Cheeger bound

In mathematics, the Cheeger bound is a bound of the second largest eigenvalue of the transition matrix of a finite-state, discrete-time, reversible stationary Markov chain. It can be seen as a special case of Cheeger inequalities in expander graphs.

Let $X$ be a finite set and let $K(x,y)$ be the transition probability for a reversible Markov chain on $X$ . Assume this chain has stationary distribution $\pi$ .

Define

Q(x,y) = \pi(x) K(x,y)

and for $A,B \subset X$ define

Q(A \times B) = \sum_{x \in A, y \in B} Q(x,y).

Define the constant $\Phi$ as

\Phi = \min_{S \subset X, \pi(S) \leq \frac{1}{2}} \frac{Q (S \times S^c)}{\pi(S)}.

The operator $K,$ acting on the space of functions from $|X|$ to $|X|$ , defined by

(K \phi)(x) = \sum_y K(x,y) \phi(y) \,

has eigenvalues $\lambda_1 \geq \lambda_2 \geq \cdots \geq \lambda_n$ . It is known that $\lambda_1 = 1$ . The Cheeger bound is a bound on the second largest eigenvalue $\lambda_2$ .

Theorem (Cheeger bound):

1 - 2 \Phi \leq \lambda_2 \leq 1 - \frac{\Phi^2}{2}.

References

J. Cheeger, A lower bound for the smallest eigenvalue of the Laplacian, Problems in Analysis, Papers dedicated to Salomon Bochner, 1969, Princeton University Press, Princeton, 195-199.
P. Diaconis, D. Stroock, Geometric bounds for eigenvalues of Markov chains, Annals of Applied Probability, vol. 1, 36-61, 1991, containing the version of the bound presented here.

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Cheeger bound

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