Learning Sparse Additive Models with Interactions in High Dimensions

Abstract

A function f: Rd → R is referred to as a Sparse Additive Model (SPAM), if it is of the form f(x) = Σl ∈ Sφl(xl), where S ⊂ [d], |S| d. Assuming φl's and S to be unknown, the problem of estimating f from its samples has been studied extensively. In this work, we consider a generalized SPAM, allowing for second order interaction terms. For some S1 ⊂ [d], S2 ⊂ [d] 2, the function f is assumed to be of the form: f(x) = Σp ∈ S1φp (xp) + Σ(l,l) ∈ S2φ(l,l) (xl,xl). Assuming φp,φ(l,l), S1 and, S2 to be unknown, we provide a randomized algorithm that queries f and exactly recovers S1,S2. Consequently, this also enables us to estimate the underlying φp, φ(l,l). We derive sample complexity bounds for our scheme and also extend our analysis to include the situation where the queries are corrupted with noise -- either stochastic, or arbitrary but bounded. Lastly, we provide simulation results on synthetic data, that validate our theoretical findings.