Quantum enhanced beam tracking surpassing the Heisenberg uncertainty limit

TL;DR

This paper demonstrates a quantum-enhanced beam tracking method using photon entanglement that surpasses the Heisenberg uncertainty limit, enabling more precise and resilient beam trajectory measurements at the single-photon level.

Contribution

It introduces a novel quantum entanglement-based technique for beam tracking that exceeds the traditional uncertainty bounds, with practical near real-time capabilities.

Findings

Achieves beam tracking beyond the Heisenberg uncertainty limit.

Works effectively at the single-photon level with existing technology.

Maintains accuracy despite background noise and bright disruptive beams.

Abstract

Determining a beam's full trajectory requires tracking both its position and momentum (angular) information. However, the product of position and momentum uncertainty in a simultaneous measurement of the two parameters is bound by the Heisenberg uncertainty limit (HUL). In this work, we present a proof-of-principle demonstration of a quantum-enhanced beam tracking technique, leveraging the inherent position and momentum entanglement between photons produced via spontaneous parametric down-conversion (SPDC). We show that quantum entanglement can be exploited to achieve a beam tracking accuracy beyond the HUL in a simultaneous measurement. Moreover, with existing detection technologies, it is already possible to achieve near real-time beam tracking capabilities at the single-photon level. The technique also exhibits high resilience to background influences, with negligible reduction in tracking accuracy even when subjected to a disruptive beam that is significantly brighter than SPDC.