On the Optimal Weighted ell₂ Regularization in Overparameterized Linear Regression
read the original abstract
We consider the linear model $\mathbf{y} = \mathbf{X} \mathbf{\beta}_\star + \mathbf{\epsilon}$ with $\mathbf{X}\in \mathbb{R}^{n\times p}$ in the overparameterized regime $p>n$. We estimate $\mathbf{\beta}_\star$ via generalized (weighted) ridge regression: $\hat{\mathbf{\beta}}_\lambda = \left(\mathbf{X}^T\mathbf{X} + \lambda \mathbf{\Sigma}_w\right)^\dagger \mathbf{X}^T\mathbf{y}$, where $\mathbf{\Sigma}_w$ is the weighting matrix. Under a random design setting with general data covariance $\mathbf{\Sigma}_x$ and anisotropic prior on the true coefficients $\mathbb{E}\mathbf{\beta}_\star\mathbf{\beta}_\star^T = \mathbf{\Sigma}_\beta$, we provide an exact characterization of the prediction risk $\mathbb{E}(y-\mathbf{x}^T\hat{\mathbf{\beta}}_\lambda)^2$ in the proportional asymptotic limit $p/n\rightarrow \gamma \in (1,\infty)$. Our general setup leads to a number of interesting findings. We outline precise conditions that decide the sign of the optimal setting $\lambda_{\rm opt}$ for the ridge parameter $\lambda$ and confirm the implicit $\ell_2$ regularization effect of overparameterization, which theoretically justifies the surprising empirical observation that $\lambda_{\rm opt}$ can be negative in the overparameterized regime. We also characterize the double descent phenomenon for principal component regression (PCR) when both $\mathbf{X}$ and $\mathbf{\beta}_\star$ are anisotropic. Finally, we determine the optimal weighting matrix $\mathbf{\Sigma}_w$ for both the ridgeless ($\lambda\to 0$) and optimally regularized ($\lambda = \lambda_{\rm opt}$) case, and demonstrate the advantage of the weighted objective over standard ridge regression and PCR.
This paper has not been read by Pith yet.
Forward citations
Cited by 1 Pith paper
-
Principles and Practice of Deep Representation Learning: or a Mathematical Theory of Memory
The book presents principles from optimization and information theory to explain deep network architectures and enable new interpretable models.
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.