Sufficient conditions for quantum advantage in random access code protocols with two-qubit states

• URL: http://arxiv.org/abs/1912.09900v6
• Date: Thu, 20 Jul 2023 13:43:52 GMT
• Title: Sufficient conditions for quantum advantage in random access code protocols with two-qubit states
• Authors: Som Kanjilal, C Jebarathinam, Tomasz Paterek, Dipankar Home
• Abstract summary: Random access code (RAC) is an important communication protocol. We consider either communication of quantum bits or a shared-in-advance quantum state used in conjunction with classical communication. For $n geq 4$ RACs assisted with a single copy of a quantum state do not outperform the classical RACs.
• Score: 1.0323063834827415
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Random access code (RAC) is an important communication protocol to obtain information about a randomly specified substring of an n-bit string, while only having limited information about the n-bit string. Quantum RACs usually utilise either communication of quantum bits or a shared-in-advance quantum state used in conjunction with classical communication. Here we consider the latter version of the quantum protocols under the constraint of single-bit communication and with shared arbitrary state of two qubits. Taking the worst-case success probability as the figure of merit, we demonstrate that any state with invertible correlation matrix can be used to outperform the best classical RAC for n=3. We derive an additional condition sufficient to beat the best classical performance in the case of n=2. In particular, separable states turn out to be a useful resource behind the quantum advantage for n=2,3. For $n \geq 4$ RACs assisted with a single copy of a quantum state do not outperform the classical RACs.

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