Passive resonant laser gyroscope with improvement of the suppression of residual amplitude modulation effects through correlation analysis

Passive resonant gyroscopes (PRGs) utilizing the Pound-Drever-Hall (PDH) method are expected to have a lower shot-noise limit in rotational rate measurement. However, there are also many technical obstacles in the way to touch the intrinsic noise floor. In this article, we find that the residual amplitude modulation (RAM) effect in the phase locking process deteriorates the accuracy and stability of the output signal of PRGs, and becomes a dominant limiting factor, especially in the low-frequency range. Since the suppression is not good enough in the PRGs due to the strict requirements, we propose to use the Pearson correlation coefficient to evaluate the correlation between the RAM signal and the PDH signal to achieve a sufficient correlation before active servo control. With the implementation of this improvement, the RAM-induced fractional frequency stability for the 12 m optical ring cavity is reduced down to 1.2 x 10(-18). The contribution of the RAM effect to the rotational sensitivity of our 3 m x 3 m PRG is lowered to 8.0 x 10(-9) rad s(-1) root Hz(-1) at 1 mHz, which is one order of magnitude better than the unconstrained situation. With this upgrade, a rotational resolution of 5.2 x 10(-10) rad s(-1) of the PRG is achieved, which is the best performance among all PRGs so far.

Automated summary

Passive resonant gyroscopes (PRGs) utilizing the Pound-Drever-Hall (PDH) method have a lower shot-noise limit, but technical obstacles hinder reaching the intrinsic noise floor. This article shows that the residual amplitude modulation (RAM) effect in the phase locking process hampers accuracy and stability of PRGs' output signals, especially at low frequencies. To overcome this, the Pearson correlation coefficient is proposed to evaluate the correlation between the RAM signal and PDH signal, achieving better performance in rotational sensitivity and resolution.