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Home > Minkowski space

 
In physics and mathematics, Minkowski space (or Minkowski spacetime) is the mathematical setting in which Einstein's theory of special relativity is most conveniently formulated. In this setting the three ordinary dimensions of space are combined with a single dimension of time to form a four-dimensional spacetime.

Note that this article describes only the mathematical structure of Minkowski space. For descriptions of the physics see the special relativity page.

1 History

Minkowski space is named for the German mathematician Hermann Minkowski, who around 1907 realized that the theory of special relativity previously worked out by Einstein and Lorentz could be elegantly described using a four-dimensional spacetime, which combines the dimension of time with the three dimensions of space.

“The views of space and time which I wish to lay before you have sprung from the soil of experimental physics, and therein lies their strength. They are radical. Henceforth space by itself, and time by itself, are doomed to fade away into mere shadows, and only a kind of union of the two will preserve an independent reality.” – Hermann Minkowski, 1908

2 Structure

Formally, Minkowski space is a four-dimensional real vector space equipped with a nondegenerate, symmetric bilinear form with signature (+,-,-,-). The overall sign is a matter of conventionAnnoyingly often in physics, some textbooks and articles use definitions for certain quantities with the opposite sign from other textbook/articles. This lack of standardization is a frequent source of confusion, misunderstandings and even outright errors and many prefer to use the signature (-,+,+,+). Minkowski space is often denoted R1,3 to emphasize the signature, although it is also denoted M 4 or simply M.

2.1 The Minkowski inner product

The inner product between two vectors v, w in Minkowski space is a map M × MR, denoted <v, w>, that satisfies four properties. Three of which are that it be

  1. bilinear: <au + v, w> = a<u, w> + <v, w>, for all a, u, v, and w
  2. symmetric: <v, w> = <w, v> for all v and w, and
  3. nondegenerate: if <v, w> = 0 for all w then v = 0,

where a is in R and u, v, w are vectors in M.

Note that this is not an inner product in the usual sense of the word since it is not positive-definite, i.e. the norm-squared of a vector v, defined as ||v||2 = <v, v>, need not be positive. The positive-definite condition has been replaced by the weaker condition of nondegeneracy (every positive-definite form is nondegenerate but not vice-versa).

Just as in Euclidean spaceEuclidean space is the usual n dimensional mathematical space, a generalization of the 2- and 3-dimensional spaces studied by Euclid. Formally, for any non-negative integer n n dimensional Euclidean space is the set R n (where R is the set of real numbers, two vectors are said to be orthogonal if <v, w> = 0. A vector v is called a unit vectorIn mathematics, a unit vector in a normed vector space is a vector (most commonly a spatial vector) whose length is 1. A unit vector is often written with a “hat”, thus: . In Euclidean space, the dot product of two unit vectors is simply the cosine of the if ||v||2 = ±1. A basis for M consisting of mutually orthogonal unit vectors is called an orthonormal basisIn mathematics, an orthonormal basis of an inner product space V i. a vector space with an inner product), or in particular of a Hilbert space H is a set of elements whose span is dense in the space, in which the elements are mutually orthogonal and norma.

There is a theorem stating that any inner product space satisfying conditions 1-3 above always has an orthonormal basis. Furthermore, the theorem states that the number of positive and negative unit vectors in any such basis is fixed. This pair of numbers is called the signature of the inner product.

We can then state then fourth condition on the Minkowski inner product:

4.  The inner product <·, ·> has signature (+,-,-,-)


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Topics: Minkowski Space, History, Structure, The Minkowski Inner Product...

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