Sparse Max-Affine Regression
Abstract
This paper presents Sparse Gradient Descent as a solution for variable selection in convex piecewise linear regression, where the model is given as the maximum of k-affine functions x j ∈ [k] aj, x + bj for j = 1,…,k. Here, \ aj\j=1k and \bj\j=1k denote the ground-truth weight vectors and intercepts. A non-asymptotic local convergence analysis is provided for Sp-GD under sub-Gaussian noise when the covariate distribution satisfies the sub-Gaussianity and anti-concentration properties. When the model order and parameters are fixed, Sp-GD provides an ε-accurate estimate given O((ε-2σz2,1)s(d/s)) observations where σz2 denotes the noise variance. This also implies the exact parameter recovery by Sp-GD from O(s(d/s)) noise-free observations. The proposed initialization scheme uses sparse principal component analysis to estimate the subspace spanned by \ aj\j=1k, then applies an r-covering search to estimate the model parameters. A non-asymptotic analysis is presented for this initialization scheme when the covariates and noise samples follow Gaussian distributions. When the model order and parameters are fixed, this initialization scheme provides an ε-accurate estimate given O(ε-2(σz4,σz2,1)s24(d)) observations. A new transformation named Real Maslov Dequantization (RMD) is proposed to transform sparse generalized polynomials into sparse max-affine models. The error decay rate of RMD is shown to be exponentially small in its temperature parameter. Furthermore, theoretical guarantees for Sp-GD are extended to the bounded noise model induced by RMD. Numerical Monte Carlo results corroborate theoretical findings for Sp-GD and the initialization scheme.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.