[Joshua, Tanaka, Disha, Fujimoto, Saito]
To perform the measurement proposed in klog:37169 using the beat signal at the OMC REFL, a new RFPD was installed at OMC REFL. After injecting the sub-laser into PRX and engaging the PLL, the beat signal was successfully observed with the newly installed RFPD. The amplitude and frequency of the beat signal both fluctuated, making it difficult to finely adjust the LO frequency to maximize the beat signal. However, since both the resonance and anti-resonance points were successfully identified, we plan to reduce the effect of these fluctuations by increasing the number of averaging frames on the spectrum analyzer. The beat frequency will then be determined by measuring the minimum and maximum frequencies at which the beat-signal amplitude begins to decrease.
- The reflected beam from the BS in front of the OMC REFL camera had previously been dumped, so this beam was utilized for the measurement. First, the beam dump was removed, and the beam power was measured to be approximately 3 mW using a power meter. A mirror, a lens with a focal length of 50 mm, an OD = 0.5 ND filter, and an RFPD were then installed (Fig. 1). The lens was inserted to focus the beam onto the RFPD, while the ND filter was used because the maximum allowable input power to the RFPD is 1 mW. The optical power measured immediately before the RFPD was approximately 0.95 mW. The alignment was then adjusted to maximize the DC output of the RFPD.
- Next, the sub-laser was injected into PRX, the PLL was engaged, and the beat signal was observed using the RFPD installed at OMC REFL. The beat signal was successfully detected. However, it was difficult to finely adjust the LO frequency used for the PLL to maximize the beat signal because both its amplitude and frequency fluctuated. Therefore, the LO frequency was swept by ±3 MHz around 160.4 MHz at a rate of 10 mHz. Under these conditions, both the resonance point (Fig. 2) and the anti-resonance point (Fig. 3) were observed. The spacing between adjacent resonance points was approximately 2.2 MHz. Based on these results, we plan to increase the number of averaging frames on the spectrum analyzer to suppress the influence of the fluctuations and determine the beat frequency by measuring the minimum and maximum frequencies at which the beat-signal amplitude begins to decrease.