On Empirical Risk Minimization with Dependent and Heavy-Tailed Data

09/06/2021

∙

In this work, we establish risk bounds for the Empirical Risk Minimization (ERM) with both dependent and heavy-tailed data-generating processes. We do so by extending the seminal works of Mendelson [Men15, Men18] on the analysis of ERM with heavy-tailed but independent and identically distributed observations, to the strictly stationary exponentially β-mixing case. Our analysis is based on explicitly controlling the multiplier process arising from the interaction between the noise and the function evaluations on inputs. It allows for the interaction to be even polynomially heavy-tailed, which covers a significantly large class of heavy-tailed models beyond what is analyzed in the learning theory literature. We illustrate our results by deriving rates of convergence for the high-dimensional linear regression problem with dependent and heavy-tailed data.

READ FULL TEXT

On Empirical Risk Minimization with Dependent and Heavy-Tailed Data

Performance of Empirical Risk Minimization for Linear Regression with Dependent Data

Regularization, sparse recovery, and median-of-means tournaments

ℓ_1-regression with Heavy-tailed Distributions

Heavy-Tailed Pitman–Yor Mixture Models

Changepoint analysis of historical battle deaths

Adaptive Huber Regression on Markov-dependent Data

Optimal Sparse Estimation of High Dimensional Heavy-tailed Time Series

On Empirical Risk Minimization with Dependent and Heavy-Tailed Data

Related Research

Performance of Empirical Risk Minimization for Linear Regression with Dependent Data

Regularization, sparse recovery, and median-of-means tournaments

ℓ_1-regression with Heavy-tailed Distributions

Heavy-Tailed Pitman–Yor Mixture Models

Changepoint analysis of historical battle deaths

Adaptive Huber Regression on Markov-dependent Data

Optimal Sparse Estimation of High Dimensional Heavy-tailed Time Series