Tensor
In
mathematics, a
tensor is (in an informal sense) a generalized
linear 'quantity' or 'geometrical entity' that can be expressed as a
multi-dimensional array relative to a choice of
basis; however, as an object in and of itself, a tensor is
independent of any chosen frame of reference. The
rank of a particular tensor is the number of array indices required to describe such a quantity. For example,
mass,
temperature, and other
scalar quantities are tensors of rank 0;
force,
momentum and other
vector-like quantities are tensors of rank 1; a
linear transformation such as an
anisotropic relationship (
relativistic mass) between
force and
acceleration vectors is a tensor of rank 2.
This article attempts to provide a non-technical introduction to the idea of tensors, and to provide an introduction to the articles which describe different, complementary treatments of the theory of tensors in detail. For a formal, axiomatic definition of
tensor, see the entry entitled
tensor (intrinsic definition). The entry
Classical treatment of tensors gives an older, less formal definition. The entry
intermediate treatment of tensors attempts to bridge the two extremes and to show their relationships.
It should also be noted that many mathematical structures informally called 'tensors' are actually '
tensor fields', tensorial quantities that vary from point to point. However, to better understand tensor fields, one should first understand the basic idea of tensors.
Tensors are of importance in
physics and
engineering. In the field of
diffusion tensor imaging, for instance, a tensor quantity that expresses the differential
permeability of organs to water in varying directions is used to produce scans of the
brain. Perhaps the most important engineering examples are the
stress tensor and
strain tensor, which are both
2nd rank tensors, and are related in a general linear material by a fourth rank
elasticity tensor.
Specifically, a 2nd rank tensor quantifying stress in a 3-dimensional/solid object has components which can be conveniently represented as 3x3 array. The three Cartesian faces of a cube-shaped infinitesimal volume segment of the solid are each subject to some given force. The force's vector components are also three in number (being in three-space). Thus, 3x3, or 9 components are required to describe the stress at this cube-shaped infintesimal segment (which may now be treated as a point). Within the bounds of this solid is a whole mass of varying stress quantities, each requiring 9 quantities to describe. Thus, the need for a 2nd order tensor is produced.
While tensors can be represented by multi-dimensional arrays of components, the point of having a tensor
theory is to explain further implications of saying that a quantity is a
tensor, beyond specifying that it requires a number of indexed components. In particular, tensors behave in specific ways under
coordinate transformations. The abstract theory of tensors is a branch of
linear algebra, now called
multilinear algebra.
The word
tensor was introduced in
1846 by
William Rowan Hamilton[William Rowan Hamilton, On some Extensions of Quaternions[1]] to describe the
norm operation in a certain type of algebraic system (eventually known as a
Clifford algebra). The word was used in its current meaning by
Woldemar Voigt in
1899.The notation was developed around
1890 by
Gregorio Ricci-Curbastro under the title
absolute differential calculus, and was made accessible to many mathematicians by the publication of
Tullio Levi-Civita's
1900 classic text of the same name (in Italian; translations followed). In the 20th century, the subject came to be known as
tensor analysis, and achieved broader acceptance with the introduction of
Einstein's theory of
general relativity, around
1915. General Relativity is formulated completely in the language of tensors. Einstein had learned about them, with great difficulty, from the geometer
Marcel Grossmann[Abraham Pais, Subtle is the Lord], or perhaps from Levi-Civita himself. Tensors are used also in other fields such as
continuum mechanics.
There are two ways of approaching the definition of tensors:
* The usual physics way of defining tensors, in terms of objects whose components transform according to certain rules, introducing the ideas of
covariant or
contravariant transformations.
* The usual mathematics way, which involves defining certain
vector spaces and not fixing any coordinate systems until bases are introduced when needed. Covariant vectors, for instance, can also be described as
one-forms, or as the elements of the
dual space to the contravariant vectors.
Physicists and engineers are among the first to recognise that vectors and tensors have a physical significance as entities, which goes beyond the (often arbitrary) co-ordinate system in which their components are enumerated. Similarly, mathematicians find there are some tensor relations which are more conveniently derived in a co-ordinate notation.
A tensor may be expressed as the sequence of values represented by a function with a vector valued
domain and a
scalar valued
range. These vectors in the domain are vectors of counting numbers, and these numbers are called indexes. For example, a rank 3 tensor might have dimensions 2, 5, and 7. Here, the vectors range from <1, 1, 1> through <2, 5, 7>. Here, the tensor would have one value at <1, 1, 1>, another at <1, 1, 2>, and so on for a total of 70 values. (Likewise, vectors may be expressed as a sequence of values represented by a function with a scalar valued domain and a scalar valued range, and the numbers in the domain are counting numbers called indices, and the number of distinct indices is sometimes called the
dimension of the vector.)
A tensor
field associates a tensor value with every point on a
manifold. Thus, instead of simply having 70 values as indicated in the above example, for a rank 3 tensor field with dimensions <2, 5, 7> every point in the space would have 70 values associated with it. In other words, a tensor field means there's some tensor valued function which has the Euclidean space as its domain. Not just any function is allowed here -- see
tensor field for more coverage of these requirements.
Not all relationships in nature are linear, but most are
differentiable and so may be locally approximated with sums of
multilinear maps. Thus most quantities in the physical sciences can be usefully expressed as tensors.
As a simple example, consider a ship in the water. We want to describe its response to an applied force. Force is a vector, and the ship will respond with an acceleration, which is also a vector. The acceleration will in general not be in the same direction as the force, because of the particular shape of the ship's body. However, it turns out that the relationship between force and acceleration is
linear in classical mechanics. Such a relationship is described by a tensor of type (1,1) (that is to say, it transforms a vector into another vector). The tensor can be represented as a
matrix which when multiplied by a vector results in another vector. Just as the numbers which representa vector will change if one changes the coordinate system, the numbers in the matrix that represents the tensor will also change when the coordinate system is changed.
In engineering, the stresses inside a
rigid body or
fluid are also described by a tensor; the word "tensor" is Latin for something that stretches, i.e., causes tension. If a particular surface element inside the material is singled out, the material on one side of the surface will apply a force on the other side. In general, this force will not be orthogonal to the surface, but it will depend on the orientation of the surface in a linear manner. This is described by a tensor of type (2,0), or more precisely by a tensor
field of type (2,0) since the stresses may change from point to point.
Some well known examples of tensors in geometry are
quadratic forms, and the
curvature tensor. Examples of physical tensors are the
energy-momentum tensor, the
inertia tensor and the
polarization tensor.
Geometric and physical quantities may be categorized by consideringthe
degrees of freedom inherent in their description. The scalarquantities are those that can be represented by a single number ---
pressure,
mass,
temperature, for example. There are also vector-likequantities, such as
force, that require a list of numbers for theirdescription. Finally, quantities such as quadratic formsnaturally require a multiply indexed array for their representation.These latter quantities can only be conceived of as tensors.
Actually, the tensor notion is quite general, and applies to all ofthe above examples; scalars and vectors are special kinds oftensors. The feature that distinguishes a scalar from a vector, anddistinguishes both of those from a more general tensor quantity isthe number of indices in the representing array. This number iscalled the
rank (or the
order) of a tensor. Thus, scalars are rank zero tensors (no indices at all), and vectors are rank one tensors.
Another example of a tensor is the
Riemann curvature tensor from the
theory of General Relativity, which is of rank 4 with dimensions <4, 4, 4, 4> (3 spatial + time = 4 dimensions). It can be treated as matrix (or vector) with 256 components (256 = 4 × 4 × 4 × 4). Only 20 of these components are actually independent of each other, greatly simplifying the matrix (or vector).
There are
equivalent approaches to visualizing and working with tensors; that the content is actually the same may only become apparent with some familiarity with the material.
*The
classical approachThe classical approach views tensors as multidimensional
arrays that are
n-dimensional generalizations of scalars, 1-dimensional vectors and 2-dimensional
matrices. The "components" of the tensor are the values in the array. This idea can then be further generalized to
tensor fields, where the elements of the tensor are
functions, or even
differentials.
However, to count as a tensor, the arrays need to transform correctly when the reference co-ordinate system is changed. This transformation is a generalisation of the relationship which holds for vector components, and is similarly an expression of the independence of the underlying entity from the reference frame in which it is expressed.
*The
modern approachThe modern (component-free) approach views tensors initially as abstract objects, expressing some definite type of multi-linear concept. Their well-known properties can be derived from their definitions, as linear maps or more generally; and the rules for manipulations of tensors arise as an extension of
linear algebra to
multilinear algebra. This treatment has attempted to replace the component-based treatment for advanced study, in the way that the more modern component-free treatment of vectors replaces the traditional component-based treatment after the component-based treatment has been used to provide an elementary motivation for the concept of a vector. You could say that the slogan is 'tensors are elements of some tensor space'. Nevertheless, a component-free approach has not become fully popular, owing to the difficulties involved with giving a geometrical interpretation to higher-rank tensors.
* The
intermediate treatment of tensors article attempts to bridge the two extremes, and to show their relationships.
In the end the same computational content is expressed, both ways. See
glossary of tensor theory for a listing of technical terms.
It is also possible for a
tensor field to have a "density". A tensor with density
r transforms as an ordinary tensor under coordinate transformations, except that it is also multiplied by the determinant of the
Jacobian to the
rth power. This is best explained, perhaps, using
vector bundles: where the determinant bundle of the
tangent bundle is a line bundle that can be used to 'twist' other bundles
r times.
*
Glossary of tensor theoryNotation
*
Abstract index notation*
Einstein notation*
Metric tensor*
Voigt notation*
Mandel notationFoundational
*
Contravariant*
Covariant*
Fibre bundle*
One-form*
Tensor field*
Tensor productApplications
*
Absolute differentiation*
Application of tensor theory in engineering*
Application of tensor theory in physics*
Curvature*
Riemannian geometry*
Tensor derivative*
An Introduction to Tensors for Students of Physics and Engineering, released by
NASA*
A discussion of the various approaches to teaching tensors, and recommendations of textbooks*
A thread discussing basic and in depth definitions as well as various examples*
Introduction to Tensor Calculus and Continuum Mechanics*
A Quick Introduction to Tensor Analysis by R. A. Sharipov.
Tensors, Differential Forms, and Variational Principles (1989) David Lovelock, Hanno Rund
Tensor Analysis on Manifolds (1981) Richard L Bishop, Samuel I. Goldberg
Introduction to Tensor Calculus, Relativity and Cosmology (2003) D. F. Lawden
Tensor Analysis (2003) L.P. Lebedev, Michael J. Cloud
*
GRTensorII is a computer algebra package for performing calculations in the general area of differential geometry. GRTensor II is not a stand alone package, the program runs with all versions of Maple V Release 3 through Maple 9.5. A limited version (GRTensorM) has been ported to Mathematica.
*
Tensorial 3.0 Tensorial is a general purpose tensor calculus package for Mathematica 4.1 or better. Some of its features are: complete freedom in choosing tensor labels and indices; base indices may be any set of integers or symbols; tensor shortcuts for easy entry of tensors; flavored (colored or annotated) indices for different coordinate systems; CircleTimes notation available; easy methods for storing and substituting tensor values; routines for partial, covariant, total, absolute (Intrinsic) and Lie derivatives; There is extensive documentation, with a Help page and numerous examples for each command. In addition there are a number of tutorial and sample application notebooks.You may wish to check the site occasionally for updates. A section in the Help Introduction now gives a history of the major additions and changes in usage.Load downTensorCalculus3.zip 369KB Package, StyleSheet and Documentation,
11 August 2005.TensorialReadMe.txt 3KB Instructions for installation,
11 October 2003. Related applications TMecanica, TContinuumMechanics, TGeneralRelativity, are also available on the site.
*
MathTensor is a tensor analysis system written for the Mathematica system. It provides more than 250 functions and objects for elementary and advanced users.
*
Tensors in Physics is a tensor package written for the Mathematica system. It provides many functions relevant for General Relativity calculations in general Riemann-Cartan geometries.
*
maxima is a free software
computer algebra system which should be usable for making tensor algebra calculations
**
tensors in maxima *
Ricci is a system for Mathematica 2.x and later for doing basic tensor analysis, available for free.
*
Tela is a software package similar to Matlab and Octave, but designed specifically for tensors.
*
Tensor Toolbox Multilinear algebra MATLAB software.
