[Tanaka, Fujimoto, Saito]
The cutoff frequency of the high-pass filter in the SR560 used for the OMC REFL PD signal was reduced from 300 Hz to 30 Hz, allowing frequency sweeps to be performed at a slower rate. When the PLL UGF was increased to 10 kHz and the LO frequency was modulated to scan PRX, no fringes were observed on the OMC REFL PD. However, both the feedback signal and the beat signal appeared to be modulated properly. Therefore, the reason why no fringes were observed on the OMC REFL PD at a UGF of 10 kHz remains unclear. An alternative approach was also tested by scanning PRX through the addition of an offset signal to the error signal. As in the case of LO frequency modulation, no fringes were observed on the OMC REFL PD when the UGF was increased to 10 kHz. In addition, the feedback signal became distorted and no longer followed the waveform of the injected signal.
- First, after reducing the OMC REFL intensity noise for PRX and PRY (klog:37150), it was noticed that the cutoff frequency of the high-pass filter in the SR560 used for the OMC REFL PD had not been updated. Therefore, it was changed from 300 Hz to 30 Hz, allowing the frequency sweep to be performed more slowly.
- Next, with the PLL UGF set to approximately 1 kHz, the LO frequency was frequency-modulated with a sensitivity of ±15 MHz/V. An 800 mVpp, 300 Hz sinusoidal waveform generated by a function generator was used as the external modulation signal. Under these conditions, PRX was scanned and fringes were successfully observed on the OMC REFL PD. However, when the UGF was increased to approximately 10 kHz by increasing the gain of the SR560 used in the PLL, the fringes disappeared. The UGF was then returned to approximately 1 kHz, and the frequency of the external modulation signal was increased above 300 Hz. As the modulation frequency increased, the number of peaks observed on the OMC REFL PD also increased. Conversely, when the UGF was reduced below 1 kHz by decreasing the SR560 gain, the number of peaks observed on the OMC REFL PD decreased. Furthermore, even when the external modulation frequency was increased above 300 Hz with the UGF maintained at approximately 10 kHz, no fringes were observed on the OMC REFL PD. Nevertheless, the feedback signal at a UGF of 10 kHz showed the same modulation behavior as that at a UGF of 1 kHz, and the beat signal observed with the spectrum analyzer also appeared to vary as expected. Therefore, it remains unclear why no fringes can be observed on the OMC REFL PD when the UGF is increased to approximately 10 kHz.
- Finally, an attempt was made to scan PRX by adding an offset signal directly to the error signal. As shown in Fig. 1, a 20 Hz, 300 mVpp sinusoidal signal was added to the error signal. In Fig. 1, the red trace represents the error signal, while the blue trace represents the injected signal. As in the case of LO frequency modulation, increasing the UGF from approximately 1 kHz to approximately 10 kHz caused the fringes to disappear from the OMC REFL PD. In addition, the feedback signal became distorted and no longer matched the waveform of the injected signal (Fig. 2). The degree of distortion varied with time and occasionally became more pronounced. Furthermore, while measuring the open-loop transfer function, the feedback signal was found to become distorted whenever a low-frequency excitation signal was injected.