Adaptive Sparse M\"obius Transforms for Learning Polynomials
Abstract
We consider the problem of exactly learning an -sparse real-valued Boolean polynomial of degree of the form . This problem corresponds to decomposing functions in the AND basis and is known as taking a M\"obius transform. While the analogous problem for the parity basis (Fourier transform) is well-understood, the AND basis presents a unique challenge: the basis vectors are coherent, precluding standard compressed sensing methods. We overcome this challenge by identifying that we can exploit adaptive group testing to provide a constructive, query-efficient implementation of the M\"obius transform (also known as M\"obius inversion) for sparse functions. We present two algorithms based on this insight. The Fully-Adaptive Sparse M\"obius Transform (FASMT) uses adaptive queries in time, which we show is near-optimal in query complexity. Furthermore, we also present the Partially-Adaptive Sparse M\"obius Transform (PASMT), which uses queries, trading a factor of to reduce the number of adaptive rounds to , with no dependence on . When applied to hypergraph reconstruction from edge-count queries, our results improve upon baselines by avoiding the combinatorial explosion in the rank . We demonstrate the practical utility of our method for hypergraph reconstruction by applying it to learning real hypergraphs in simulations.
Cite
@article{arxiv.2602.06246,
title = {Adaptive Sparse M\"obius Transforms for Learning Polynomials},
author = {Yigit Efe Erginbas and Justin Singh Kang and Elizabeth Polito and Kannan Ramchandran},
journal= {arXiv preprint arXiv:2602.06246},
year = {2026}
}