplication so that it constitutes an additive group , the nonzero elements form a multiplicative group, and multiplication distributes over addition.
..... Click the link for more information. (of which the rational, real, and complex numbers are examples). Some of the concepts of modern algebra have found their way into elementary mathematics education in the so-called new mathematics.
Some important abstractions recently introduced in algebra are the notions of category and functor, which grew out of so-called homological algebra. Arithmetic arithmetic, branch of mathematics commonly considered a separate branch but in actuality a part of algebra . Conventionally the term has been most widely applied to simple teaching of the skills of dealing with Numbers for practical purposes, e.g.
..... Click the link for more information. and number theory number theory, branch of mathematics concerned with the properties of the integers (the numbers 0, 1, −1, 2, −2, 3, −3, …). An important area in number theory is the analysis of prime numbers.
..... Click the link for more information. , which are concerned with special properties of the integers—e.g., unique factorization, primes, equations with integer coefficients (Diophantine equations), and congruences—are also a part of algebra. Analytic number theory, however, also applies the nonalgebraic methods of analysis to such problems.
Analysis
The essential ingredient of analysis analysis, branch of mathematics that utilizes the concepts and methods of the calculus . It includes not only basic calculus, but also advanced calculus, in which such underlying concepts as that of a limit are subjected to rigorous examination; differential and
..... Click the link for more information. is the use of infinite processes, involving passage to a limit limit, in mathematics, value approached by a sequence or a function as the index or independent variable approaches some value, possibly infinity. For example, the terms of the sequence 1-2, 1-4, 1-8, 1-16, … are obviously getting smaller and smaller; since,
..... Click the link for more information. . For example, the area of a circle may be computed as the limiting value of the areas of inscribed regular polygons as the number of sides of the polygons increases indefinitely. The basic branch of analysis is the calculus calculus, branch of mathematics that studies continuously changing quantities. The calculus is characterized by the use of infinite processes, involving passage to a limit —the notion of tending toward, or approaching, an ultimate value.
..... Click the link for more information. . The general problem of measuring lengths, areas, volumes, and other quantities as limits by means of approximating polygonal figures leads to the integral calculus. The differential calculus arises similarly from the problem of finding the tangent line to a curve at a point. Other branches of analysis result from the application of the concepts and methods of the calculus to various mathematical entities. For example, vector U [−3,1] and V [5,2], one can add their corresponding components to find the resultant vector R [2,3], or one can graph U and V on a set of coordinate axes and complete the parallelogram formed with U and V
..... Click the link for more information. analysis is the calculus of functions whose variables are vectors. Here various types of derivatives and integrals may be introduced. They lead, among other things, to the theory of differential and integral equations, in which the unknowns are functions rather than numbers, as in algebraic equations. Differential equations are often the most natural way in which to express the laws governing the behavior of various physical systems. Calculus is one of the most powerful and supple tools of mathematics. Its applications, both in pure mathematics and in virtually every scientific domain, are manifold.
Geometry
The shape, size, and other properties of figures and the nature of space are in the province of geometry. Euclidean geometry geometry [Gr.,=earth measuring], branch of mathematics concerned with the properties of and relationships between points, lines, planes, and figures and with generalizations of these concepts.
..... Click the link for more information. is concerned with the axiomatic study of polygons, conic sections, spheres, polyhedra, and related geometric objects in two and three dimensions—in particular, with the relations of congruence and of similarity between such objects. The unsuccessful attempt to prove the "parallel postulate" from the other axioms of Euclid led in the 19th cent. to the discovery of two different types of non-Euclidean geometry non-Euclidean geometry, branch of geometry in which the fifth postulate of Euclidean geometry, which allows one and only one line parallel to a given line through a given external point, is replaced by one of two alternative postulates.
..... Click the link for more information. .
The 20th cent. has seen an enormous development of topology topology, branch of mathematics , formerly known as analysis situs, that studies patterns of geometric figures involving position and relative position without regard to size.
..... Click the link for more information. , which is the study of very general geometric objects, called topological spaces, with respect to relations that are much weaker than congruence and similarity. Other branches of geometry include algebraic geometry and differential geometry r moves along a curve at arc length s from some fixed point, then t = dr/ds is a unit tangent vector to the curve at r. The normal vector n
..... Click the link for more information. , in which the methods of analysis are brought to bear on geometric problems. These fields are now in a vigorous state of development.
Applied Mathematics
The term applied mathematics loosely designates a wide range of studies with significant current use in the empirical sciences. It includes numerical methods and computer computer, device capable of performing a series of arithmetic or logical operations. A computer is distinguished from a calculating machine, such as an electronic calculator , by being able to store a computer program (so that it can repeat its operations and make
..... Click the link for more information. science, which seeks concrete solutions, sometimes approximate, to explicit mathematical problems (e.g., differential equations, large systems of linear equations). It has a major use in technology for modeling and simulation. For example, the huge wind tunnels wind tunnel, apparatus for studying the interaction between a solid body and an airstream. A wind tunnel simulates the conditions of an aircraft in flight by causing a high-speed stream of air to flow past a model of the aircraft (or part of an aircraft) being tested.
..... Click the link for more information. , formerly used to test expensive prototypes of airplanes, have all but disappeared. The entire design and testing process is now largely carried out by computer simulation, using mathematically tailored software. It also includes mathematical physics, which now strongly interacts with all of the central areas of mathematics. In addition, probability probability, in mathematics, assignment of a number as a measure of the "chance" that a given event will occur. There are certain important restrictions on such a probability measure.
..... Click the link for more information. theory and mathematical statistics statistics, science of collecting and classifying a group of facts according to their relative number and determining certain values that represent characteristics of the group.
..... Click the link for more information. are often considered parts of applied mathematics. The distinction between pure and applied mathematics is now becoming less significant.
Development of Mathematics
The earliest records of mathematics show it arising in response to practical needs in agriculture, business, and industry. In Egypt and Mesopotamia, where evidence dates from the 2d and 3d millennia B.C., it was used for surveying and mensuration; estimates of the value of π (pi pi, in mathematics, the ratio of the circumference of a circle to its diameter. The symbol for pi is π. The ratio is the same for all circles and is approximately 3.1416.
..... Click the link for more information. ) are found in both locations. There is some evidence of similar developments in India and China during this same period, but few records have survived. This early mathematics is generally empirical, arrived at by trial and error as the best available means for obtaining results, with no proofs given. However, it is now known that the Babylonians were aware of the necessity of proofs prior to the Greeks, who had been presumed the originators of this important step.
Greek Contributions
A profound change occurred in the nature and approach to mathematics with the contributions of the Greeks. The earlier (Hellenic) period is represented by Thales Thales (thā`lēz), c.636–c.546 B.C.
..... Click the link for more information. (6th cent. B.C.), Pythagoras Pythagoreans are best known for two teachings: the transmigration of souls and the theory that numbers constitute the true nature of things. The believers performed purification rites and followed moral, ascetic, and dietary rules to enable their souls to achieve a higher rank in
..... Click the link for more information. , Plato Plato (plā`tō), 427?–347 B.C., Greek philosopher.
..... Click the link for more information. , and Aristotle Aristotle (ăr'ĭstŏt`əl), 384–322 B.C., Greek philosopher, b. Stagira. He is sometimes called the Stagirite.
..... Click the link for more information. , and by the schools associated with them. The Pythagorean theorem, known earlier in Mesopotamia, was discovered by the Greeks during this period.
During the Golden Age (5th cent. B.C.), Hippocrates of Chios made the beginnings of an axiomatic approach to geometry and Zeno of Elea Zeno of Elea (zē`nō, ē`lēə), c.490–c.430 B.C., Greek philosopher of the Eleatic school .
..... Click the link for more information. proposed his famous paradoxes concerning the infinite and the infinitesimal, raising questions about the nature of and relationships among points, lines, and numbers. The discovery through geometry of irrational numbers, such as 2, also dates from this period. Eudoxus of Cnidus Eudoxus of Cnidus (y
dŏk`səs, nī`dəs), 408?–355? B.C.
..... Click the link for more information. (4th cent. B.C.) resolved certain of the problems by proposing alternative methods to those involving infinitesimals; he is known for his work on geometric proportions and for his exhaustion theory for determining areas and volumes.
The later (Hellenistic) period of Greek science is associated with the school of Alexandria. The greatest work of Greek mathematics, Euclid Euclid (y`klĭd), fl. 300 B.C., Greek mathematician.
..... Click the link for more information. 's Elements (c.300 B.C.), appeared at the beginning of this period. Elementary geometry as taught in high school is still largely based on Euclid's presentation, which has served as a model for deductive systems in other parts of mathematics and in other sciences. In this method primitive terms, such as point and line, are first defined, then certain axioms and postulates relating to them and seeming to follow directly from them are stated without proof; a number of statements are then derived by deduction from the definitions, axioms, and postulates. Euclid also contributed to the development of arithmetic and presented a geometric theory of quadratic equations.
In the 3d cent. B.C., Archimedes Archimedes (ärkĭmē`dēz), 287–212 B.C., Greek mathematician, physicist, and inventor.
..... Click the link for more information. , in addition to his work in mechanics, made an estimate of π and used the exhaustion theory of Eudoxus to obtain results that foreshadowed those much later of the integral calculus, and Apollonius of Perga Apollonius of Perga, fl. 247–205 B.C., Greek mathematician of the Alexandrian school. He produced a treatise on conic sections that included, as well as his own work, much of the work of his predecessors, among whom was Euclid.
..... Click the link for more information. named the conic sections and gave the first theory for them. A second Alexandrian school of the Roman period included contributions by Menelaus (c.A.D. 100, spherical triangles), Heron of Alexandria Heron of Alexandria (hēr`ŏn) or Hero, mathematician and inventor.
..... Click the link for more information. (geometry), Ptolemy Ptolemy (Claudius Ptolemaeus), fl. 2d cent. A.D., celebrated Greco-Egyptian mathematician, astronomer, and geographer. He made his observations in Alexandria and was the last great astronomer of ancient times.
..... Click the link for more information. (A.D. 150, astronomy, geometry, cartography), Pappus Pappus (păp`əs), fl. c.300, Greek mathematician of Alexandria.
..... Click the link for more information. (3d cent., geometry), and Diophantus Diophantus (dīəfăn`təs), fl. A.D. 250, Greek algebraist.
..... Click the link for more information. (3d cent., arithmetic).
Chinese and Middle Eastern Advances
Following the decline of learning in the West after the 3d cent., the development of mathematics continued in the East. In China, Tsu Ch'ung-Chih estimated π by inscribed and circumscribed polygons, as Archimedes had done, and in India the numerals now used throughout the civilized world were invented and contributions to geometry were made by Aryabhata Aryabhata (är'yəbhŭt`ə), c.476–550, Hindu mathematician and astronomer.
..... Click the link for more information. and Brahmagupta Brahmagupta (brä'məg
p`tə), c.598–c.
..... Click the link for more information. (5th and 6th cent. A.D.). The Arabs were responsible for preserving the work of the Greeks, which they translated, commented upon, and augmented. In Baghdad, Al-Khowarizmi Al-Khowarizmi (äl-khōwärēz`mē), fl. 820, Arab mathematician of the court of Mamun in Baghdad.
..... Click the link for more information. (9th cent.) wrote an important work on algebra and introduced the Hindu numerals for the first time to the West, and Al-Battani Al-Battani (äl-bät-tä`nē) or Albatenius
..... Click the link for more information. worked on trigonometry. In Egypt, Ibn al-Haytham Ibn al-Haytham (ĭb`ən äl-hīth-äm`) or Alhazen
..... Click the link for more information. was concerned with the solids of revolution and geometrical optics. The Persian poet Omar Khayyam wrote on algebra.
Western Developments from the Twelfth to Eighteenth Centuries
Word of the Chinese and Middle Eastern works began to reach the West in the 12th and 13th cent. One of the first important European mathematicians was Leonardo da Pisa (Leonardo Fibonacci Fibonacci, Leonardo (lāōnär`dō fēbōnät`chē), b. c.1170, d.
..... Click the link for more information. ), who wrote on arithmetic and algebra (Liber abaci, 1202) and on geometry (Practica geometriae, 1220). With the Renaissance came a great revival of interest in learning, and the invention of printing made many of the earlier books widely available. By the end of the 16th cent. advances had been made in algebra by Niccolò Tartaglia Tartaglia, Niccolò (nēk-kōlô` tärtä`lyä), c.1500–1557, Italian engineer and mathematician.
..... Click the link for more information. and Geronimo Cardano Cardano, Geronimo (jārô`nēmō kärdä`nō), 1501–76, Italian physician and mathematician.
..... Click the link for more information. , in trigonometry by François Viète Viète or Vieta, François
..... Click the link for more information. , and in such areas of applied mathematics as mapmaking by Mercator and others.
The 17th cent., however, saw the greatest revolution in mathematics, as the scientific revolution spread to all fields. Decimal fractions were invented by Simon Stevin Stevin, Simon (sē`môn stəvīn`), 1548–1620, Dutch engineer and mathematician.
..... Click the link for more information. and logarithms by John Napier Napier, John, 1550–1617, Scottish mathematician. He invented logarithms and wrote Mirifici logarithmorum canonis descriptio (1614), containing the first logarithmic table and the first use of the word logarithm.
..... Click the link for more information. and Henry Briggs Briggs, Henry, 1561–1630, English mathematician. He was the first professor of geometry at Gresham College, London (1596–1619), and Savilian professor of astronomy at Oxford (from 1619).
..... Click the link for more information. ; the beginnings of projective geometry were made by Gérard Desargues Desargues, Gérard (zhārär` dəzärg`)
..... Click the link for more information. and Blaise Pascal Pascal, Blaise (blĕz päskäl`), 1623–62, French scientist and religious philosopher.
..... Click the link for more information. ; number theory was greatly extended by Pierre de Fermat Fermat's Last Theorem, which states that the equation xn + yn = zn, where x, y, z, and n are nonzero integers, has no solutions for n that are greater than 2.
..... Click the link for more information. ; and the theory of probability was founded by Pascal, Fermat, and others. In the application of mathematics to mechanics and astronomy, Galileo Galileo (Galileo Galilei) (găl'ĭlē`ō; gälēlĕ`ō gälēlĕ`ē)
..... Click the link for more information. and Johannes Kepler Kepler, Johannes (yōhä`nəs kĕp`lər), 1571–1630, German astronomer. From his student days at the Univ.
..... Click the link for more information. made fundamental contributions.
The greatest mathematical advances of the 17th cent., however, were the invention of analytic geometry by René Descartes Descartes, René (rənā` dākärt`), Lat.
..... Click the link for more information. and that of the calculus by Isaac Newton Newton, Sir Isaac, 1642–1727, English mathematician and natural philosopher (physicist), who is considered by many the greatest scientist that ever lived.
..... Click the link for more information. and, independently, by G. W. Leibniz Leibniz or Leibnitz, Gottfried Wilhelm, Baron von
..... Click the link for more information. . Descartes's invention (anticipated by Fermat, whose work was not published until later) made possible the expression of geometric problems in algebraic form and vice versa. It was indispensable in creating the calculus, which built upon and superseded earlier special methods for finding areas, volumes, and tangents to curves, developed by F. B. Cavalieri Cavalieri, Francesco Bonaventura (fränchās`kō bōnävānt
..... Click the link for more information. , Fermat, and others. The calculus is probably the greatest tool ever invented for the mathematical formulation and solution of physical problems.
The history of mathematics in the 18th cent. is dominated by the development of the methods of the calculus and their application to such problems, both terrestrial and celestial, with leading roles being played by the Bernoulli Jacob, Jacques, or James Bernoulli, 1654–1705, became professor at Basel in 1687. One of the chief developers both of the ordinary calculus and of the calculus of variations , he was the first to use the word integral
..... Click the link for more information. family (especially Jakob, Johann, and Daniel), Leonhard Euler Euler, Leonhard (lā`ônhärt oi`lər), 1707–83, Swiss mathematician.
..... Click the link for more information. , Guillaume de L'Hôpital, and J. L. Lagrange Lagrange, Joseph Louis, Comte (zhôzĕf` lwē kôNt lägräNzh`)
..... Click the link for more information. . Important advances in geometry began toward the end of the century with the work of Gaspard Monge Monge, Gaspard, comte de Péluse (gäspär` môNzh kôNt də pālüz`)
..... Click the link for more information. in descriptive geometry and in differential geometry and continued through his influence on others, e.g., his pupil J. V. Poncelet Poncelet, Jean Victor (zhäN` vēktôr` pôNslā`), 1788–1867, French mathematician and army engineer.
..... Click the link for more information. , who founded projective geometry (1822).
In the Nineteenth Century
The modern period of mathematics dates from the beginning of the 19th cent., and its dominant figure is C. F. Gauss Gauss, Carl Friedrich (kärl frē`drĭkh gous)
..... Click the link for more information. . In the area of geometry Gauss made fundamental contributions to differential geometry, did much to found what was first called analysis situs but is now called topology, and anticipated (although he did not publish his results) the great breakthrough of non-Euclidean geometry. This breakthrough was made by N. I. Lobachevsky Lobachevsky, Nikolai Ivanovich (nyĭkəlī` ēvä`nəvĭch ləbəchĕf`skē)
..... Click the link for more information. (1826) and independently by János Bolyai Farkas, or Wolfgang, Bolyai, 1775–1856, b. Bolya, Transylvania, was educated in Nagyszeben from 1781 to 1796 and studied in Germany during the next three years at Jena and Göttingen, where he began a lifelong friendship with Carl
..... Click the link for more information. (1832), the son of a close friend of Gauss, whom each proceeded by establishing the independence of Euclid's fifth (parallel) postulate and showing that a different, self-consistent geometry could be derived by substituting another postulate in its place. Still another non-Euclidean geometry was invented by Bernhard Riemann Riemann, Bernhard (Georg Friedrich Bernhard Riemann) (gā`ôrk frē`drĭkh bĕrn`härt rē`män)
..... Click the link for more information. (1854), whose work also laid the foundations for the modern tensor calculus description of space, so important in the general theory of relativity.
In the area of arithmetic, number theory, and algebra, Gauss again led the way. He established the modern theory of numbers, gave the first clear exposition of complex numbers, and investigated the functions of complex variables. The concept of number was further extended by W. R. Hamilton Hamilton, Sir William Rowan, 1805–65, Irish mathematician and astronomer, b. Dublin. A child prodigy, he had mastered 13 languages by the age of 13 and was still an undergraduate when he became professor of astronomy at the Univ. of Dublin (1827).
..... Click the link for more information. , whose theory of quaternions (1843) provided the first example of a noncommutative algebra (i.e., one in which ab ≠ ba). This work was generalized the following year by H. G. Grassmann Grassmann, Hermann Günther (hĕr`män gün`tər gräs`män)
..... Click the link for more information. , who showed that several different consistent algebras may be derived by choosing different sets of axioms governing the operations on the elements of the algebra.
These developments continued with the group theory of M. S. Lie Lie, Marius Sophus (mä`rēs sō`f
..... Click the link for more information. in the late 19th cent. and reached full expression in the wide scope of modern abstract algebra. Number theory received significant contributions in the latter half of the 19th cent. through the work of Georg Cantor Cantor, Georg (gā`ôrkh kän`tôr), 1845–1918, German mathematician, b. St. Petersburg.
..... Click the link for more information. , J. W. R. Dedekind Dedekind, Julius Wilhelm Richard (yl`y
..... Click the link for more information. , and K. W. Weierstrass Weierstrass, Karl Wilhelm Theodor (kärl vĭl`hĕlm tā`ōdōr vī`ərshträs)
..... Click the link for more information. . Still another influence of Gauss was his insistence on rigorous proof in all areas of mathematics. In analysis this close examination of the foundations of the calculus resulted in A. L. Cauchy Cauchy, Augustin Louis, Baron (ōgüstăN` lwē bärôN` kōshē`), 1789–1857, French mathematician.
..... Click the link for more information. 's theory of limits (1821), which in turn yielded new and clearer definitions of continuity, the derivative, and the definite integral. A further important step toward rigor was taken by Weierstrass, who raised new questions about these concepts and showed that ultimately the foundations of analysis rest on the properties of the real number system.
In the Twentieth Century
In the 20th cent. the trend has been toward increasing generalization and abstraction, with the elements and operations of systems being defined so broadly that their interpretations connect such areas as algebra, geometry, and topology. The key to this approach has been the use of formal axiomatics, in which the notion of axioms as "self-evident truths" has been discarded. Instead the emphasis is on such logical concepts as consistency and completeness. The roots of formal axiomatics lie in the discoveries of alternative systems of geometry and algebra in the 19th cent.; the approach was first systematically undertaken by David Hilbert in his work on the foundations of geometry (1899).
The emphasis on deductive logic inherent in this view of mathematics and the discovery of the interconnections between the various branches of mathematics and their ultimate basis in number theory led to intense activity in the field of mathematical logic after the turn of the century. Rival schools of thought grew up under the leadership of Hilbert, Bertrand Russell Russell, Bertrand Arthur William Russell, 3d Earl, 1872–1970, British philosopher, mathematician, and social reformer, b. Trelleck, Wales.
..... Click the link for more information. and A. N. Whitehead Whitehead, Alfred North, 1861–1947, English mathematician and philosopher, grad. Trinity College, Cambridge, 1884. There he was a lecturer in mathematics until 1911. At the Univ.
..... Click the link for more information. , and L. E. J. Brouwer. Important contributions in the investigation of the logical foundations of mathematics were made by Kurt Gödel Gödel, Kurt (gö`dəl), 1906–78, American mathematician and logician, b. Brünn (now Brno, Czech Republic), grad. Univ.
..... Click the link for more information. and A. Church.
Bibliography
See R. Courant and H. Robbins, What Is Mathematics? (1941); E. T. Bell, The Development of Mathematics (2d ed. 1945) and Men of Mathematics (1937, repr. 1961); J. R. Newman, ed., The World of Mathematics (4 vol., 1956); E. E. Kramer, The Nature and Growth of Mathematics (1970); M. Kline, Mathematical Thought from Ancient to Modern Times (1973); D. J. Albers and G. L. Alexanderson, ed., Mathematical People (1985).
mathematics
Science of structure, order, and relation that has evolved from counting, measuring, and describing the shapes of objects. It deals with logical reasoning and quantitative calculation. Since the 17th century it has been an indispensable adjunct to the physical sciences and technology, to the extent that it is considered the underlying language of science. Among the principal branches of mathematics are algebra, analysis, arithmetic, combinatorics, Euclidean and non-Euclidean geometries, game theory, number theory, numerical analysis, optimization, probability, set theory, statistics, topology, and trigonometry.
mathematics
www.martindalecenter.com/GradMath.html
www.math.psu.edu/MathLists/Contents.html
http://carbon.cudenver.edu/~hgreenbe/glossary/index.php
mathematics [¦math·ə¦mad·iks]
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