Mathematics

Practical mathematics, in nearly every society, is used for such purposes as accounting, measuring land, or predicting astronomical events. Mathematical discovery or research often involves discovering and cataloging patterns, without regard for application. The remarkable fact that the "purest" mathematics often turns out to have practical applications is what Eugene Wigner has called "the unreasonable effectiveness of mathematics." Today, the natural sciences, Engineering, Economics, and Medicine depend heavily on new mathematical discoveries.

The word "mathematics" comes from the Greek μάθημα (máthema) meaning "science, knowledge, or learning" and μαθηματικός (mathematikós) meaning "fond of learning". It is often abbreviated maths in Commonwealth English and math in American English.

History

Main article: History of mathematics

The evolution of mathematics might be seen to be an ever-increasing series of abstractions, or alternatively an expansion of subject matter. 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. Arithmetic (e.g. Addition, Subtraction, Multiplication and division), naturally followed. Monolithic monuments testify to a knowledge of geometry.

Further steps need Writing or some other system for recording numbers such as tallies or the knotted strings called khipu used by the Inca Empire to store numerical data. Numeral systems have been many and diverse.

Historically, the major disciplines within mathematics arose, from the start of recorded history, out of the need to do calculations on taxation and commerce, to measure land and to predict astronomical events. These needs can be roughly related to the broad subdivision of mathematics, into the studies of number, space and change.

Mathematics since has been much extended, and there has been a fruitful interaction between mathematics and science, to the benefit of both.

Mathematical discoveries have been made throughout history and continue to be made today.

Inspiration, aesthetics, and pure and applied mathematics

Mathematics is relevant for the subject which inspired it, and can be applied to solve further problems in that same area. There is also mathematics that joins the general stock of concepts, and requires to be put on a 'common denominator' with existing ideas. During the nineteenth century this distinction hardened up, into Applied mathematics as opposed to Pure mathematics.

Mathematics interests mathematicians because of its elegance, the intrinsic Aesthetics or inner Beauty, which is hard for anyone to articulate. Simplicity and generality are valued. These seemingly incompatible properties may combine in a piece of mathematics: a unifying Generalization for several subfields, or a helpful tool for common calculations. Pure mathematics, it may seem, has value only in its beauty. But a part of mathematics, which was considered only of interest to mathematicians, has frequently later become applied mathematics because of some new insight or field of study opening up, as if it anticipated later needs.

Notation, language, and rigor

Main article: Mathematical notation

Mathematical writing is not easily accessible to the layperson. A Brief History of Time, Stephen Hawking's 1988 bestseller, contained a single mathematical equation. This was the author's compromise with the publisher's advice, that each equation would halve the sales.

The reasons for the inaccessibility even of carefully-expressed mathematics can be partially explained. Contemporary mathematicians strive to be as clear as possible in the things they say and especially in the things they write (this they have in common with lawyers). They refer to rigor. To accomplish rigor, mathematicians have extended Natural language. There is precisely-defined vocabulary for referring to mathematical objects, and stating certain common relations. There is an accompanying Mathematical notation, which like Musical notation has a definite content, and also has a strict Grammar (under the influence of Computer science, more often now called Syntax). Some of the terms used in mathematics are also common outside mathematics, such as ring, group and category; but are not such that one can infer the meanings. Some are specific to mathematics, such as Homotopy and Hilbert space. It was said that Henri Poincaré was only elected to the Académie française so that he could tell them how to define automorphe in their dictionary.

Rigor is fundamentally a matter of Mathematical proof. Mathematicians want their theorems to follow mechanically from axioms by means of formal axiomatic reasoning. This is to avoid mistaken 'theorems', based on fallible intuitions; of which plenty of examples have occurred in the history of the subject (for example, in Mathematical analysis).

Axioms in traditional thought were 'self-evident truths', but that conception turns out not to be workable in pushing the mathematical boundaries. At a formal level, an axiom is just a string of symbols, which has an intrinsic meaning only in the context of all derivable formulas of an Axiomatic system. It was the goal of Hilbert's program to put all of mathematics on a firm axiomatic basis, but according to Gödel's incompleteness theorem every (strong enough) axiom system has undecidable formulas; and so a final Axiomatization of mathematics is unavailable. Nonetheless mathematics is often imagined to be (as far as its formal content) nothing but Set theory in some axiomatization, in the sense that every mathematical statement or proof could be cast into formulas within set theory.

Is mathematics a science?

If one considers Science to be strictly about the physical world, then mathematics, or at least pure mathematics, is not a science. An alternative view is that certain scientific fields (such as theoretical physics) are mathematics with axioms that are intended to correspond to reality. In fact, the theoretical physicist, J. M. Ziman, proposed that science is public knowledge and thus includes mathematics.

In any case, mathematics shares much in common with many fields in the physical sciences, notably the exploration of the logical consequences of assumptions. Intuition and experimentation also play a role in the formulation of conjectures in both mathematics and the (other) sciences.

Overview of fields of mathematics

The study of structure starts with numbers, first the familiar natural numbers and integers and their arithmetical operations, which are characterized 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 ruler-and-compass 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 three-dimensional space (also applying to both more and fewer dimensions), later also generalized to non-Euclidean 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 real-valued functions is known as Real analysis. For several reasons, it is convenient to generalize to the complex numbers which are studied in Complex analysis. Functional analysis focuses attention on (typically infinite-dimensional) 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 Mathematical logic and then Set theory 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

Quantity

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