Eigenvalue
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In matrix theory, an element in the underlying ring R of a square matrix A is called a right eigenvalue if there exists a nonzero column vector x such that Ax=λx, or a left eigenvalue if there exists a nonzero row vector y such that yA=yλ. If R is commutative, the left eigenvalues of A are exactly the right eigenvalues of A and are just called eigenvalues. If R is not commutative, e.g. quaternions, they may be different.
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2 Spectrum 3 Multiset of eigenvalues 4 Trace and Determinant 5 See also |
Multiplicity
Suppose A is a square matrix over commutative ring. The algebraic multiplicity (or simply multiplicity) of an eigenvalue λ of A is the number of factors t-λ of the characteristic polynomial of A. The geometric multiplicity of λ is the number of factor t-λ of the minimal polynomial of A or equivalently the nullity of (λI-A).
An eigenvalue of algebraic multiplicity 1 is called a simple eigenvalue.
Spectrum
In functional analysis, the spectrum of a bounded linear operator A on a Banach space is the set of scalar ν such that νI-A does not have a bounded two-sided inverse. Note that by the closed graph theorem, if a bounded operator has an inverse, the inverse is necessarily bounded.
If the underlying Banach space is finite dimensional, then the spectrum of A is the same of the set of eigenvalues of A. This follows from the fact that on finite dimensional spaces injectivity of a linear operator A is equivalent to surjectivity of A.
Multiset of eigenvalues
Occasionally, in an article on matrix theory, one may read a statement like:
- The eigenvalues of a matrix A are 4,4,3,3,3,2,2,1.
This style is used because algebraic multiplicity is the key to many mathematical proofs in matrix theory.
Trace and Determinant
Suppose the eigenvalues of a matrix A are λ1,λ2,...,λn. Then the trace of A is λ1+λ2+...+λn and the determinant of A is λ1λ2...λn. These two are very important concepts in matrix theory.
See also
Please refer to eigenvector for some other properties of eigenvalues.