(Log for Friday's work)

To investigate the line noises and the low-frequency 1/f noise, whether they were actual magnetic field or sensing noise, I located the sensors at opposite direction (Y-direction) and checked their coherence and phase.
The spectrum shape is lmost the same for both channels.
There were large coherence (~1) for both the line noises and the low-frequency 1/f noise, and the phase was about 180 degree. So we can say these noises are actual magnetic field.

After these tests, I recoverd the sensor positions and directions to the original ones. (Hx for the X-direction, Hy for the Y-direction)

The FLDACCs for SRM moved back to the SR-OMC area from the BS area. I went to the second reassembly of the broken FLDACCs. #2 folded pendulum block was replaced with #8 block (Picture #1). The assembled pendulum looks fine (Picture #2).

Since newly added channels are not monitored by SDF, I started to monitor these channels as shown in fig1.

With Kenta Tanaka

We accepted SDFs caused by the works on klog36194.

[Takahashi, Ikeda]

We checked if the SDFs for VIS are 0. We attached MON flags to the SDFs that changed due to the model modification in SRM.

SDF of K1:IMC-SERVO_NPRO_TEMP_BIAS_OFFSET was changed from 5 of January.
Though laser work was conducted at that time (klog36019), there is no description on the laser temp bias changes and according to the working log, there seems no need to change temp bias.
So, I'm not so sure this change is related to this laser work.

Anyway, we confirmed IFO can be locked with the current EPICS values, I accepted the SDF shown in fig1.

[Miyoki]

The cleaning was done.

The water dropping above -X side of SRM continues. We put a wavy plastic plate and dust cloth to catch the water dropping. So we should be careful when  the top curtain will be opened.

I tried using the a2A5328-4gmPRO camera while it was occupying k1cam1.
But high-resolution and/or high-bit-depth recording still failed.
So using dedicated camera server doesn't become a solution for this issue
And also, either an upgrade of the network capacity or an allocation of dedicated bandwidth seems to be necessary.

-----
Bottleneck investigation
To isolate a network capacity issue from a server capacity issue, I moved all acA640-120gm cameras to k1cam0 and k1cam2, then tested a2A5328-4gmPRO while k1cam1 exclusively occupied by it. But capturing high-resolution and/or high-bit-depth images was still failed. Increasing buffer size of NIC from 256kB to 4096kB (upper limit) by ethtool didn't change a situation. In this configuration, a25328-4gmPRO should be able to occupy 1Gbps band-width on the NIC of k1cam1. And also, this situation isn't probably improved by using 10GigE NIC for k1cam1 because NIC of a25328-4gmPRO is 1GbE.

These facts suggest that a current limitation is actual throughput of a network path which can be occupied by a2A5328-4gmPRO. (I haven't isolated just a bandwidth issue from buffer size issue of each network switch.) Current connection of the CAM network is shown in Fig.1. Though the core camera switch in the server room on which all traffic concentrates is 10GigE one, edge switches except at IOO and connections are 1GbE. (Because all cameras in the corner station were connected from IOO rack in the past, only the edge switch at IOO is 10GigE one.) acA640-120gm which is main cameras for KAGRA GigE system is used with 640x480 as resolution, 8bit depth (Mono8) and 25fps. So ~60Mbps per 1 camera is required and 1Gbps bandwidth is enough to stably use 12-13 cameras (corresponding to ~70% of full bandwidth) and managing 18 cameras with 2 camera servers and one 10GigE core switch is sufficient.

a2A5328-4gmPRO is designed as using almost full width of 1Gbps to send caputured images (It's natural behavior because if bandwidth is limited as slower than 1Gbps, a risk of a connection time-out increases for high-resolution cameras such as a2A5328-4gmPRO.) So sharing bandwidth of 1GbE with another devices is not proper configuration for a2A5328-4gmPRO. If network paths will be shared, the CAM network should be upgraded to 10GigE for at least the shared paths with a2A5328-4gmPRO. Another solution is connecting a2A5328-4gmPRO to the core switch in the server room directly. But it may be more tough work than preparing a dedicated TCam server physically near a2A5328-4gmPRO.

Simple camera server application for a2A5328-4gmPRO
To capture images easily for this investigation, I prepared a simple camera server application as /kagra/camera/test-a2A5328-4gmPRO/test_CameraServer.py. It runs on one of camera servers (currently k1cam1) and listens various requests from CDS-workstations via the client application as /kagra/camera/test-a2A5328-4gmPRO/test_CameraClient.py. Because this server application keeps a connection to camera devices (keeping camera.Open()) same as camlan- and pylon-camera-server, this server application must be stopped before another applications connect to same camera devices. This application is now managed by the systemd in the user slice. So it can be stopped by a following command on k1cam1.
> systemctl --user stop test_CameraServer.service

2 FFUS were recoverd above SRM by reconnecting power/line cables near FFUs. 1FFU above SR3 and OMMT was still off maybe because of power/signal line disconnection.

Wrapped stainless steal floors near SR2 and SRM were repaired.

[Miyoki]

The Fujimi-sangyou member found a huge water pool on the ceiling just above the -X side of the SRM vacuum tanks. (Maybe Hayakawa-kun also noticed well before) (Photo.1)

Although the water drain pipe was set just around this pool, there seems to be no water flow in this drain pipe, maybe because something is stuck at some point. So we tried to drain this water along some possible paths by pushing up the water pool with several T-bars. Fortunately, about 70% water could be drained out. (Photo.2) We need to fix this drain system while the amount of water is small. 

[Hayakawa, Uchiyama, Takahashi-m, Sawada, Yamaguchi, Takahashi-r]

Fujimi-sangyo started cleaning of the SR-OMC area. 

Dan Chen, Misato Onishi

We conducted tests of the new laser for YPcal at University of Toyama.

An operational test was carried out, and we confirmed that the script currently used at YPcal can be applied almost without modification.

We verified the output power up to 20 W, and no issues were observed.

Regarding the noise performance, sufficiently low noise was achieved even without noise suppression by the OFS loop.

Further details are available here.

## What we did on 2026.02.27

We engaged the high-bandwidth ASCs for both P and Y directions. As soon as engaging ASCs, DHARD_{P,Y} started oscillated at some high-frequecies, 15-18 Hz. We tried to solve the issue by implementing a bandstop filter between 14-20 Hz. Then, the oscillations at their frequencies seems to be stoppped but sometimes 15 Hz oscillation raise up like glitch (fig.1). If the glitch was large, IFO got down. We found that IM actuator was saturated at this timing (fig.2) (When I wrote this log, I found TM was also saturated). Since we just use IM to damp the 3 Hz mode in Yaw but the feedback to IM above 3 Hz was not cut at that time, we implemented 3 Hz bandpath filter in FM2 of IM_LOCK_Y. Thanks to this, we avoid the IM actuator saturation (but TM was still saturated.) (fig.3) We succeeded in enhance the lock duration from several minites to 10-15 minites. However, lock loss itself by 15 Hz seems to be remained (maybe due to TM saturarion). So we implemented the 15 Hz notch filter for {D,C]HARD_{P,Y} instead of the bandstop filter.

Next, we found that the 2 Hz oscillation grow up 10-15 minites after ASCs were engaged (fig.4). As the 2.2 Hz oscillation was larger, L_RMS seems to get larger. At last, L_RMS surpassed the thereshold and the the IFO got down (fig.5). We found that ETMY Y still oscilllated even though ASC was already disengaged. We found only ETMY had no 2.1 Hz mode NBDAMP for some reason. So we implemented the damping control for 2.1 Hz mode in ETMY_NBDAMP_Y4 (fig.6). Then, 2.1 Hz oscillation seems to disappeared (fig.7).

After that, we measured the OLTFs of ARM DoFs, except for {D,C}SOFT_P (Sorry, I gave up to measure them last night). Fig.8, 9, 10, and 11 show the results of Yaw loops.

• As for C{HARD, SOFT}_Y, The gain in DC seems to be smaller than the ones when only Yaw HB ASCs were engaged.
• As for DSOFT_Y, we could not measure it well.
• As for DHARD_Y, the large 15 Hz peak appeared in the TF from OUT to IN1. Also, the shape of the TF above 10 Hz seems to be strange. 

Fig. 11 and 12 show the results of {D,C}HARD_P.

• In the DHARD_P OLTF (cyan line), the gain shape around 10 Hz seems to be strange. I found that I forgot to turned off the ITMX_TM_LOCK_P path. After that, we obtained the red lines. The strange shape at 10 Hz disappeared.
  • This time, I did not remeasure DHARD_Y TFs to check the effect of TM_P path, especially 10 Hz. We need to check it later.
• As for CHARD_P, TF structures seems to be changed. During the measurement, though we excited DHARD_Y but CHARD_P was excited more (fig.13).

Totally, some large couplings in the loops remains in the loops.

Now the causes of the lockloss are categorized to 2 topics; glitches, and 1.14 Hz oscillation.

• The glitches remains even after the above adjustement. One of the possibilites is that the control noise kickes the suspension. The DARM spectrum from 10 Hz to 100 Hz got worse whole the HB ASCs were engaged (fig.14) maybe becasue the attenuation by roll off is not enough in the MN stage. According to the cryopayload eignemode list (JGWdoc), at 15.88 Hz, there is the TM V mode. The MN_P feedback kick this? 
  • Or PR3 glitches in klog36437 was observed?
• As for 1.1 Hz oscillation, this oscillation appeared again after the above adjustement (fig.15). 

## Next (maybe after the achievement of the RSE LSC lock acquistion.)

• decouple sensors and actuators more precisely
• redesign hierarichal actuator including roll off in each stage to solve the glitch and oscillation issue.

Sorry, they were used for High-Bandwidth ASCs. I forgot to turned off them.

For now, we do not plan to use High-Bandwidth ASCs until the RSE commissioning. I'm not sure whether they are used in nominal PRFPMI lock. However PRFPMI could be locked either with or without them. So They can be turned off for now.  

I installed the signal generator box for the LVDT driver in the SRM rack (Picture #1). The amplitude of the 10kHz output was set to 7Vp-p. The cables from the SRM chamber (Picture #2) were connected to the LVDT distributor and the coil driver.

Ushiba-san, Yokozawa-san, Yuzurihara-san, DanChen-san, Ikeda

The task of clearing SDF differences prior to the model update was performed, but some differences remain.
These must be cleared by the responsible personnel before the power outage work begins.
I've attached some SDF captures from the real-time model connected to Dolphin.

The connections of Q and I for ReflPda1_56{Q,I} in the k1lsc model were swapped, so this has been corrected.
At present, the signals are internally terminated and not in use, so there is no impact from this correction.

[K1LSC0]
 k1lsc
  K1:ALS_PLL_LSC_REFL_PDA1_56_{Q,I}

Ushiba-san, R.Takahashi-san, Ikeda

The VIS model file described in K-Log#36374 has been installed.

[K1SRM]
 TOWER_MASTER
 PAYLOAD_MASTER
 k1vissrmt
 k1vissrmp
  The file prior to the modification was copied to the archive/ directory (20260216).
  Since the blocks were unified(related to K-Log#18595), resulting in a change in the DAQ data volume.

  DAQ_BYTE_COUNT
  k1vissrmt: 506 -> 398
  k1vissrmp: 422 -> 469
 

[Tanaka, Alex, Carl]

Yesterday we checked the IMC whitening of IMC REFL QPDA2. The board was wobbly. Pressing the board more firmly into the socket resulted in the whitening working correctly.  Photo shows the whitening board digital switch breakout in question (next to 1302082, not the in focus board).  diaggui screen live traces show all channels showing 2 stages of whitening engaged as the switch positions request (we also checked the raw inputs).  Noise level is higher than the reference traces as interferometer was in observe with 5W input while the reference traces interferometer was not locked and input with 1W.  First 3 reference traces show old no whitening state, 4th reference shows whitening at 1W.

We prepared to do jitter injections to remeasure coupling functions with the fixed QPD as witness sensors but were not able to take any measurements due to the earthquake in Russia.

I took the TCam photos for commissioning at 08:39 ~ 08:43 this morning. The previous work is klog and klog. 

• ITMY
  • original
  • fitting result
  • previous reference
• For these mirrors, I updated the reference positions. I also re-draw the yellow line shown at the k1mon4. For the other mirrors, we don't need to update the reference positions.