Tilt Measurement at the Quantum Cramer–Rao Bound Using a Higher-Order Hermite–Gaussian Mode

Tilt Measurement at the Quantum Cramer–Rao Bound Using a Higher-Order Hermite–Gaussian Mode

The quantum Cramer–Rao bound (QCRB) provides an ultimate precision limit in parameter estimation. The sensitivity of spatial measurements can be improved by using the higher-order Hermite–Gaussian mode. However, to date, the QCRB-saturating tilt measurement has not been realized. Here, we experiment...

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Veröffentlicht in:Photonics 2023-05, Vol.10 (5), p.584
Hauptverfasser: Li, Zhi, Wang, Yijian, Sun, Hengxin, Liu, Kui, Gao, Jiangrui
Format: Artikel
Sprache:eng
Schlagworte:
Atomic force microscopy
Cramer-Rao bounds
Detectors
Electrons
Gravitational waves
Gravity
high-order Hermite–Gaussian mode
homodyne detection
Lasers
Light
Measurement
Microscopes
Observatories
Parameter estimation
Parameter sensitivity
quantum Cramer–Rao bound
Signal to noise ratio
tilt measurement
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Zusammenfassung:The quantum Cramer–Rao bound (QCRB) provides an ultimate precision limit in parameter estimation. The sensitivity of spatial measurements can be improved by using the higher-order Hermite–Gaussian mode. However, to date, the QCRB-saturating tilt measurement has not been realized. Here, we experimentally demonstrate tilt measurements using a higher-order HG40 mode as the probe beam. Using the balanced homodyne detection with an optimal local beam, which involves the superposition of high-order HG30 and HG50 modes, we demonstrate the precision of the tilt measurement approaching the QCRB. The signal-to-noise ratio of the tilt measurement is enhanced by 9.2 dB compared with the traditional method using HG00 as the probe beam. This scheme is more practical and robust to losses, which has potential applications in areas such as laser interferometer gravitational-wave observatories and high-sensitivity atomic force microscopes.
ISSN:2304-6732
2304-6732
DOI:10.3390/photonics10050584