Courant minimax principle

In mathematics, the Courant minimax principle gives the eigenvalues of a real symmetric matrix. It is named after Richard Courant.

Introduction

The Courant minimax principle gives a condition for finding the eigenvalues for a real symmetric matrix. The Courant minimax principle is as follows:

For any real symmetric matrix A,

λ k = min C max x = 1 , C x = 0 A x , x , {\displaystyle \lambda _{k}=\min \limits _{C}\max \limits _{{\|x\|=1},{Cx=0}}\langle Ax,x\rangle ,}

where C {\displaystyle C} is any ( k 1 ) × n {\displaystyle (k-1)\times n} matrix.

Notice that the vector x is an eigenvector to the corresponding eigenvalue λ.

The Courant minimax principle is a result of the maximum theorem, which says that for q ( x ) = A x , x {\displaystyle q(x)=\langle Ax,x\rangle } , A being a real symmetric matrix, the largest eigenvalue is given by λ 1 = max x = 1 q ( x ) = q ( x 1 ) {\displaystyle \lambda _{1}=\max _{\|x\|=1}q(x)=q(x_{1})} , where x 1 {\displaystyle x_{1}} is the corresponding eigenvector. Also (in the maximum theorem) subsequent eigenvalues λ k {\displaystyle \lambda _{k}} and eigenvectors x k {\displaystyle x_{k}} are found by induction and orthogonal to each other; therefore, λ k = max q ( x k ) {\displaystyle \lambda _{k}=\max q(x_{k})} with x j , x k = 0 ,   j < k {\displaystyle \langle x_{j},x_{k}\rangle =0,\ j<k} .

The Courant minimax principle, as well as the maximum principle, can be visualized by imagining that if ||x|| = 1 is a hypersphere then the matrix A deforms that hypersphere into an ellipsoid. When the major axis on the intersecting hyperplane are maximized — i.e., the length of the quadratic form q(x) is maximized — this is the eigenvector, and its length is the eigenvalue. All other eigenvectors will be perpendicular to this.

The minimax principle also generalizes to eigenvalues of positive self-adjoint operators on Hilbert spaces, where it is commonly used to study the Sturm–Liouville problem.

See also

References

  • Courant, Richard; Hilbert, David (1989), Method of Mathematical Physics, Vol. I, Wiley-Interscience, ISBN 0-471-50447-5 (Pages 31–34; in most textbooks the "maximum-minimum method" is usually credited to Rayleigh and Ritz, who applied the calculus of variations in the theory of sound.)
  • Keener, James P. Principles of Applied Mathematics: Transformation and Approximation. Cambridge: Westview Press, 2000. ISBN 0-7382-0129-4
  • Horn, Roger; Johnson, Charles (1985), Matrix Analysis, Cambridge University Press, p. 179, ISBN 978-0-521-38632-6