Abstract

The Adaptive Metropolis (AM) algorithm is based on the symmetric random-walk Metropolis algorithm. The proposal distribution has the following time-dependent covariance matrix, at step $n+1$ , $S_n=\mathrm{Cov}(X_1,\ldots,X_n)+\varepsilon I$, that is, the sample covariance matrix of the history of the chain plus a (small) constant $\varepsilon>0$ multiple of the identity matrix $I$ . The lower bound on the eigenvalues of $S_n$ induced by the factor $\varepsilon I$ is theoretically convenient, but practically cumbersome, as a good value for the parameter $\varepsilon$ may not always be easy to choose. This article considers variants of the AM algorithm that do not explicitly bound the eigenvalues of $S_n$ away from zero. The behaviour of $S_n$ is studied in detail, indicating that the eigenvalues of $S_n$ do not tend to collapse to zero in general. In dimension one, it is shown that $S_n$ is bounded away from zero if the logarithmic target density is uniformly continuous. For a modification of the AM algorithm including an additional fixed component in the proposal distribution, the eigenvalues of $S_n$ are shown to stay away from zero with a practically non-restrictive condition. This result implies a strong law of large numbers for super-exponentially decaying target distributions with regular contours.

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