Mathematics

Mathematics is the study of quantity, structure, space and change. It developed, through the use of abstraction and logical reasoning, from counting, calculation, measurement, and the study of the shapes and motions of physical objects.
Mathematics is also used to refer to the insight gained by mathematicians by doing mathematics, also known as the body of mathematical knowledge. This latter meaning of mathematics includes the mathematics used to do calculations and is an indispensable tool in the natural sciences and engineering.
Contents 
History
The evolution of mathematics can be seen to be an ever increasing series of abstractions. The first abstraction was probably that of numbers. The realization that two apples and two oranges do have something in common, namely that they fill the hands of exactly one person, was a breakthrough in human thought. In addition to recognizing how to count concrete objects, prehistoric peoples also recognized how to count abstract quantities, like time  days, seasons, years. From counting, naturally followed arithmetic (e.g. addition, subtraction, multiplication and division).
However, mathematics undoubtedly could not have developed out of simple counting and arithmetic without writing and a way of writing numbers. Perhaps prehistoric peoples first expressed quantity by drawing lines in the ground or scratching wood.
Historically, the major disciplines within mathematics arose out of the need to do calculations in commerce, to measure land and to predict astronomical events. These three needs can be roughly related to the broad subdivision of mathematics into the studies of structure, space and change.
Inspiration, aesthetics and pure and applied mathematics
Mathematics arises wherever there are difficult problems that merit careful mental investigation. At first these were found in commerce, land measurement and later astronomy. Nowadays, mathematics derives much inspiration from the natural sciences and it is not uncommon for new mathematics to be pioneered by physicists, although it may need to be recast into more rigorous language. Some notable examples of this happening are Newton inventing calculus and Feynman inventing his Feynman path integral, but it also happens with results from string theory. The mathematics arising from this immediately has relevance for the subject which inspired it and can be applied to solve problems in that subject. Mathematics which can be so used is called applied mathematics as opposed to pure mathematics. In this way applied mathematics is an indispensable tool. With the increase in our mathematical knowledge, mathematics itself has become a source of inspiration. Mathematics is inspiring to mathematicians because it has some intrinsic aesthetics or inner beauty, which is hard to explain. Mathematicians value especially simplicity and generality and when these seemingly incompatible properties combine in a piece of mathematics, as in a unifying generalization for several subfields, or in a helpful tool for common calculations, often that piece of mathematics is called beautiful. Since the result of mathematics inspired by mathematics is often pure mathematics and thus has no applications outside of mathematics yet, the only value it has is in its aesthetics. Surprisingly often, it has happened that pure mathematics, which was considered only of interest to mathematics, has become applied mathematics because of some new insight, as if it anticipated later needs.
Notation, language and rigor
Main article: Mathematical notation
Mathematicians strive to be as clear as possible in the things they say and especially in the things they write, something which mathematicians refer to as rigor. To accomplish rigor, mathematicians have extended natural language with precisely defined vocabulary and grammar for referring to mathematical objects and stating certain common relations, with accompanying notation. Some of the terms they use also have a meaning outside of mathematics, such as ring, group and category, but some are specific to mathematics, such as homotopy and Hilbert space.
Even so, in the past it sometimes happened that something which had supposedly been proved turned out to be false. This was possible because mathematics was done using natural language. To prevent this from happening, mathematicians wanted their theorems to follow mechanically from a few simple incontrovertible truths and for this they invented axioms and axiomatic reasoning.
An axiom is just a string of symbols which have an intrinsic meaning because of all derivable formulas. It was the goal of Hilbert's program to put all of mathematics on a firm axiomatic basis, but according to G?'s incompleteness theorem every (strong enough) axiom system has undecidable formulas so a final axiomatization of mathematics is unavailable. Nonetheless mathematics is often imagined to be nothing but set theory in some axiomatization, in the sense that every mathematical statement or proof could be cast into formulas within set theory. But for most of mathematics this complete rigor is far too cumbersome and mathematical language and notation are supposed to suffice.
Queen of science
Albert Einstein referred to the subject as the Queen of the Sciences in his book Ideas and Opinions, a phrase first used by Carl Friedrich Gauss. Both followed by centuries St Thomas Aquinas' "Philosophy is the handmaiden of theology and theology is queen of the sciences". If one considers science to be strictly empirical, then mathematics itself is not a science. That is, mathematical knowledge exists separate from the physical world.
Mathematics shares much in common with the sciences. Experimentation plays a large role in the formulation of reasonable conjectures, and therefore is not by any means excluded from use by research mathematicians. However, theorems are only accepted if proofs have been found for them.
Overview of fields of mathematics
The major disciplines within mathematics first arose out of the need to do calculations in commerce, to measure land and to predict astronomical events. These three needs can be roughly related to the broad subdivision of mathematics into the study of structure, space and change (i.e. algebra, geometry and analysis). In addition to these three main concerns, there are also subdivisions dedicated to exploring links from the heart of mathematics to other fields: to logic and other simpler systems (foundations) and to the empirical systems of the various sciences (applied mathematics).
The study of structure starts with numbers, first the familiar natural numbers and integers and their arithmetical operations, which are recorded in elementary algebra. The deeper properties of whole numbers are studied in number theory. The investigation of methods to solve equations leads to the field of abstract algebra, which, among other things, studies rings and fields, structures that generalize the properties possessed by everyday numbers. Long standing questions about rulerandcompass constructions were finally settled by Galois theory. The physically important concept of vectors, generalized to vector spaces and studied in linear algebra, belongs to the two branches of structure and space.
The study of space originates with geometry, first the Euclidean geometry and trigonometry of familiar threedimensional space (also applying to both more and fewer dimensions), later also generalized to nonEuclidean geometries which play a central role in general relativity. The modern fields of differential geometry and algebraic geometry generalize geometry in different directions: differential geometry emphasizes the concepts of functions, fiber bundles, derivatives, smoothness, and direction, while in algebraic geometry geometrical objects are described as solution sets of polynomial equations. Group theory investigates the concept of symmetry abstractly; topology, the greatest growth area in the twentieth century, has a focus on the concept of continuity. Both the group theory of Lie groups and topology reveal the intimate connections of space, structure and change.
Understanding and describing change in measurable quantities is the common theme of the natural sciences, and calculus was developed as a most useful tool for that. The central concept used to describe a changing variable is that of a function. Many problems lead quite naturally to relations between a quantity and its rate of change, and the methods to solve these are studied in the field of differential equations. The numbers used to represent continuous quantities are the real numbers, and the detailed study of their properties and the properties of realvalued functions is known as real analysis. For several reasons, it is convenient to generalise to the complex numbers which are studied in complex analysis. Functional analysis focuses attention on (typically infinitedimensional) spaces of functions, laying the groundwork for quantum mechanics among many other things. Many phenomena in nature can be described by dynamical systems; chaos theory makes precise the ways in which many of these systems exhibit unpredictable yet still deterministic behavior.
In order to clarify the foundations of mathematics, the fields first of set theory and then mathematical logic were developed. Mathematical logic, which divides into recursion theory, model theory and proof theory, is now closely linked to computer science. When electronic computers were first conceived, several essential theoretical concepts were shaped by mathematicians, leading to the fields of computability theory, computational complexity theory, and information theory. Many of those topics are now investigated in theoretical computer science. Discrete mathematics is the common name for the fields of mathematics most generally useful in computer science.
An important field in applied mathematics is statistics, which uses probability theory as a tool and allows the description, analysis and prediction of phenomena where chance plays a part. It is used in all sciences. Numerical analysis investigates methods for efficiently solving a broad range of mathematical problems numerically on computers, beyond human capacities, and taking rounding errors and other sources of error into account to obtain credible answers.
Major themes in mathematics
An alphabetical and subclassified list of mathematical topics is available. The following list of themes and links gives just one possible view. For a fuller treatment, see Areas of mathematics or the list of lists of mathematical topics.
Quantity
This starts from explicit measurements of sizes of numbers or sets, or ways to find such measurements.
<math>1, 2, \ldots<math> <math>0, 1, 1, \ldots<math> <math>\frac{1}{2}, \frac{2}{3}, 0.125,\ldots<math> <math>\pi, e, \sqrt{2},\ldots<math> <math>i, 3i+2, e^{i\pi/3},\ldots<math> Natural numbers Integers Rational numbers Real numbers Complex numbers
 Number – Natural number – Integers – Rational numbers – Real numbers – Complex numbers – Hypercomplex numbers – Quaternions – Octonions – Sedenions – Hyperreal numbers – Surreal numbers – Ordinal numbers – Cardinal numbers – padic numbers – Integer sequences – Mathematical constants – Number names – Infinity – Base
Change
 Ways to express and handle change in mathematical functions, and changes between numbers.
<math>36 \div 9 = 4<math> <math>\int 1_S\,d\mu=\mu(S)<math> Arithmetic Calculus Vector calculus Analysis <math>\frac{d^2}{dx^2} y = \frac{d}{dx} y + c<math> Differential equations Dynamical systems Chaos theory
 Arithmetic – Calculus – Vector calculus – Analysis – Differential equations – Dynamical systems – Chaos theory – List of functions
Structure
Pinning down ideas of size, symmetry, and mathematical structure.
 Abstract algebra – Number theory – Algebraic geometry – Group theory – Monoids – Analysis – Topology – Linear algebra – Graph theory – Universal algebra – Category theory – Order theory – Measure theory
Spatial relations
 A more visual approach to mathematics.
Missing image
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Topology Geometry Trigonometry Differential geometry Fractal geometry
 Topology – Geometry – Trigonometry – Algebraic geometry – Differential geometry – Differential topology – Algebraic topology – Linear algebra – Fractal geometry
Discrete mathematics
 Discrete mathematics involves techniques that apply to objects that can only take on specific, separated values.
Applied mathematics
 Applied mathematics uses the full knowledge of mathematics to solve realworld problems.
 Mechanics – Numerical analysis – Optimization – Probability – Statistics – Financial mathematics – Game theory – Mathematical biology – Cryptography – Information theory – Fluid dynamics
Famous theorems and conjectures
 These theorems have interested mathematicians and nonmathematicians alike.
 Pythagorean theorem – Fermat's last theorem – Goldbach's conjecture – Twin Prime Conjecture – G?'s incompleteness theorems – Poincar頣onjecture – Cantor's diagonal argument – Four color theorem – Zorn's lemma – Euler's identity – ChurchTuring thesis
Important theorems and conjectures
See list of theorems, list of conjectures for more
 These are theorems and conjectures that have changed the face of mathematics throughout history.
 Riemann hypothesis – Continuum hypothesis – P=NP – Pythagorean theorem – Central limit theorem – Fundamental theorem of calculus – Fundamental theorem of algebra – Fundamental theorem of arithmetic – Fundamental theorem of projective geometry – classification theorems of surfaces – GaussBonnet theorem
Foundations and methods
 Approaches to understanding the nature of mathematics also influence the way mathematicians study their subject.
 Philosophy of mathematics – Mathematical intuitionism – Mathematical constructivism – Foundations of mathematics – Set theory – Symbolic logic – Model theory – Category theory – Logic – Reverse Mathematics – Table of mathematical symbols
History and the world of mathematicians
See also list of mathematics history topics
 History of mathematics – Timeline of mathematics – Mathematicians – Fields medal – Abel Prize – Millennium Prize Problems (Clay Math Prize) – International Mathematical Union – Mathematics competitions – Lateral thinking – Mathematical abilities and gender issues
Mathematics and other fields
Common misconceptions
Mathematics is not a closed intellectual system, in which everything has already been worked out. There is no shortage of open problems.
Pseudomathematics is a form of mathematicslike activity undertaken outside academia: and occasionally by mathematicians themselves. It often consists of determined attacks on famous questions, consisting of proofattempts made in an isolated way (that is, long papers not supported by previously published theory). The relationship to generallyaccepted mathematics is similar to that between pseudoscience and real science. The misconceptions involved are normally based on:
 misunderstanding of the implications of mathematical rigour;
 attempts to get round the usual criteria for publication of mathematical papers in a learned journal after peer review, with assumptions of bias;
 lack of familiarity with, and therefore underestimation of, the existing literature.
The case of Kurt Heegner's work shows that the mathematical establishment is neither infallible, nor unwilling to admit error in assessing 'amateur' work. And like astronomy, mathematics owes much to amateur contributors such as Fermat and Mersenne.
Mathematics is not accountancy. Although arithmetic computation is crucial to accountants, their main concern is to verify that computations are correct through a system of doublechecks. Advances in abstract mathematics are mostly irrelevant to the efficiency of concrete bookkeeping, but the use of computers clearly does matter.
Mathematics is not numerology. Numerology uses modular arithmetic to reduce names and dates down to numbers, but assigns emotions or traits to these numbers intuitively or on the basis of traditions.
Math Worksheets
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Math Activities
Math Clipart
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See also
Bibliography
 Benson, Donald C., The Moment Of Proof: Mathematical Epiphanies (1999).
 Courant, R. and H. Robbins, What Is Mathematics? (1941);
 Davis, Philip J. and Hersh, Reuben, The Mathematical Experience. Birkh䵳er, Boston, Mass., 1980. A gentle introduction to the world of mathematics.
 Boyer, Carl B., History of Mathematics, Wiley, 2nd edition 1998 available, 1st edition 1968 . A concise history of mathematics from the Concept of Number to contemporary Mathematics.
 Gullberg, Jan, MathematicsFrom the Birth of Numbers. W.W. Norton, 1996. An encyclopedic overview of mathematics presented in clear, simple language.
 Hazewinkel, Michiel (ed.), Encyclopaedia of Mathematics. Kluwer Academic Publishers 2000. A translated and expanded version of a Soviet math encyclopedia, in ten (expensive) volumes, the most complete and authoritative work available. Also in paperback and on CDROM.
 Kline, M., Mathematical Thought from Ancient to Modern Times (1973).
 Pappas, Theoni, The Joy Of Mathematics (1989).