Zero-Error List Decoding for Classical-Quantum Channels
By: Marco Dalai, Filippo Girardi, Ludovico Lami
The aim of this work is to study the zero-error capacity of pure-state classical-quantum channels in the setting of list decoding. We provide an achievability bound for list-size two and a converse bound holding for every fixed list size. The two bounds coincide for channels whose pairwise absolute state overlaps form a positive semi-definite matrix. Finally, we discuss a remarkable peculiarity of the classical-quantum case: differently from the fully classical setting, the rate at which the sphere-packing bound diverges might not be achievable by zero-error list codes, even when we take the limit of fixed but arbitrarily large list size.
Similar Papers
Quantum Error Correction in Adversarial Regimes
Quantum Physics
Protects secret quantum messages from spies.
Polar Codes for Erasure and Unital Classical-Quantum Markovian Channels
Quantum Physics
Makes quantum computers send messages reliably.
On Strong Converse Bounds for the Private and Quantum Capacities of Anti-degradable Channels
Quantum Physics
Keeps secret messages safe from spies.