Difference between revisions of "Segre classification"

Let $V$ be an $n$-dimensional vector space over an algebraically closed field $F$ (say $F=C$, but not $\textbf{R}$; this special case will be dealt with separately) and let $f$ be a linear operator from $V$ to itself. The essential information in $f$ can be described by the theory of the Jordan canonical form (cf. Normal form). The essential result is that if $\lambda_1,...,\lambda_r$ are the distinct eigenvalues of $f$ with multiplicities $n_1,...,n_r$, then $V$ is the direct sum $V=V_1\oplus ...\oplus V_r$ where each $V_i$ is $f$-invariant, $\mathrm{dim}V_i=n_i$ and, when restricted to $V_i$, $f$ has the form $\lambda_iI+N_i$ where $I$ is the identity mapping on $V_i$ and each $N_i$ is nilpotent (see e.g. [a1]).

An equivalent and perhaps more familiar description of is through the matrix representing with respect to a particular basis of . The same theory says that this basis may be chosen so that takes its Jordan canonical form

Here, each is an -matrix with in each diagonal position and an entry or in each superdiagonal position (and it is assumed that each unnamed entry in any matrix is zero). Each matrix can then be written in the form

where each is an -matrix and with .

A shorthand way of indicating this structure for is by means of its Segre symbol (or Segre characteristic), which is

Thus, in the Segre symbol there is a set of entries (enclosed in round brackets) for each distinct eigenvalue. If there is only one entry in a set of brackets, the brackets are usually omitted.

An obvious important application of the theory is when . For vector spaces over the above does not apply, since is not algebraically closed and the proof relies on the fundamental theorem of algebra (cf. also Algebra, fundamental theorem of). Of course, the Jordan forms still apply if the characteristic equation can be solved completely over . If not, an alternative approach (the rational canonical form) is available [a2]. If a real matrix admits a complex conjugate pair of eigenvalues, this is often indicated in the Segre symbol by a pair of entries .

One of the important modern applications of the Segre classification is the Petrov classification of gravitational fields [a3]. Another also appears in Einstein's theory and to briefly describe it the following definitions are required.

A space-time is a -dimensional connected Hausdorff manifold admitting a Lorentz metric of signature . On such space-times, symmetric second-order tensors are often encountered (e.g. the Ricci, Einstein and energy-momentum tensors; cf. also Tensor on a vector space). Following the success of the Petrov classification it has been found useful to classify such tensors at a point in by regarding them as linear mappings on the tangent space to at . Since is a real vector space one, of course, encounters the problem of closure mentioned above. However, if the tensor in question is , then one has the eigenvector-eigenvalue problem

(a1)

for a complex eigenvector and eigenvalue and , respectively. It should be noted here that one could write (a1) as , but because of the Lorentz signature of this would not be in the standard form to which one could apply the usual theory. There are ways of handling this latter equation but the approach (a1) is more standardized. The solution to this problem can be found in detail in [a4], [a3], [a5], [a6]. It turns out that, of the potential Segre types available, the only ones possible, bearing in mind the second equation in (a1) and the signature of , are , , and together with their degeneracies indicated, as mentioned above, by the use of round brackets. The use of this classification of such tensors is often very useful in general relativity theory (see e.g. [a7]).

References