Rayleigh quotient

In mathematics, the Rayleigh quotient[1] (/ˈr.li/) for a given complex Hermitian matrix and nonzero vector is defined as:[2][3]For real matrices and vectors, the condition of being Hermitian reduces to that of being symmetric, and the conjugate transpose to the usual transpose . Note that for any non-zero scalar . Recall that a Hermitian (or real symmetric) matrix is diagonalizable with only real eigenvalues. It can be shown that, for a given matrix, the Rayleigh quotient reaches its minimum value (the smallest eigenvalue of ) when is (the corresponding eigenvector).[4] Similarly, and .

The Rayleigh quotient is used in the min-max theorem to get exact values of all eigenvalues. It is also used in eigenvalue algorithms (such as Rayleigh quotient iteration) to obtain an eigenvalue approximation from an eigenvector approximation.

The range of the Rayleigh quotient (for any matrix, not necessarily Hermitian) is called a numerical range and contains its spectrum. When the matrix is Hermitian, the numerical radius is equal to the spectral norm. Still in functional analysis, is known as the spectral radius. In the context of -algebras or algebraic quantum mechanics, the function that to associates the Rayleigh–Ritz quotient for a fixed and varying through the algebra would be referred to as vector state of the algebra.

In quantum mechanics, the Rayleigh quotient gives the expectation value of the observable corresponding to the operator for a system whose state is given by .

If we fix the complex matrix , then the resulting Rayleigh quotient map (considered as a function of ) completely determines via the polarization identity; indeed, this remains true even if we allow to be non-Hermitian. However, if we restrict the field of scalars to the real numbers, then the Rayleigh quotient only determines the symmetric part of .

  1. ^ Also known as the Rayleigh–Ritz ratio; named after Walther Ritz and Lord Rayleigh.
  2. ^ Horn, R. A.; Johnson, C. A. (1985). Matrix Analysis. Cambridge University Press. pp. 176–180. ISBN 0-521-30586-1.
  3. ^ Parlett, B. N. (1998). The Symmetric Eigenvalue Problem. Classics in Applied Mathematics. SIAM. ISBN 0-89871-402-8.
  4. ^ Costin, Rodica D. (2013). "Midterm notes" (PDF). Mathematics 5102 Linear Mathematics in Infinite Dimensions, lecture notes. The Ohio State University.

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