[Tanaka, Fujimoto, Saito]
The high-voltage amplifier tested in klog:37154 was inserted between the SR560 used in the PLL and the PZT of the sub-laser. By setting the SR560 gain to 1000 and the cutoff frequency of the Moku:Lab integrator to 1 kHz, and by adding a 10 kHz low-pass filter in Moku:Lab, the UGF increased to approximately 10 kHz. The 10 kHz low-pass filter was introduced because oscillations at around 85 kHz were observed in the error signal. However, under these conditions, no fringes could be observed on the OMC REFL PD during a PRX scan. Reducing the gain of the SR560 allowed the fringes to reappear, so the SR560 gain was changed to 200 and the cutoff frequency of the Moku:Lab integrator was reduced to 100 Hz. The LO frequency was then frequency-modulated with a sensitivity of ±30 MHz/V. As the external modulation signal, an 80 Hz, 800 mVpp sinusoidal waveform generated by a function generator was applied, and a PRX scan was performed to acquire data. Owing to an earthquake, it was not possible to obtain the current open-loop transfer function or data using a triangular-wave modulation signal, so these measurements will be carried out next time.
- First, the high-voltage amplifier tested in klog:37154 was inserted between the SR560 used in the PLL and the PZT of the sub-laser. Before introducing the amplifier, the SR560 gain had been set to 2000. Since the amplifier provided an additional gain of 10, the SR560 gain was reduced to 200, and it was confirmed that PLL operation was still possible. To increase the UGF beyond the previous value of approximately 1 kHz, the gain of the SR560 was gradually increased. However, oscillations appeared in the error signal at around 85 kHz. Therefore, a 10 kHz low-pass filter was added using Moku:Lab. With the SR560 gain set to 1000 and the cutoff frequency of the Moku:Lab integrator set to 1 kHz, the open-loop transfer function was measured, yielding a UGF of approximately 10 kHz (Fig. 1). An attempt was then made to perform a PRX scan, but no fringes were visible in the OMC REFL PD signal. When the gain of the SR560 was reduced, fringes became visible again in the OMC REFL PD signal. Therefore, the SR560 gain was set to 200 and the cutoff frequency of the Moku integrator was set to 100 Hz.
- Because the high-voltage amplifier enabled the PZT to be driven over a larger range, the frequency modulation sensitivity was increased to ±30 MHz/V. To drive the PZT as slowly as possible while maintaining a clean fringe shape, an 80 Hz, 800 mVpp sinusoidal waveform generated by a function generator was used as the external signal for frequency modulation. Data for both the OMC REFL PD signal and the external modulation signal were then acquired (Fig. 2).
- Due to an earthquake, it was not possible to obtain the current open-loop transfer function or the data corresponding to the case where a triangular-wave signal was used for frequency modulation. These measurements are planned for the next session.