Three-party sequential communication tasks certify incompatibility of quantum instruments via violation of a tight classical bound, providing genuine semi-device-independent certification independent of component incompatibilities.
Demultiplexing Generalized Information via Quantum Transmission Lines
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abstract
Demultiplexers are the fundamental primitives of network architecture, enabling perfect routing of an input classical signal to a designated one, among multiple output ports. Quantum transmission lines, having access to the quantum systems directly, are able to transmit both the classical and quantum information encoded in quantum systems. A natural question therefore emerges that whether the scrambled classical and quantum information in a quantum system can be perfectly demultiplexed in the designated classical and quantum output ports? Here we answer this question by introducing a quantum to quantum-classical device, namely the quantum demultiplexer (Q-DEMUX). We characterize the class of Q-DEMUXs enabling perfect routing of both the classical and the quantum information along with their simple circuit realizations. Our results highlight an explicit connection between the strength of a Q-DEMUX with the incompatibility of quantum instruments. Finally, we extend the notion in a stronger variant where the sender is oblivious regarding the nature of the data to be transmitted through the Q-DEMUX.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
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Genuine certification of incompatible quantum instruments through sequential communication tasks
Three-party sequential communication tasks certify incompatibility of quantum instruments via violation of a tight classical bound, providing genuine semi-device-independent certification independent of component incompatibilities.