Conclusive Identification Via Noisy Classical Channel: Superactivation and Quantum Advantage
Abstract
We introduce conclusive identification task for classical channels: a receiver identifies transmitted inputs without error when possible, and responds inconclusively when outputs are ambiguous. For a symmetric not-fully-corrupted channel N : X X, the single-shot conclusive identification index ci(N) counts the maximum number of conclusively identifiable inputs. We show ci(N) exhibits a striking superactivation phenomenon: a channel with ci(N) = 0 achieves ci(N idcβ) = |X| when assisted by a perfect classical channel of dimension β < |X|. The minimum classical assistance required equals the chromatic number (SN) of the channel's support graph SN. We provide channel families where the superactivation gap ci(N idcβ) - ci(idcβ) can be made arbitrarily large. A noiseless quantum channel of dimension equal to the orthogonal rank (SN) suffices, yielding a strict quantum advantage whenever (SN) < (SN). This advantage is demonstrated through three explicit constructions motivated by combinatorial and algebraic state-independent, and state-dependent proofs of Kochen-Specker contextuality. Via the co-normal product of graphs, we analyze the scaling of the quantum advantage ratio f(SN)/(SN), and present a channel for which quantum assistance is exponentially more efficient than classical. Our results establish SN, rather than the confusability graph GN, as the natural combinatorial object for conclusive identification, revealing that channels deemed useless under Shannon's zero-error framework can exhibit rich superactivation and quantum advantage, with deep connections to quantum contextuality.
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