The SRM GRD says "GAS is close to saturation (F0)".
The K1:VIS-SRM_F0_COILOUTF_GAS_OUTPUT is ~25100 counts now.
I updated the Pcal guardian code based on the preparation report from Jinshui Tian and Yuli Liang.
We incorporated the minor improvements discussed so far.
A detailed report will follow.
Tanaka, Aritomi
We succeeded in locking DRMI with 1F signals and also in engaging ADS for DRMI (IMMT2, PRM, BS, and SRM). We measured Open loop TFs of DRMI DoFs (PRCL, SRCL, MICH). Current Lock duration is at most 20 mins. However, the lock can be restored automatically soon. According to the results, there seem to be some couplings between the DoFs. Anyway, It is enough duration to characterize DRMI more finely.
We checked the current DRMI lock with 1f and 3f mixtur configuration (PRCL:3f, MICH, SRCL:1f, (ref. Takano-san's summary slide)). DRMI could be locked with this configuration but some offsets are necessary as setpoints of errro signals. And lock duration seemed to be short, less than 10 sec. We performed try and error to improve the duration. Eventually, we tried to change PRCL error signal from 3f (REFL135I) to 1f (POP45I) and succeeded in DRMI lock with 1f signal. This time, we changed the sign (3f:+ -> 1f:-) and increased the gain (3f:1 -> 1f:30). Also, we implemented the roll-off filters in loops. Moreover, There seems to be some offsets in error signals
After that, we measured OLTFs of their loops.
Fig.1 shows the PRCL OLTF, red shows the one in locking DRMI with the 1f signal and brue shows the one in locking PRMI with the 1f signal. According to KAGRA schnupp asymmetry, RF45 at AS port should be dark. So the PRCL response should not be changed if we use RF45 for PRCL, that is, the PRCL OLTF in locking DRMI should not be changed from the PRMI one. In this sense, the shape of red gain TF seems to be almost same as the brue one. However, as for the overall gain, we did not tuned finely. So the change of the overall gain is fine. On the other hands, phase TF seems to be changed from the PRMI one. This indicates there are some coupling between PRCL and other DoFs for some reason (MICH detune? upper/lower sideband asymmetry?)
Fig.2 and 3 show the MICH and SRCL OLTFs, respectively. Reds are the ones in locking DRMI, and blues are the ones in locking SRMI. OLTF could not be measued well maybe due to large coupling between DoFs.
After that, we tried to implement ADS for DRMI. I expected that the response of the RF45 build up power, POP90 shoud not be changed by the SRM exsitance. In this case, I assumed that only SRM ADS should be tuned and tuning for others is not necessary. I chosed AS34 as SRM ADS signal in locking DRMI and performed the phasing of the signals. Then we obtained the demod. phases of SRM ADS PIT:-174 deg(Fig.4), and YAW:170 deg(Fig.5). Thanks to the phasing, Q signals seems to become 0 after the phasing (Fig.6). They seem to be fine.
I engaged SRM ADS at the same time as BS, PRM, and IMMT2 ADSs after DRMI was locked. Fig. 7 shows the time series of ADS error/feedback signals and build up power in PRC (POP90) and SRC(AS34). After calming down the feedback signals, especially SRM YAW, POP90 and AS34 seems to be improved.
Now, the lock duratiion of DRMI with ADS is at most 20 mins (fig.8). For now, we do not investigate the cause of lock loss. Tomorrow, we will perform the DRMI characterization.
The fitting results for the individual PRY resonance peaks presented in klog:37209 are summarized below. The measurement data are stored in Dropbox → All files/Dropbox KAGRA/Measurements/IFO/PRCL/PRCL_OMC_REFL_beat_signal_LO_sweep/2026_07_14_PRY.
The fitting results for the individual SRY resonance peaks presented in klog:37209 are summarized below. The measurement data are stored in Dropbox → All files/Dropbox KAGRA/Measurements/IFO/SRCL/SRCL_OMC_REFL_beat_signal_LO_sweep/2026_07_14_SRY.
[Kimura and Yasui]
On July 15, as part of maintenance work on the cryogenic cooling units, we set up two valve units for the radiation shield cryo-coolers (IXC P-53 and IXC P-55).
The remaining tasks are filling the system with G-1 class helium gas up to 15 bar and performing leak tests on all connections.
Saito-kun,
Could you upload the overplot graphs of the raw data and the fitting functions similar to fig 2 and 3 in klog37201?
[Aritomi, Ushiba, Tanaka, Saito]
Sub-laser light was injected into the SRY, PRY, PRX, and SRX, and a PLL was established. The LO frequency was then swept to scan the beat signal. Using the maximum hold function of the Moku:Lab spectrum analyzer, transmission power as a function of frequency was recorded around 190 MHz, 160 MHz, 140 MHz, −140 MHz, −160 MHz, and −190 MHz. The data were fitted both with and without a linear background, and the maximum and minimum peak frequencies within the corresponding fitting uncertainties were determined. The cavity lengths were then calculated from these results. The differences between the measured cavity lengths and the design values were 0.15 ± 0.33 cm for PRY and 1.58 ± 0.82 cm for SRY. Therefore, the PRY measurement is consistent with the design value within its uncertainty of 0.33 cm, whereas the SRY measurement differs from the design value by more than the estimated uncertainty, suggesting that the actual cavity length may differ from the design value. The results for PRX and SRX will be reported after the analysis is completed.
For the data near each resonance peak, fitting was performed both with and without a linear background, following the same procedure as in the previous analysis (klog:37201). From the fitted peak frequencies and their uncertainties, the maximum and minimum frequencies within the fitting uncertainty were determined. The overall uncertainty range was then defined as the largest and smallest values obtained from both fitting models. The following data were used to determine the PRY and SRY cavity lengths.
PRY
Minimum (MHz) Maximum (MHz)
186.9049 186.9561
163.8426 163.8974
131.4761 131.5159
-115.5105 -115.4909
-157.0807 -157.0589
-189.4049 -189.3442
SRY
Minimum (MHz) Maximum (MHz)
186.8354 186.9305
166.0559 166.2530
131.4035 131.4918
-127.2003 -126.2609
-159.4324 -159.3557
-189.3570 -189.2707
From the measurement results, the midpoint between the minimum and maximum frequencies was calculated for each resonance. These midpoint frequencies were divided by the FSR calculated from the design cavity lengths (64.9265 m for PRY and 64.9264 m for SRY). The resulting values were rounded to the nearest integers, and the measured frequencies were fitted with the linear function AN+B, where A and B are fitting parameters and N is the rounded integer. The fitting results were as follows.
PRY (Fig. 1)
A: 2.30865 ± 0.00012 MHz
B: −0.0741 ± 0.0074 MHz
SRY (Fig. 2)
A: 2.30815 ± 0.00029 MHz
B: −0.092 ± 0.021 MHz
Since A corresponds to the FSR, the cavity lengths were calculated from the fitted values of A.
PRY
Measured cavity length: 64.9280 ± 0.0033 m
Design value: 64.9265 m
Difference (measured − design): 0.15 ± 0.33 cm
SRY
Measured cavity length: 64.9422 ± 0.0082 m
Design value: 64.9264 m
Difference (measured − design): 1.58 ± 0.82 cm
Therefore, the PRY measurement is consistent with the design value within the uncertainty of 0.33 cm. In contrast, the difference between the measured and design values for SRY exceeds the estimated uncertainty, suggesting that the actual SRY cavity length may differ from the design value. The results for PRX and SRX will be posted once the analysis has been completed.
With Misato Onishi, Yuli Liang, Jinshui Tian
We installed 2 QPDs in Rx module on 7/14 for the Pcal beam monitoring.
And, I took Tcam data with changing Pcal beam positions by the pico PCAL_EY2 in the 7/15 morning.
The data will be analysed to check the QPD performance.
With Dan Chen, Yuli Liang, Jinshui Tian
We continued the work from the previous day. (37183)
Before starting the work, we recorded the alignment of the current YPcal laser using the previously prepared reference setup.
We reduced the power of the main beam path of new laser using HWP before performing the alignment work.
We aligned the beam from the new laser and successfully extracted it from the Tx module.
At the end of the work, we turned on the current laser and checked the beam position on the RxPD.
No significant change was observed, indicating that the installation and alignment work had not affected the alignment of the existing laser.
I collected the high-power coil driver (HPCD) from EYV (S1604763) and brought it back to Mozumi.
According to Saito-kun, HV amp (x10) was directly connected to the laser PZT input for the PLL lock. According to my past experiences, the direct connection tends to excite PZT at high frequency.
To solve this problem, we inserted a passive LPF that is set as one of the filters for the control servo between the PZT input and the HV. According to my memory, 10Hz ?? LPF and 100kHz?? LPF were used as one of the control filters. So what I can suggest is to set a passive LPF btw the PZT and the HV, and remove the same LPF in the control filters. I have a ponoma case and a film condenser (400V?) in my room.
Another concern is that the UGF at 10kHz for the PLL control might to excite some resonances of the PZT as in the main laser frequency stabilization servo.
I performed the initial alignment Xarm, Yarm, OMC, PRMI and SRY.
[Aritomi, Ushiba, Tanaka, Saito]
The sub-laser was injected into SRY, and the PLL was engaged while the LO frequency was swept to scan the beat signal. Using the maximum hold function of the Moku:Lab spectrum analyzer, the SRY transmitted power was recorded as a function of frequency. Because the slopes on the two sides of the resonance peak were different, the data were fitted both with and without a linear background offset. The two fitting methods yielded resonance frequencies differing by approximately 47.9 kHz. If this difference is regarded as the fitting uncertainty, it is comparable to the measurement uncertainty reported previously (klog:37191). The PLL UGF was then reduced to narrow the beat-signal linewidth, and the measurement and fitting procedure was repeated. However, the fitted resonance frequencies with and without a linear background offset differed by approximately 143 kHz, indicating that the fitting uncertainty was not improved. To achieve more accurate fitting, it will likely be necessary to suppress fluctuations in the beat-signal amplitude and reduce the influence of higher-order modes.
[Jinshui Tian, Yuli Liang, Dan Chen]
On 2026/07/09, we updated the Pcal Reconstruction model for both EX and EY so the output Pcal beam position is consistent with the calculation in the paper: Performance of the KAGRA photon calibrators during the fourth joint observing run with LIGO and Virgo - IOPscience.
We deployed the updated model files into the production environment via k1ctr27 (replacing the original files) and confirmed the GRD and SDF statuses.
We then recompiled, installed, and restarted the front-end models as follows:
EX Model (k1ex0):
ssh k1ex0
cdscode
make k1calex
make install-k1calex
startk1calex
EY Model (k1ey0):
ssh k1ey0
cdscode
make k1caley
make install-k1caley
startk1caley
From ndscope, observable value steps were noted on the following channels:
EX Channels: K1:CAL-PCAL_EX_A_X_MON & K1:CAL-PCAL_EX_A_Y_MON at GPS: 1467955200 s
EY Channels: K1:CAL-PCAL_EY_A_X_MON & K1:CAL-PCAL_EY_A_Y_MON at GPS: 1467956800 s
We plan to calculate and compare the pre- and post-update channel data tomorrow.
[ Yasui, Oshino, Nakagaki ]
We have installed a system to monitor the open/closed status of the manual gate valve between PRM and PR3.
The open/closed status is provided via the following PVs:
K1:VAC-GV_PR3_OPEN
K1:VAC-GV_PR3_CLOSE
These have also been added to the `VAC_OVERVIEW` MEDM screen.
Since we were unable to test the valve in the closed position today, we will conduct that test at a later date.
Because the LPD values went down in these days, Pcal GRD went to FAULT state today.
I think this is caused by the instability in the laser source.
So I changed the threshold value from 3.3 to 3.0.
I compared the spectra in the IRM damper servo ON/OFF again. The IP was excited in yaw with the IP actuators. The servo gain was increased from 1.5 to 2. Although the peak around 60 mHz was damped by the servo, the RMS reduction was small due to the resonance at 160mHz.
I collected the high-power coil drivers (HPCDs) from IXV (S1604827) and IYV (S1706250) and brought them back to Mozumi.
I collected the high-power coil driver (HPCD) from EYV (S1604763) and brought it back to Mozumi.