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Quantum Advantage in Non-Interactive Source Simulation

Quantum Physics 2024-05-03 v2 Information Theory math.IT

Abstract

This work considers the non-interactive source simulation problem (NISS). In the standard NISS scenario, a pair of distributed agents, Alice and Bob, observe a distributed binary memoryless source (Xd,Yd)(X^d,Y^d) generated based on joint distribution PX,YP_{X,Y}. The agents wish to produce a pair of discrete random variables (Ud,Vd)(U_d,V_d) with joint distribution PUd,VdP_{U_d,V_d}, such that PUd,VdP_{U_d,V_d} converges in total variation distance to a target distribution QU,VQ_{U,V}. Two variations of the standard NISS scenario are considered. In the first variation, in addition to (Xd,Yd)(X^d,Y^d) the agents have access to a shared Bell state. The agents each measure their respective state, using a measurement of their choice, and use its classical output along with (Xd,Yd)(X^d,Y^d) to simulate the target distribution. This scenario is called the entanglement-assisted NISS (EA-NISS). In the second variation, the agents have access to a classical common random bit ZZ, in addition to (Xd,Yd)(X^d,Y^d). This scenario is called the classical common randomness NISS (CR-NISS). It is shown that for binary-output NISS scenarios, the set of feasible distributions for EA-NISS and CR-NISS are equal with each other. Hence, there is not quantum advantage in these EA-NISS scenarios. For non-binary output NISS scenarios, it is shown through an example that there are distributions that are feasible in EA-NISS but not in CR-NISS. This shows that there is a quantum advantage in non-binary output EA-NISS.

Cite

@article{arxiv.2402.00242,
  title  = {Quantum Advantage in Non-Interactive Source Simulation},
  author = {Hojat Allah Salehi and Farhad Shirani and S. Sandeep Pradhan},
  journal= {arXiv preprint arXiv:2402.00242},
  year   = {2024}
}
R2 v1 2026-06-28T14:33:55.923Z