What question did this study set out to answer?

The research aims to establish a nonasymptotic universality principle for sums of random matrices generated by Markovian processes.

April 29, 2026Open Access

Sharp concentration for sums of matrices with Markovian dependence through universality

Key Points

The research aims to establish a nonasymptotic universality principle for sums of random matrices generated by Markovian processes.
Utilized spectral properties of Markov chains to draw parallels with Gaussian matrices.
Employed Boolean cumulants and a change-of-measure argument for efficient estimates.
Demonstrated applications using Wigner-type matrices and spectral clustering models.
Achieved sharp concentration inequalities compared to previous Markovian matrix results.
Demonstrated polynomial dimensional improvements over traditional methods.
Recovered sharp limiting values in the context of spectral clustering techniques.

Abstract

Abstract We prove that a sum of random matrices generated by a ψ -mixing Markov chain has similar spectral properties to a Gaussian matrix with the same mean and covariance structure. This nonasymptotic universality principle enables sharp concentration inequalities when combined with recent advances in the Gaussian literature. We illustrate the theory with examples, showing how it enables polynomial dimensional improvements relative to previous Markovian matrix concentration results when applied to Wigner-type matrices, and how one can recover sharp limiting values for a model used to study spectral clustering techniques. A key challenge in the proof is that techniques based only on classical cumulants, which can be used when summands are independent, are not sufficient on their own for efficient estimates in a Markovian setting. Our approach exploits Boolean cumulants and a change–of–measure argument.

Mark Helpful

Bookmark

Relay

View Full Paper