English

Learning general sparse additive models from point queries in high dimensions

Numerical Analysis 2019-05-02 v3

Abstract

We consider the problem of learning a dd-variate function ff defined on the cube [1,1]dRd[-1,1]^d\subset {\mathbb R}^d, where the algorithm is assumed to have black box access to samples of ff within this domain. Denote Sr([d]r);r=1,,r0{\mathcal S}_r \subset {[d] \choose r}; r=1,\dots,r_0 to be sets consisting of unknown rr-wise interactions amongst the coordinate variables. We then focus on the setting where ff has an additive structure, i.e., it can be represented as f=jS1ϕj+jS2ϕj++jSr0ϕj,f = \sum_{{\mathbf j} \in {\mathcal S}_1} \phi_{{\mathbf j}} + \sum_{{\mathbf j} \in {\mathcal S}_2} \phi_{{\mathbf j}} + \dots + \sum_{{\mathbf j} \in {\mathcal S}_{r_0}} \phi_{{\mathbf j}}, where each ϕj\phi_{{\mathbf j}}; jSr{\mathbf j} \in {\cal S}_r is at most rr-variate for 1rr01 \leq r \leq r_0. We derive randomized algorithms that query ff at carefully constructed set of points, and exactly recover each Sr{\mathcal S}_r with high probability. In contrary to the previous work, our analysis does not rely on numerical approximation of derivatives by finite order differences.

Cite

@article{arxiv.1801.08499,
  title  = {Learning general sparse additive models from point queries in high dimensions},
  author = {Hemant Tyagi and Jan Vybiral},
  journal= {arXiv preprint arXiv:1801.08499},
  year   = {2019}
}
R2 v1 2026-06-22T23:56:34.534Z