Totally Concave Regression

Shape constraints offer compelling advantages in nonparametric regression by enabling the estimation of regression functions under realistic assumptions, devoid of tuning parameters. However, most existing shape-constrained nonparametric regression methods, except additive models, impose too few restrictions on the regression functions. This often leads to suboptimal performance, such as overfitting, in multivariate contexts due to the curse of dimensionality. On the other hand, additive shape-constrained models are sometimes too restrictive because they fail to capture interactions among the covariates. In this paper, we introduce a novel approach for multivariate shape-constrained nonparametric regression, which allows interactions without suffering from the curse of dimensionality. Our approach is based on the notion of total concavity originally due to T. Popoviciu and recently described in Gal [24]. We discuss the characterization and computation of the least squares estimator over the class of totally concave functions and derive rates of convergence under standard assumptions. The rates of convergence depend on the number of covariates only logarithmically, and the estimator, therefore, is guaranteed to avoid the curse of dimensionality to some extent. We demonstrate that total concavity can be justified for many real-world examples and validate the efficacy of our approach through empirical studies on various real-world datasets.