Quantum-Processing-Assisted Classical Communications

Abstract: We describe a general quantum receiver protocol that maps laser-light-modulated classical communications signals into quantum processors for decoding with quantum logic. The quantum logic enables joint quantum measurements over a codeword. These joint measurements are needed to achieve the quantum limit of communications capacity. Our receiver design requires only logarithmically increasing qubit resources with the size of the codeword and accommodates practically relevant coherent-state modulation containing multiple photons per pulse. Focusing on classical-quantum polar codes, we outline the necessary quality of quantum operations and codeword lengths to demonstrate a quantum processing-enhanced communications rate surpassing that of any known classical optical receiver-decoder pair. Specifically, we show that a small quantum receiver of 4 qubits with loss rates of $\sim 2\%$ and quantum gate errors of $\sim 0.02\%$ can provide a $10$ percent gain in the communications rate in the weak signal limit. Additionally, we outline a possible hardware implementation of the receiver based on efficient spin-photon interfaces such as cavity-coupled diamond color centers or atomic qubits for which the required functionality has been experimentally verified, although not at the required error levels.