English

Near-Optimal and Tractable Estimation under Shift-Invariance

Statistics Theory 2025-01-13 v2 Classical Analysis and ODEs Machine Learning Statistics Theory

Abstract

How hard is it to estimate a discrete-time signal (x1,...,xn)Cn(x_{1}, ..., x_{n}) \in \mathbb{C}^n satisfying an unknown linear recurrence relation of order ss and observed in i.i.d. complex Gaussian noise? The class of all such signals is parametric but extremely rich: it contains all exponential polynomials over C\mathbb{C} with total degree ss, including harmonic oscillations with ss arbitrary frequencies. Geometrically, this class corresponds to the projection onto Cn\mathbb{C}^{n} of the union of all shift-invariant subspaces of CZ\mathbb{C}^\mathbb{Z} of dimension ss. We show that the statistical complexity of this class, as measured by the squared minimax radius of the (1δ)(1-\delta)-confidence 2\ell_2-ball, is nearly the same as for the class of ss-sparse signals, namely O(slog(en)+log(δ1))log2(es)log(en/s).O\left(s\log(en) + \log(\delta^{-1})\right) \cdot \log^2(es) \cdot \log(en/s). Moreover, the corresponding near-minimax estimator is tractable, and it can be used to build a test statistic with a near-minimax detection threshold in the associated detection problem. These statistical results rest upon an approximation-theoretic one: we show that finite-dimensional shift-invariant subspaces admit compactly supported reproducing kernels whose Fourier spectra have nearly the smallest possible p\ell_p-norms, for all p[1,+]p \in [1,+\infty] at once.

Keywords

Cite

@article{arxiv.2411.03383,
  title  = {Near-Optimal and Tractable Estimation under Shift-Invariance},
  author = {Dmitrii M. Ostrovskii},
  journal= {arXiv preprint arXiv:2411.03383},
  year   = {2025}
}

Comments

30 pages; corrected some minor typos and added the quasi-stability assumption in Section 2.3

R2 v1 2026-06-28T19:49:22.161Z