Enhancing the Sensitivity of Quantum Fiber-Optical Gyroscope via a Non-Gaussian-State Probe

A theoretical scheme to enhance the sensitivity of a quantum fiber-optical gyroscope (QFOG) via a non-Gaussian-state probe based on quadrature measurements of the optical field is proposed. The non-Gaussian-state probe utilizes the product state comprising a photon-added coherent state (PACS) with photon excitations and a coherent state (CS). The sensitivity of the QFOG is studied and it is found that it can be significantly enhanced through increasing the photon excitations in the PACS probe. The influence of photon loss on the performance of QFOG is investigated and it is demonstrated that the PACS probe exhibits robust resistance to photon loss. Furthermore, the performance of the QFOG using the PACS probe against two Gaussian-state probes: the CS probe and the squeezed state (SS) probe is compared and it is indicated that the PACS probe offers a significant advantage in terms of sensitivity, regardless of photon loss, under the constraint condition of the same total number of input photons. Particularly, it is found that the sensitivity of the PACS probe can be three orders of magnitude higher than that of two Gaussian-state probes for certain values of the measured parameter. The capabilities of the non-Gaussian state probe in enhancing the sensitivity and resisting photon loss can have a wide-ranging impact on future high-performance QFOGs. This work investigates the sensitivity of a quantum fiber-optical gyroscope (QFOG) via a non-Gaussian-state (NGS) probe. It is found that the sensitivity of QFOG can be significantly enhanced by increasing the photon excitations in the NGS probe. It is demonstrated that the NGS probe exhibits robust resistance to photon loss. It is indicated that the NGS probe offers a significant advantage in the sensitivity over Gaussian-state probes, regardless of photon loss, under the same constraint condition. image