Optimal Cloning of Quantum States with a Fixed Failure Rate

TL;DR

This paper investigates the optimal trade-off between failure rate and clone fidelity in quantum state cloning, showing that allowing some failure can improve clone quality, with optimal protocols involving measurement and preparation.

Contribution

It introduces the concept of Fixed Failure Rate (FFR) cloning, deriving the optimal fidelity for a pair of states and demonstrating the optimality of measure-and-prepare protocols.

Findings

Lower failure rates can be achieved at the cost of reduced fidelity.

Optimal protocols involve discrimination with fixed inconclusive outcomes.

Convergence exhibits a symmetry-breaking phase transition.

Abstract

Perfect cloning of a known set of states with arbitrary prior probabilities is possible if we allow the cloner to sometimes fail completely. In the optimal case the probability of failure is at its minimum allowed by the laws of quantum mechanics. Here we show that it is possible to lower the failure rate below that of the perfect probabilistic cloner but the price to pay is that the clones are not perfect; the global fidelity is less than one. We determine the optimal fidelity of a cloner with a Fixed Failure Rate (FFR cloner) in the case of a pair of known states. Optimality is shown to be attainable by a measure-and-prepare protocol in the limit of infinitely many clones. The optimal protocol consists of discrimination with a fixed rate of inconclusive outcome followed by preparation of the appropriate clones. The convergence shows a symmetry-breaking second-order phase transition in the fidelity of the approximate infinite clones.