Scalable Quantum Network Determination with Einstein-Podolsky-Rosen Steering

Quantum networks of entangled end nodes serve stronger than the classical correlation for unparalleled quantum internet applications. However, practical quantum networking exists noise, at worst, causing end nodes to be described in pre-existing classical data. In such untrusted networks, determining the quantum network fidelity and genuine multi-node entanglement becomes crucial problems. Here, we theoretically and experimentally show that when the network nodes aim to be entangled in a star topology, detecting truly $N$-node Einstein-Podolsky-Rosen steering in networks with high noise tolerance requires only $N+1$ measurement settings. With this small experimental effort, steering detection determines the quantum network fidelity and genuine multi-node entanglement in the presence of untrusted measurement devices. Experimentally, using spontaneous parametric down-conversion entanglement sources, we demonstrate the determinations of genuine 3-photon and 4-photon quantum networks via genuine multi-photon steering and the false positives of the widely used entanglement witnesses. Our results help accurately evaluate setting up realistic entanglement-backbone quantum networks.