Discriminating idempotent quantum channels
This work addresses an important open problem in quantum information theory by establishing the strong converse property for a specific family of quantum channels, with implications for quantum communication and computation.
The paper tackles the problem of discriminating between idempotent quantum channels, showing that when they share a common full-rank invariant state, an image inclusion condition determines asymptotic behavior, leading to explicit error exponents and the strong converse property, with perfect discrimination possible when inclusion fails. It applies results to GNS-symmetric channels, showing exponential convergence of discrimination rates, and provides a converse bound for channels without a common invariant state.
We study binary discrimination of idempotent quantum channels. When the two channels share a common full-rank invariant state, we show that a simple image inclusion condition completely determines the asymptotic behavior: when it holds, a broad family of channel divergences collapse to a closed-form, single-letter expression, regularization is unnecessary, and all error exponents (Stein/Chernoff/strong-converse) are explicitly computable with no adaptive advantage. Crucially, this yields the strong converse property for this channel family, which is an important open problem for general channels. When the inclusion fails, asymmetric exponents become infinite, implying perfect asymptotic discrimination. We apply the results to GNS-symmetric channels, showing discrimination rates for large number of self iterations converge exponentially fast to those of the corresponding idempotent peripheral projections. If the two channels do not share a common invariant state, we provide a single-letter converse bound on the regularized sandwiched Rényi cb-divergence, which suffices to establish a strong converse upper bound on the Stein exponents.