English

Approximate Computation via Le Cam Simulability

Statistics Theory 2026-01-01 v1 Computational Complexity Information Theory math.IT Statistics Theory

Abstract

We propose a decision-theoretic framework for computational complexity, complementary to classical theory: moving from syntactic exactness (Turing / Shannon) to semantic simulability (Le Cam). While classical theory classifies problems by the cost of exact solution, modern computation often seeks only decision-valid approximations. We introduce a framework where "computation" is viewed as the efficient simulation of a target statistical experiment within a bounded risk distortion (Le Cam deficiency). We formally define computational deficiency (δpoly\delta_{\text{poly}}) and use it to construct the complexity class LeCam-P (Decision-Robust Polynomial Time), characterizing problems that may be syntactically hard but semantically easy to approximate. We show that classical Karp reductions can be viewed as zero-deficiency simulations, and that approximate reductions correspond to bounded deficiency. Furthermore, we establish the No-Free-Transfer Inequality, showing that strictly invariant representations inevitably destroy decision-relevant information. This framework offers a statistical perspective on approximation theory, bridging the gap between algorithmic complexity and decision theory.

Keywords

Cite

@article{arxiv.2512.24860,
  title  = {Approximate Computation via Le Cam Simulability},
  author = {Deniz Akdemir},
  journal= {arXiv preprint arXiv:2512.24860},
  year   = {2026}
}
R2 v1 2026-07-01T08:46:55.220Z