david.barker@LIGO.ORG - posted 11:47, Monday 30 March 2026 (89697)
Mon CP1 Fill
Mon Mar 30 10:08:08 2026 INFO: Fill completed in 8min 5secs
Images attached to this report
Mon Mar 30 10:08:08 2026 INFO: Fill completed in 8min 5secs
Attached to this alog are the Omicron glitch rate compariosns between O4a, O4b, and O4c. I am posting just for the record, but this was also presented at the LVK in Pisa (see here). For the comparisons, I used roughly about ~3240 hours of observing time (denoted by the H1:DMT-ANALYSIS_READY:1 flag). The exact GPS times used for the analysis were:
O4a: 1372611618 - 1389484818
O4b: 1397692818 - 1422118818
O4c: 1422118818 - 1447502418
The first attached plot shows the glitch rate across each observing period, which includes glitches with an SNR > 7.5, and frequency between 10 Hz - 1024 Hz. The rate was the highest in O4a, at around ~38 glitches per hour. The subsequent glitch rates for O4b/c were lower and similar levels, coming in at around ~11 glitcher per hour and ~10 glitches per hour. In O4a, the glitch rate was high due to increased non-stationary noise from ~10 Hz - 50 Hz (see alogs 71005 & 71092). The following two plots show the glitch rates as a function of SNR and frequency. Most glitches had an SNR below 50, and frequency below 50 Hz.
[Tom, Sophie, Ibrahim, Betsy] Thursday, Friday and Saturday of last week we assembled a batch of 4 QOSEM In-Vac cables (D2500311) for use at LLO on the BBSS. All cables have passed electrical testing. On Sunday, Betsy cleaned and began an airbake on the cables, and they have now begun there vacuum bake, which should finish Wednesday evening.
TITLE: 03/30 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
OUTGOING OPERATOR: None
CURRENT ENVIRONMENT:
SEI_ENV state: MAINTENANCE
Wind: 14mph Gusts, 10mph 3min avg
Primary useism: 0.03 μm/s
Secondary useism: 0.13 μm/s
QUICK SUMMARY:
IFO is in IDLE for PLANNED MAINTENANCE
An earthquake tripped some watchdogs - untripped now.
Plans this week prep BHSS and SPI in Optics lab and continue BSC2 platform install.
Sun Mar 29 10:10:19 2026 INFO: Fill completed in 10min 16secs
I've found that the pico mount for 50:50 BS on the REFL WFS sled in front of ASC REFL_A was loose and rotated counter-clockwise seen from the top by a huge amount (1st attachment, orange arrows show the direction of rotation). Our guess is that the BS mount was bumped when we were leaning into HAM1 from -Y door to work on the JAC output periscope. In general, it's hard to rotate the mount clockwise seen from the top even if the screw is not super tight (because the screw tends to be tightened), but it's easier to go counter-clockwise.
When this was found, the beam was hitting the +X-Y edge of the mirror, there was no clear reflection beam found so no beam on WFSA, but somehow the ugly transmission beam with lots of diffraction patterns was making it to WFSB.
We reverted the RM1 and RM2 bias sliders back to O4 level (RM1 PIT=-180, YAW=-57, RM2 PIT=890, YAW=-530) and I confirmed that the centering on the 2" lens was good. WFSA mount was screwed down tight to the post.
RM1 bias was adjusted further (RM1 PIT=-190, YAW=263) to roughly center the beam on WFSB.
At this point I looked at the beam on WFSA and it was still off mostly in YAW but there was also a large PIT offset. These were taken care of by adjusting the picos I've just screwed down.
I enabled the REFL WFS centering which worked right away. LSC REFL diodes are receiving almost equal amount of light. We'll have to make sure that the beam is not clipped on LSC diodes. Anyway, I relieved the ASC using RM sliders and ended up these numbers: RM1 PIT=-192, YAW=274, RM2 PIT=910, YAW=-532.
Making sure that the beam is centered-ish on the LSC sensors
We enabled the WFS DC centering, relieved the WFS output by RM sliders, disabled the WFS centering. Then scanned RM1 in PIT to find out where the LSC REFL A and B DC starts to fall off, and make an average position in terms of RM1 PIT offset ("plateau center"). In general the plateau center is not the same as WFS DC center.
Use the common pico for the REFL LSC sensors to make the plateau center come closer to the WFS DC center. See the 1st attachment.
Repeat the same thing for YAW. We noticed that LSC REFL B is not exactly the mirror image of REFL A, mostly horizontally, as you can see from the 2nd attachment. If they are, we expect both to start falling at the same time but they don't. To fix that we need to touch up the non-pico 50:50 splitter that steer half of the beam to REFL B, but we chose not to do it because the scan range you see here is huge, and beam will totally fall off of WFSB before LSC REFL A and B starts falling.
After all of these and minor tweaks here and there, we ended up with: RM1 P = -196, Y=281, RM2 P=910, Y=-490.
Tilting WFSA in YAW
I checked the beam position along the REFL path and unfortunately the reflection from WFSA was hitting the mirror mount. I tilted the WFS clockwise, paying attention NOT to change the optical path length significantly. After this, Jason and Jennie used pico to steer the beam back to the center of WFS. I confirmed that the WFSA reflection goes into the beam dump.
Final check
I rechecked the beam position along the REFL path. Nothing was grossly off-centered except for 1" mirrors and BS on the WFS sled (this was always the case).
On M2, RM1 and M5, the beam position looked OK though it was hard to say anything quantitatively. No picture for these.
1" lens for the LSC censors, 2" lens on the WFS sled as well as 1" lens on the WFS sled looked good.
Reflection of all LSC and ASC REFL sensors fall on the beam dumps.
Pictures will follow.
I looked at the POP path too but it wasn't flashing and it was already 4PM so we gave up. We'll continue on Monday.
Correction: In the above alog text, "LSC_REFL_B_ghost.jpg" points to the picture for REFL_A ghost beam. This is the correct one: LSC_REFL_B_ghost.jpg.
Sat Mar 28 10:07:24 2026 INFO: Fill completed in 7min 21secs
We're getting <HIHI, MAJOR> alarm about H1:PEM-CS_DUST_LAB2_300NM_PCF, which I cannot trend using NDSCOPE, but I can plot H1:PEM-CS_DUST_LAB2_300NM_RAW and that number has been 30[V?] for the past 6 days.
I've silenced it but could somebody check?
Not sure why this would be alarming today, it has been invalid for many weeks. The 0.3um raw counts went from 0 to 30 last Sunday 15:34 22mar2026, but it looks like the calibrated counts-per-cubic-foot has been NAN or INF for a very long time, which is why it cannot be trended with ndscope.
Perhaps the alarms system was recently restarted and DUST2 is regularly acknowledged on startup?
This station (PCAL lab/LAB2) doesn't even have a device connected currently. There have been connections issues here for the past few months that I haven't tracked down yet. I'm not sure why it would have restarted to alarm, but I'll comment this station out of the ioc startup for now.
[Jenne, Jennie, Keita, Jim, Sheila, Betsy]
Sum up: We're aligned pretty similarly to a reference time of [ 14 March 2026 02:20:00 UTC ], which is an "IR Found" time in between DRMI locks. We're back in the same place on IM4 Trans QPD as well as both forward-going POP QPDs. We have some mediocre PRX flashes. We are back (in the REFL path) on the same 3 of 4 PDs that we were before re-venting, so we should be in a good place for the team to work on REFL path things tomorrow.
Some details:
The 4 attachments have vaguely descriptive names. The one from March 14th is my reference time, and then probably the other one that is useful to look at is the End of Day where I left things. I'm not sure I was seeing PRX flashes at the very very end of the day, so PRM might need some adjustment in the morning. The other two attachments are showing where the suspensions were before I started, as well as showing that I first got back to the reference time osem positions.
Jennie W, Keita, Betsy, Jason,
Betsy and Jason rolled up IOT1 this afternoon and Keita tweaked the alignment from the top periscope mirror to the DCPDs with the PSL output at 2W. He also re-aligned the trigger PD.
We can now lock JAC in air with the double door cover so we can have the light exiting the chamber but most of the door covered above and below where the beam exits.
I had to run the 'normalise signals guardian state after we closed the table and turned the light off, probably because the signal on REFL PD changed.
We left the light pipe closed and both doors covered at the end of the day.
NB: I accidentally pinged the HAM1 -Y side large table beam dump plate (the one that would catch the scatter from the JAC REFL viewport) with one of the small paper clips we use to hold the two door covers to each other. I will wipe this down tomorrow.
I turned the power down to 100mW at the end of the day using the rotation stage.
Today, Keita and Oli turned up the power to the fiber again so we are getting about 30 mW out. This is enough power that you can see the beam transmit the input coupler of the OMCs easily on a card. With the room lights dim, you can see flashing of the beam at both DCPDs with a card. Using the IR sensitive camera, we are able to fine tune the input alignment further.
The beam has been well-aligned to OMCA, and the flashing present at the DCPDs looks mostly like mode mismatch, which makes sense because we made no effort to mode-match our input beam to the OMCs.
The beam alignment to OMCB still needs some work. It looks predominantly like a yaw misalignment, so we need to make some finer adjustments of the upstream optics.
Since all of the BHSS optics have been pre-angled using the clocking tool, I followed the map on slide 86 of T2100190 to place the lenses, mirrors and beam dumps. Just by eye, I can tell we will need to fine tune this alignment further once we have laser beam. I was unable to place one beam dump because it goes roughly where we are pooling the OMCA cables. Once we can route and clamp those cables properly, there will be room for the dump. I haven't placed the QPDs yet, they are still bagged. I also placed the three head optics randomly, since they can't be placed until the OMC iris template is removed.
As a reminder, the order of operations here is to use the iris alignment template to get good input alignment to both OMCs. Then, this template is removed so we can use other precision templates to align the three optics that go at the head of the manta ray: mirrors A/B-R1 and 36-R1. Then, we can finish the rest of the beam paths to the OMC QPDs.
I took a phone video of OMCA flashing and managed to screengrab these two photos from the videos: DCPDA, DCPDB
I returned to the slider positions where we had good green and IR flashes in the filter cavity from Wed 89629. Since this time of good flashes the H:M2 pico was reverted to 0 (it's setting during in chamber work), so the green flashes weren't as high as they were on Wed. Screenshot attached here. In this alignment I went to SQZT7 and looked at the green reflection, it looks like an oval but is coming to the persicope. (photo)
While at the table, I moved the picomotor for H:M2 X to -710, which is where Tony and I had put it 89596 and where we had both IR and green flashes good. I could see the beam move on SQZT7, but it wasn't a big move, and after pico'ing it looks like we still have an oval beam making it to the table.. (photo, screenshot) On the cameras we can clearly see cavity flashes in green but the IR flashes were off the camera, so I went to FCES and centered the flashes on the IR camera (using the seed). I also went back to sqzt7 and aligned the FC green refl onto the diode.
While I was there, I watched the green beam on a card while I moved suspensions to see how much freedom we have to move the suspensions and still get the green beam out of the viewport. I could move ZM1,2,3 and FC1 by a couple hundred urad in both pitch and yaw (although not in either direction), so there is a reasonable adjustment range. Moving these didn't impact the oblong shape of teh beam, so it doesn't seem like that is caused by clipping. I then moved the ZM2 psams settings, and saw a big change in beam shape, it became more round looking on a card for strain guages of 4.15 or 5.15 (our usual setting is 3.15).
I left the alignment back at the one that gave good flashes for IR and green (up to 10, is off in pitch), and with the CLF IR flashes are max 0.15 counts.
TITLE: 03/27 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
INCOMING OPERATOR: None
SHIFT SUMMARY: The +/- Y doors were taken off HAM1 this afternoon alog89672, See Jims' alog89673 for the current CS seismic configuration. I'm not sure if the intercom is working, I didn't hear myself after plugging it in and trying the offices. THe LVEA is now is LASER HAZARD, as is the optics lab.
LOG:
| Start Time | System | Name | Location | Lazer_Haz | Task | Time End |
|---|---|---|---|---|---|---|
| 14:28 | FAC | Kim, Nellie | LVEA | N | Tech clean, Nellie out @ 15:12 | 15:19 |
| 14:58 | FAC | Randy | LVEA | N | Prep for door removal | 15:26 |
| 15:51 | VAC | Travis | LVEA | N | Check HAM1 purge air | 15:57 |
| 16:05 | FAC | Mitch | LVEA | N | Cleanup in the Wbay | 16:22 |
| 16:07 | EE | Fil, Marc | LVEA | N | Cable pulling for moving electronics, HAM3/BSC2 | 17:09 |
| 16:22 | VAC | Nellie | LVEA | N | Tech clean | 17:11 |
| 16:36 | VAC | Gerardo, Randy | LVEA | N | HAM1 door removal! Travis to join | 18:33 |
| 16:41 | FAC | Jason | Optics lab, LVEA | LOCAL/N | Property hunt | 17:21 |
| 16:50 | VAC | Betsy, Mitch, Travis | LVEA | N | HAM1 doors, Mitch Betsy out 1700 | 18:30 |
| 16:51 | FAC | Kim | LVEA | N | Tech clean | 17:44 |
| 17:02 | SEI | Jeff, Sina | Optics lab | LOCAL | SPI work | 18:07 |
| 17:03 | BHD | Oli | Optics lab | LOCAL | BHSS work, magnet pol checks | 20:16 |
| 17:12 | EE | Fil, Marc | MidY | N | Cable search | 19:53 |
| 17:32 | OPS | Ibrahim | Optics lab | N | Put away parts before curtains | 17:46 |
| 17:35 | FAC | Jason | PCAL lab | N | Property inventory | 17:39 |
| 17:38 | OPS | Betsy, Jim | LVEA | N | Cleanroom move by HAM1, Betsy out 1746 | 18:43 |
| 17:53 | EE | Thomas | Vac Prep | LOCAL | In-Vac cables | 19:19 |
| 18:32 | SUS | Ibrahim | Vac-Prep | LOCAL | Joining Thomas | 19:19 |
| 18:55 | BHD | Elenna, Keita | Optics lab | LOCAL | BHSS, Keita out 19:37 | 20:16 |
| 19:20 | SEI | Jim, Betsy | LVEA | N | LOCK HAM1 ISI | 20:07 |
| 19:43 | FAC | Randy | LVEA | N -> Y | Work on emod, handrails | 22:46 |
| 19:49 | SPI | Jeff, Sina, Jason | Optics lab/PSL encl | LOCAL | Measure fiber power, in lab checks then PSL enc checks, Jason out of PSL at 20:40 | 21:25 |
| 19:53 | EE | Fil, Marc | LVEA | N ->Y | Cables, all around HAM3 and BSC2 | 23:10 |
| 19:56 | SQZ | Sheila | LVEA | LOCAL | turn on SQZ laser, potential transition to hazard at SQZT7 | 20:06 |
| 20:11 | EE | Ibrahim, Thomas | Vac Prep | N | In-Vac cabling | 20:18 |
| 20:37 | EE | Ibrahim, Thomas, Sophie | Vac Prep | N | In-Vac cable making, Ibrahim 23:15 | Ongoing |
| 20:20 | ISC | Betsy | LVEA | N | Look into putting tables back | 21:39 |
| 20:48 | ISC | Sheila | LVEA | N | Talk to Fil and Marc, Turn on SQZ laser | 21:03 |
| 21:02 | TCS | Sophie | Vac prep | N | CHETA work | 22:56 |
| 21:22 | ISC | Betsy | Optics lab then LVEA | N | Parts/tools checks then LVEA | 21:56 |
| 21:22 | VAC | Travis, Bram | LVEA | N | Look at laser stop buttons | 21:27 |
| 21:24 | BHD | Elenna | Optics lab | LOCAL | Turn on the laser, cont BHD work | Ongoing |
| 21:31 | OPS | Sheila | LVEA | N -> Y | Laser Hazard transition | 21:47 |
| 21:58 | SQZ | Sheila | LVEA | Y | SQZT7 work, alignment | 22:15 |
| 21:59 | OPS | Jenne | LVEA | Y | Look for Fil/Marc | 22:14 |
| 22:06 | ISC | Keita, Jennie, Betsy | LVEA | Y | HAM1 work | Ongoing |
| 22:08 | SEI | Jeff | LVEA | N | Find part | 22:28 |
| 22:09 | ISC | Jason | LVEA | Y | Join HAM1 team | 22:21 |
| 22:38 | SQZ | Sheila | LVEA then FCES | Y | SQZT7 check before FCES | 23:06 |
| 23:21 | SQZ | Sheila | LVEA | Y | SQZ7 checks | Ongoing |
| 23:29 | SEI | Jim | LVEA | Y | Unlock HAM3 HEPI | Ongoing |
F. Clara, J. Kissel, S. Koehlenbeck, J. Oberling, M. Pirello D2400110 Today we picked up where we left off with the install of SPI into H1. Where we last left things, we'd installed a new SPI pick-off of ALS/SQZ beam in Apr 2025 (see ECR E2400083 and results in LHO aLOGs 83989, 83996, 83978). Back then, we had ended the work with the input to the fiber collimator within the PSL dumped. With Jason and Sina in the PSL, we confirmed that the SPI path was still blocked. However, we also realized/remembered/confirmed that the entire ALS/SQZ/SPI path had 25% less power -- We've been running the PSL at lower power allocation downstream of the PMC since Sep 2025 to prevent issues we'd found with the currently installed EOM after a power outage triggered a dust monitor to spew out dust into the PSL (see that saga in e.g. LHO:87109 LHO:86966). They found the power at the SPI pick-off was 140 [mW] instead of the 188 [mW] we left in Apr 2025 (see LHO:83996). (Using labels in the half-up-to-date drawing D1300348) Jason and Sina rotated ALS-HWP2 upstream of ALSPBS01 to restore the nominal 50 [mW] into the ALS/SQZ pick-off and ~200 [mW] (190 [mW] measured). This means there's ~50 [mW] less out to ALS / ISCT1 than before today. Then with the SPI pickoff still dumped, we installed a 30 [m] patch cord*** from the PSL optical table, out the mouse hole between the +X wall of the PSL enclosure and HAM1, then up running along the upper racks to waterfall down at SUS-H2. The fiber sits within the typical orange tubing. Per D2400110, this is SPI_PSL_001, and it's labeled as such on both ends. After install, I connected the SUS-R2 end to a Thorlabs S121C power meter with S120-APC2 fiber adapter. With this installed (making the system laser safe at SUS-R2 end), Jason/Sina unblocked the SPI pickoff input. With 190 [mW] in, we measure 187 [mW] out on the other end. 98% transmission, pretty excellent. Almost unbelievably excellent but we weren't rigorous with our uncertainty and systematics. Happy with this result, we then blocked the SPI path again, and re-capped the SUS-R2 end for final dressing in the racks. We'll unblock again when we're read to connect it to the Laser Prep Chassis. ***Patch cord details: Manufacturer DIAMOND DIAMOND Part Number: ENS/1094388 Customer Part Number: 9711228 Patchcord SM L=30 PM 2xFC 2mm APC (i.e. 2mm narrow key FC/APC on both ends) tran 6,6/125/245 PAND 980nm
J. Oberling, S. Koehlenbeck 2026-03-27 #BelatedaLOG During this power measurement, I made the rookie mistake of overlooking the PM100D power meter console's laser wavelength setting -- and not taking a picture of the display during the measurement. Today, we both (a) retook the measurement at 1064 [nm] with 189.3 [mW] input, and found 173 [mW] output. (b) confirmed that at 532 [nm] the output read as 188 [mW]. For now we set the nominal power into the laser prep chassis as 173 [mW]. After this measurement, we took this same power meter (S121C) and fiber adapter (S120-APC2) into the optics lab and instead used the fiber-coupled NPRO we'd been using to test ISIK in there. We measured the power out of the fiber (i) with it fiber-coupled in the same way as the SPI_PSL_001 measurement, and (ii) using an addition PAF2-5C collimator to project the beam into free space on to the power meter. We set the FC-NPRO's power to 177 [mW] in the (i) configuration, but then measured 140 [mW] in the (ii) configuration. This leads us to suspect that the S120-APC2 + S121C system -- a reflective Si diode, with a shiny metal adapter -- is errantly reporting more power than there really is. We'll repeat the measurement of SPI_PSL_001 another day with a thermal power meter to arrive at our final number.
