Linear algebra
From Wikipedia, the free encyclopedia
Linear algebra is the branch of mathematics concerned with the study of vectors, vector spaces (also called linear spaces), linear maps (also called linear transformations), and systems of linear equations. Vector spaces are a central theme in modern mathematics; thus, linear algebra is widely used in both abstract algebra and functional analysis. Linear algebra also has a concrete representation in analytic geometry and it is generalized in operator theory. It has extensive applications in the natural sciences and the social sciences, since nonlinear models can often be approximated by a linear one.
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[edit] History
The history of modern linear algebra dates back to the years 1843 and 1844. In 1843, William Rowan Hamilton (from whom the term vector stems) introduced the quaternions. In 1844, Hermann Grassmann published his book Die lineale Ausdehnungslehre (see References). Arthur Cayley introduced matrices, one of the most fundamental linear algebraic ideas, in 1857. These early references belie the fact that linear algebra is mainly a development of the twentieth century: the number-like objects called matrices were hard to place before the development of ring theory in abstract algebra. With the coming of special relativity many practitioners gained appreciation of the subtleties of linear algebra. Furthermore, the routine application of Cramer's rule to solve partial differential equations led to inclusion of linear algebra in standard coursework at universities. For instance, E.T. Copson wrote:
| “ | When I went to Edinburgh as a young lecturer in 1922, I was surprised to find how different the curriculum was from that at Oxford. It included topics such as Lebesgue integration, matrix theory, numerical analysis, Riemannian geometry, of which I knew nothing... | ” |
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—E.T. Copson, Preface to Partial Differential Equations, 1973 |
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Francis Galton initiated the use of correlation coefficients in 1888. Often more than one random variable is in play and they may be cross-correlated. In statistical analysis of multivariate random variables the correlation matrix is a natural tool. Thus statistical study of such random vectors helped develop matrix usage.
[edit] Elementary introduction
Linear algebra had its beginnings in the study of vectors in Cartesian 2-space and 3-space. A vector, here, is a directed line segment, characterized by both its magnitude, represented by length, and its direction. Vectors can be used to represent physical entities such as forces, and they can be added to each other and multiplied with scalars, thus forming the first example of a real vector space.
Modern linear algebra has been extended to consider spaces of arbitrary or infinite dimension. A vector space of dimension n is called an n-space. Most of the useful results from 2 and 3-space can be extended to these higher dimensional spaces. Although many people cannot easily visualize vectors in n-space, such vectors or n-tuples are useful in representing data. Since vectors, as n-tuples, are ordered lists of n components, it is possible to summarize and manipulate data efficiently in this framework. For example, in economics, one can create and use, say, 8-dimensional vectors or 8-tuples to represent the Gross National Product of 8 countries. One can decide to display the GNP of 8 countries for a particular year, where the countries' order is specified, for example, (United States, United Kingdom, France, Germany, Spain, India, Japan, Australia), by using a vector (v1, v2, v3, v4, v5, v6, v7, v8) where each country's GNP is in its respective position.
A vector space (or linear space), as a purely abstract concept about which theorems are proved, is part of abstract algebra, and is well integrated into this discipline. Some striking examples of this are the group of invertible linear maps or matrices, and the ring of linear maps of a vector space. Linear algebra also plays an important part in analysis, notably, in the description of higher order derivatives in vector analysis and the study of tensor products and alternating maps.
In this abstract setting, the scalars with which an element of a vector space can be multiplied need not be numbers. The only requirement is that the scalars form a mathematical structure, called a field. In applications, this field is usually the field of real numbers or the field of complex numbers. Linear maps take elements from a linear space to another (or to itself), in a manner that is compatible with the addition and scalar multiplication given on the vector space(s). The set of all such transformations is itself a vector space. If a basis for a vector space is fixed, every linear transform can be represented by a table of numbers called a matrix. The detailed study of the properties of and algorithms acting on matrices, including determinants and eigenvectors, is considered to be part of linear algebra.
One can say quite simply that the linear problems of mathematics - those that exhibit linearity in their behavior - are those most likely to be solved. For example differential calculus does a great deal with linear approximation to functions. The difference from nonlinear problems is very important in practice.
The general method of finding a linear way to look at a problem, expressing this in terms of linear algebra, and solving it, if need be by matrix calculations, is one of the most generally applicable in mathematics.
[edit] Some useful theorems
- Every vector space has a basis.[1]
- A matrix is invertible if and only if its determinant is nonzero.
- A matrix is invertible if and only if the linear map represented by the matrix is an isomorphism
- If a square matrix has a left inverse or a right inverse then it is invertible (see invertible matrix for other equivalent statements).
- A matrix is positive semidefinite if and only if each of its eigenvalues is greater than or equal to zero.
- A matrix is positive definite if and only if each of its eigenvalues is greater than zero.
- The spectral theorem (regarding diagonalizable matrices).
[edit] Generalisation and related topics
Since linear algebra is a successful theory, its methods have been developed in other parts of mathematics. In module theory one replaces the field of scalars by a ring. In multilinear algebra one deals with the 'several variables' problem of mappings linear in each of a number of different variables, inevitably leading to the tensor concept. In the spectral theory of operators control of infinite-dimensional matrices is gained, by applying mathematical analysis in a theory that is not purely algebraic. In all these cases the technical difficulties are much greater.
[edit] See also
[edit] Note
- ^ The existence of a basis straightforward for finitely generated vector spaces, but in full generality it is logically equivalent to the axiom of choice.
[edit] References
- Beezer, Rob, A First Course in Linear Algebra, licensed under GFDL.
- Fearnley-Sander, Desmond, Hermann Grassmann and the Creation of Linear Algebra, American Mathematical Monthly 86 (1979), pp. 809–817.
- Grassmann, Hermann, Die lineale Ausdehnungslehre ein neuer Zweig der Mathematik: dargestellt und durch Anwendungen auf die übrigen Zweige der Mathematik, wie auch auf die Statik, Mechanik, die Lehre vom Magnetismus und die Krystallonomie erläutert, O. Wigand, Leipzig, 1844.
- Jim Hefferon: Linear Algebra (Online textbook)
- Edwin H. Connell: Elements of Abstract and Linear Algebra (Online textbook)
[edit] External links
- MIT Linear Algebra Lectures: free videos from MIT OpenCourseWare
- Linear Algebra Toolkit.
- Linear Algebra Workbench: multiply and invert matrices, solve systems, eigenvalues etc.
- Linear Algebra on MathWorld.
- Linear Algebra overview and notation summary on PlanetMath.
- Matrix and Linear Algebra Terms on Earliest Known Uses of Some of the Words of Mathematics
- Linear Algebra by Elmer G. Wiens. Interactive web pages for vectors, matrices, linear equations, etc.
- Linear Algebra Solved Problems: Interactive forums for discussion of linear algebra problems, from the lowest up to the hardest level (Putnam).
- Linear Algebra for Informatics. José Figueroa-O'Farrill, University of Edinburgh
- Linear Algebra by Jim Hefferon: A free textbook with exercises and a solutions guide written by a professor at Saint Michael's College.
- Online Notes / Linear Algebra Paul Dawkins, Lamar University
- Elementary Linear Algebra textbook with solutions
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Major fields of mathematics
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| Logic • Set theory • Algebra (Abstract algebra - Linear algebra) • Discrete mathematics • Combinatorics • Number theory • Analysis • Geometry • Topology • Applied mathematics • Probability • Statistics • Mathematical physics |
