Rayleigh quotient iteration

The algorithm is very similar to inverse iteration, but replaces the estimated eigenvalue at the end of each iteration with the Rayleigh quotient. Begin by choosing some value $\backslash mu\_0$ as an initial eigenvalue guess for the Hermitian matrix $A$. An initial vector $b\_0$ must also be supplied as initial eigenvector guess.

Calculate the next approximation of the eigenvector $b\_\{i+1\}$ by

b_{i+1} = \frac{(A-\mu_i I)^{-1}b_i}{\|(A-\mu_i I)^{-1}b_i\|},

where $I$ is the identity matrix,

and set the next approximation of the eigenvalue to the Rayleigh quotient of the current iteration equal to

\mu_{i+1} = \frac{b^*_{i+1} A b_{i+1}}{b^*_{i+1} b_{i+1}}.

To compute more than one eigenvalue, the algorithm can be combined with a deflation technique.{{Citation needed|date=February 2025}}

Note that for very small problems it is beneficial to replace the matrix inverse with the adjugate, which will yield the same iteration because it is equal to the inverse up to an irrelevant scale (the inverse of the determinant, specifically). The adjugate is easier to compute explicitly than the inverse (though the inverse is easier to apply to a vector for problems that aren't small), and is more numerically sound because it remains well defined as the eigenvalue converges.

Consider the matrix

:$$

A =

\left[\begin{matrix}

1 & 2 & 3\\

1 & 2 & 1\\

3 & 2 & 1\\

\end{matrix}\right]

for which the exact eigenvalues are $\backslash lambda\_1\; =\; 3+\backslash sqrt5$, $\backslash lambda\_2\; =\; 3-\backslash sqrt5$ and $\backslash lambda\_3\; =\; -2$, with corresponding eigenvectors

:$v\_1\; =\; \backslash left[$

\begin{matrix}

1 \\

\varphi-1 \\

1 \\

\end{matrix}\right], $v\_2\; =\; \backslash left[$

\begin{matrix}

1 \\

-\varphi \\

1 \\

\end{matrix}\right] and $v\_3\; =\; \backslash left[$

\begin{matrix}

1 \\

0 \\

1 \\

\end{matrix}\right].

(where $\backslash textstyle\backslash varphi=\backslash frac\{1+\backslash sqrt5\}2$ is the golden ratio).

The largest eigenvalue is $\backslash lambda\_1\; \backslash approx\; 5.2361$ and corresponds to any eigenvector proportional to $v\_1\; \backslash approx\; \backslash left[$

\begin{matrix}

1 \\

0.6180 \\

1 \\

\end{matrix}\right].

We begin with an initial eigenvalue guess of

:$b\_0\; =$

\left[\begin{matrix}

1 \\

1 \\

1 \\

\end{matrix}\right], ~\mu_0 = 200.

Then, the first iteration yields

:$b\_1\; \backslash approx$

\left[\begin{matrix}

-0.57927 \\

-0.57348 \\

-0.57927 \\

\end{matrix}\right], ~\mu_1 \approx 5.3355

the second iteration,

:$b\_2\; \backslash approx$

\left[\begin{matrix}

0.64676 \\

0.40422 \\

0.64676 \\

\end{matrix}\right], ~\mu_2 \approx 5.2418

and the third,

:$b\_3\; \backslash approx$

\left[\begin{matrix}

-0.64793 \\

-0.40045 \\

-0.64793 \\

\end{matrix}\right], ~\mu_3 \approx 5.2361

from which the cubic convergence is evident.

The following is a simple implementation of the algorithm in Octave.

function x = rayleigh(A, epsilon, mu, x)

x = x / norm(x);

% the backslash operator in Octave solves a linear system

y = (A - mu * eye(rows(A))) \ x;

lambda = y' * x;

mu = mu + 1 / lambda

err = norm(y - lambda * x) / norm(y)

while err > epsilon

x = y / norm(y);

y = (A - mu * eye(rows(A))) \ x;

lambda = y' * x;

mu = mu + 1 / lambda

err = norm(y - lambda * x) / norm(y)

end

end

• Power iteration
• Inverse iteration

• Lloyd N. Trefethen and David Bau, III, Numerical Linear Algebra, Society for Industrial and Applied Mathematics, 1997. {{isbn|0-89871-361-7}}.
• Rainer Kress, "Numerical Analysis", Springer, 1991. {{isbn|0-387-98408-9}}

{{Numerical linear algebra}}

Category:Numerical linear algebra

Category:Articles with example MATLAB/Octave code