ryan.short@LIGO.ORG - posted 10:05, Monday 18 May 2026 (90264)
PSL 10-Day Trends
FAMIS 63899
No major events of note; things looking very stable recently.
Images attached to this report
FAMIS 63899
No major events of note; things looking very stable recently.
In preparation for testing out the BOSEMs on the BBSS, I've updated the OSEM2EUL and EUL2OSEM matrix values from the suspension projection values for the BSFM's geometry to projection values from the BBSS's geometry.
OSEM2EUL
before (BSFM projections), after (BBSS projections)
EUL2OSEM
TITLE: 05/18 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: 12mph Gusts, 6mph 3min avg
Primary useism: 0.03 μm/s
Secondary useism: 0.15 μm/s
QUICK SUMMARY: No alarms over the weekend, temperatures looking normal, dust counts low as well. The same 31 channels are disconnected from the EDC since the CS HEPI pump controller is still down.
Likely continuing with alignment work in HAM2 today following the ISS array replacement.
TJ and I cleaned the BSC2 aluminum floor, the bottom of the chamber below that, feedthrough nozzles, support tubes and their nozzles (see figure for photo of cleaning and some of the stuff we found). The particulate level while walking around gently did not change significantly from before to after the cleaning (see table below). This and the other cleaning experiments reported in the table suggest that, at the current state of cleanliness, the dominant source of suspended particulate is the people and the things we bring in rather than dust that we stir up by moving around.
The dust counts generally returned to low levels a minute or two after the activities in the table.
Just as patting clothes produces more dust, we found that rapid movements produce more dust in the chamber than slow movements. The linked video shows the movement speed and the wiping speed that produced the lower levels in the table below: slow chamber speed.
Recommendations:
1. The chambers are currently clean enough that general cleaning is probably counterproductive.
2. Move slowly when possible. This can reduce the particulate suspended from your bunny suit by an order of magnitude.
|
Activity |
Particulate per cubic foot* |
|
|
0.3 um |
0.5 um |
|
|
Standing still in chamber |
0 |
0 |
|
Walking around gently in BSC2 before cleaning |
150 |
80 |
|
Walking around gently in BSC2 an hour after cleaning aluminum floor, bottom of chamber, and all nozzles |
170 |
85 |
|
Wiping aluminum BSC chamber floor |
200 |
50 |
|
Wiping feedthroughs and their nozzles |
200 |
70 |
|
Cleaning support tubes and their nozzles |
100 |
60 |
|
Slow wiping of BSC floor under aluminum floor towards center (lowest part) |
200 |
50 |
|
Fast wiping of BSC floor under aluminum floor towards center (lowest part) |
800 |
500 |
|
Deploying vacuum hose and accessories |
1000 |
800 |
|
Vacuuming up material wiped to center of BSC floor |
200 |
50 |
|
Vacuuming bellows with tube accesory that fits between them |
600 |
150 |
|
Vacuuming walls in spool piece |
200 |
50 |
|
Vacuuming aluminum floor in chamber while hose assembly is dragging |
600 |
200 |
|
Waving hand up and down while standing still outside the chamber |
150 |
50 |
|
Waving hand up and down while standing still inside the chamber, monitor at same relative position |
200 |
70 |
* Particle counts are aproximate averages, mostly of 1 minute samples. Repeats suggested that differences in the table of a factor of two or greater are significant. Quiet controls were taken in between reported measurements to ensure that measured levels were not significantly affected by previous activities. Monitor: Met One GT-521S laser particle counter
TJ and Robert
Clipping on IFO REFL baffle is gone.
The problem of IFO REFL beam clipping by the last IFO REFL baffle in HAM2 (see alog 90251, especially this picture) seems to have been caused by a huge PRM change in the PRM alignment sliders made on Monday May/11/2026 past 1700 local time (that none of us knew/remembered/understood).
Once Sheila reverted PRM back to March/2026 alignment, changing the IFO REFL beam path (but not the alignment into ISS path), IFO REFL was not clipped any more even though it looked low on the baffle (IFOREFL_baffle.mp4). LSC and ASC REFL sensors on HAM1 ISI saw the flashes right away without any adjustment of RMs, and the flash peaks were already reasonable. According to Sheila, compaing to a time when DRMI was acquiring in November:
All of these were a good sign.
Forward-going beam into the IM4 is clipped by the baffle in front of IM4, and the IFO REFL beam is clipped by the baffle at the -Y edge of the IFI.
Unfortunately I've found that there were two other clipping points that I must have missed yesterday using IR viewer. See clipping.png, sorry for a blurry through-IR-viewer picture shot from the distance. Go back to HAM2layout_annotated2.png to figure out which baffle is what.
There's a baffle in front of IM4 between IM4 and IM3, and the forward-going beam is slightly clipped at the +X edge of that baffle.
Also the IFO REFL beam is clipped by the baffle installed at the -Y edge of the IFI. I know this is IFO REFL because the bright spot goes away when I block the beam on PRM by a sheet of aluminum. I cannot quite tell from the picture which edge of the baffle is clipping, but I think it's also +X edge.
In the past, when PRM spot position was measured with full IFO, it was like a mm off according to Sheila, so it's hard to imagine that the beam was clipping on the baffle in front of IM4.
Changing IMC alignment (trial 1, didn't fix clipping).
We decided to back off the changes we've made for MC1, 2 and 3 since Monday and revert back to in-vac March alignment. If we have to make a huge adjustment to JM3 to follow the IMC, maybe the beam coming from JM3 is suspect (which means that the MC2 trans path is somehow suspect too).
Before I did anything, the starting point was captured in alignment_2026-05-15_16-14-21.png.
MC1/2/3 was reverted just based on slider values and not using OSEM readings as per alignment_2026-03-18.png.
Then JM3 was adjusted in PIT and YAW to give the maximum transmission measured in IM4_TRANS_NSUM. Actually I didn't move JM3 as much as I expected.
That alone couldn't recover a good 00 mode flashing so I moved MC2 and MC3 to follow the input beam. MC2 moved back closer to the position this morning.
After that I felt as if it was somehow easier to optimize further using MC1 as well as MC3, thinking that it would be a minor adjustment but somehow ended up moving MC1 by a large amount after iterations.
My end point is captured in alignment_202605151726_sliders.png.
Without IM3 and IM2, the beam was still on IM4_TRANS as well as ISS QPD, the flashes were good, so I looked at the clipping on the baffle in front of IM4 as well as the baffle at the -Y edge of the IFI, and they were still there. IFO REFL baffle was still not clipping.
Will have to think about what these all mean.
(Jordan V., Gerardo M.)
Late entry.
The compressor that produces the purge air developed a seeping leak of oil a few weeks ago, second oil leak, located were a previous work was done last March, see here for details, then the leak turned into a drop by drop leak, then other hose joints started to seep, we called the vendor regarding the leaks so they can fix the issue, they should be here next week. However, due to the amount of oil the unit has lost, we decided to add some oil to the compressor.
Before adding oil, the chambers were checked that all soft covers were on, operator was notified that the compressor was getting shut down, Kobelco unit was turned off. All doors for the compressor unit were opened, air moving equipment was added to cool down the compressor for about 1 hour, then oil was added until the sight glass showed a good level. Unit was restored and turned on. We allowed the unit to run one hour to achieve nominal temperature, then we opened the purge air to the chambers. DP at the drying towers showed -78 degrees C.
Attached are a few photos, the front display shows the oil temp TT4, nominal is above 110 degrees F, and the unit alarms above 170 degrees F.
TITLE: 05/15 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
INCOMING OPERATOR: None
SHIFT SUMMARY: Alignment continued in HAM2 today after the Kobelco unit was worked on this morning. Ibrahim has been tidying up around the test stand area and wrapping up parts from the BSFM. Robert continued grounding studies at End X, and Jeff worked in the optics lab on SPI. His work requires leaving the laser running over the weekend in the optics lab; curtain is closed and proper signage is up.
LOG:
| Start Time | System | Name | Location | Lazer_Haz | Task | Time End |
|---|---|---|---|---|---|---|
| 19:43 | SAF | LASER HAZARD | LVEA | YES | LVEA IS LASER HAZARD | Ongoing |
| 14:59 | VAC | Jordan | LVEA | - | Check covers/RGA, shut down Kobelco | 15:11 |
| 15:32 | FAC | Kim | LVEA | - | Technical cleaning | 17:02 |
| 15:41 | SPI | Jeff | Opt Lab | Local | SPI prep work | 19:33 |
| 16:25 | VAC | Jordan | LVEA | - | Checking RGA | 16:30 |
| 16:39 | FAC | Randy | LVEA | - | Plugging in equipment | 17:31 |
| 16:40 | SUS | Ibrahim | LVEA | - | BSFM housekeeping | 19:21 |
| 17:20 | FAC | Kim | LVEA | - | Technical cleaning | 18:00 |
| 17:41 | ISC | Keita | LVEA | Y | HAM2 beam alignment | 17:55 |
| 17:55 | PEM | Robert | EX | N | Grounding studies (in/out all day) | Ongoing |
| 17:58 | VAC | Jordan | LVEA | - | Ramping up RGA temp | 18:04 |
| 19:47 | ISC | Keita | LVEA | Y | HAM2 beam alignment | 21:42 |
| 20:40 | VAC | Jordan | LVEA | - | Checking RGA | 20:45 |
| 21:32 | SPI | Jeff | Opt Lab | Local | SPI prep work | 22:57 |
| 21:49 | SUS | Ibrahim | LVEA | - | BSFM wrap, bag, tag | Ongoing |
| 22:38 | EPO | Oli +2 | LVEA | - | Tour | Ongoing |
| 23:05 | VAC | Jordan | LVEA | - | End-of-day RGA check | 23:10 |
J. Kissel
Quick summary of status and things done before the weekend:
2026-05-14
- Secured new D2400143-v6 breadboard to 1"Dx6"L posts
- w/ J. Freed Helicoiled most holes
2026-05-15
- Finished helicoiling and confirmed all holes have helicoils.
- Brought out IXM100 mounts that are to replace CVM100 mounts, confirmed left vs. right-handed assignment
- Fit-checked (success!), then installed new version of 45 deg periscope adapters to M_M4 and M_M5 mounts.
- Aligned periscope adapters as best possible by eye
- Migrated over and re-cabled up all photodiodes per wiring diagram and cable routing defined in LHO:90228.
- Migrated R_F1 and M_F1 fiber collimators, confirming and adjusting alignment of slow-axis w/ vertical flat.
- Re-connected optical fiber input to each collimator.
- Re-introduced beam on to breadboard confirming that NPRO and Laser Prep Chassis still work as good as we left it.
- Measured raw power from R_F1 and M_F1 fiber collimator output using S121C power meter.
- Aligned R_F1 and M_F1 fiber collimator output using
- D2500080 alignment iris target assemblies
- D2400143-v6 holes 89 + 101 for R_F1 and 101 + 80 for M_F1 and
- S121C behind the "far" iris, maximizing power throughput.
- Migrated R_P1 and M_P1 thin-film polarizers.
- Measured P-pol (TRANS) and S-pol (REFL).
- Migrated D_R_P1 and D_M_P1 beam dumps.
Optical power going into the mock PSL input fiber is ~195 [mW] as we left it, and internal laser prep chassis reads 7.8 [V] implying that input power to the chassis is the same 173 [mW] we set it to, to match the real PSL input (see LHO:89693).
RF power on power monitors from prep chassis are as expected, in the 750 +/- 10 [mV] range.
Measuring power with our trusty S121C with ThorLabs PM100-D readout (confirmed to be measuring at 1064 [nm] wavelength): 
Josh and I hard at work doing helicoil science. Photo credit: Ryan Short.
TITLE: 05/15 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: 6mph Gusts, 3mph 3min avg
Primary useism: 0.06 μm/s
Secondary useism: 0.13 μm/s
QUICK SUMMARY: Work in HAM2 continues today as part of the ISS swap, but not until the Kobelco unit has had some maintenance done this morning. No in-chamber work allowed until that's finished. 31 disconnected channels on the EDC since the corner HEPI pump controller appears to still be down.
In other news, a M6.7 EQ out of Japan is rolling through, and it's a beautiful morning on-site.
Good news is that we're done with the alignment of the ISS path. Pictures and details are to follow.
Then I reinstalled the last IFO REFL baffle right in front of the HAM2-HAM1 septum window. (The baffle was removed after marking the exact position using three temporary dog clamps on the ISI on day 1 because it was in the way, I was supposed to record that in alog 90158 but forgot. I'm absolutely sure that the position of the baffle was restored within 0.1mm of the original position.)
Bad news is the IFO REFL was clipped on that baffle. 00 mode flash isn't clipped that much but horizontal modes certainly are. That was not THAT surprising because the IMC alignment was/is not great (see my comment 90224). This looks to me that the uncontrolled degree of freedom of the IMC is wrong regardless of the reason why a huge alignment change had to be made to center the MC2 TRANS QPD.
Good news is the ISS path alignment is not impacted by that, at least greatly, because we made sure that the beam hit the right location of IM4 TRANS as well as ISS array QPD before we did anything in the ISS path. Note that the baffle clipping the beam is not in the ISS path.
In other words,
However, since we don't want to revisit HAM2 once we close it, I'd like to understand what's going on for the IMC/IFO alignment.
For location of things, refer to HAM2layout_annotated.png. Blue line = IMC reflection. Red line = IMC transmission. Orange line = IFO REFL rejected by the IFI. Green things are baffles (two-hole baffle and the last IFO REFL baffle are circled in green).
The alignment status at the start of Thursday morning:
The beam was very high on the two-hole baffles but was OK on the input hole of the ISS array. See alog 90237, see this picture as well as this, and this video. This just meant that we were shooting down the beam from the 1" lens toward the center of the array QPD.
Work done on Thursday:
We moved the beam down using the two pico mirrors such that ultimately the beam goes through the center of the input hole of the array and reasonably centered on QPD.
Detailed procedure was:
We have found no unexpected behavior here, I was surprised that the process was easy and things made sense given the difficulty people had in the past to improve alignment of the array in vacuum with the old unit. That's probably because the beam was already clipping back then.
The only thing was that the YAW actuator of the second pico mirror didn't have much range to start with even before we moved anything. At some point it didn't hit its end of the range but was close (2nd_pico_position_before.jpg). Since we need a healthy headroom for adjustment both ways, I relieved the pico by mechanically rotating the pico mirror assy (2nd_pico_position_after.jpg).
IFO REFL beam was clipping on the baffle:
To close out the week, we got stops and shroud mounts installed on the 2 CRS today. This is as far as we can go until we can get flexures or start assembling HOQIs, so probably not much more to report until later next week. We've covered the CRS in foil to protect them, and packed up the left over hardware for these 2 sensors.
TITLE: 05/14 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
INCOMING OPERATOR: None
SHIFT SUMMARY:
Cement truck convoy day for CEBEX today. Bigger BeamSplitter "captured" in the suspension assy & FARO-ed in the afternoon. A couple big middle school tours. ISS Array alignment continued.
LOG:
Ibrahim, Betsy, Oli
Today, we installed BBS01 into the BBSS successfully.
BBS01 was on a table. BBSS was on the aluma lift. We picked BBS01 using the ERGO arm and slowly came into the optic. In this process, we:
On top of pictures below, 2 videos:
Wahoo! Congrats, y'all!
Note, current status as of last Thur was handoff to FARO IAS (Jason/Ryan C) who are up for mapping and guiding us into place. CAD files from CIT arrived Thur so quite literally just in time to get on it.
Also, thanks Travis for all the pictures.
I spun the iNCal (currently installed version) at a low speeds to see if low speed operation shows the same vibrations that high speed operation does (see 67207). Even rotating at 1 Hz shows a large increase in signal in the accelerometer (H1:PEM-EX_ACC_BSC9_ETMX_Z) around 200 Hz. 7 Hz shows an order of magnitude increase between 100-300 Hz. The 0 Hz spectrum is with the iNCal powered but a set speed of 0 Hz.
The lesson is that the iNCal will inject broad band noise in the strain readout even at very low speed operation.
Following yesterday's alog 90219:
At this point I and Rahul checked the beam positions in HAM2. Some things to note:
We proceeded to swap the ISS array unit.
At this point we saw flashes on QPDs as well as array PDs right away. INNER as well as OUTER SUM flashes were both about 0.06 (in the old unit it was 0.03 for OUTER but INNER was much smaller).
We started trying to center the QPD using the first pico mirror. Since pico driver is temporary unavailable (IOT2L is moved away) Rahul turned the pico manually while Elena looked at the laptop screen to monitor flashes in the individual segments. We managed an OK job (arrayqpd_centered.jpg) and checked the beam spots again.
The baffle height might not be the same as the lens height and/or the ISS array input hole height, but otherwise it seems that we're shooting down the beam from the 1" lens to the ISS array. We'll check if the lens, baffle and the array are all at the same height or not, and decide how to proceed.
1st: Rahul is disconnecting the QPD cable.
2nd, 3rd (photo by Betsy): Rahul in chamber (me outside).
4th: Old unit was extracted. This is S1202971.
5th: New unit (S1202965) to the left, old one to the right.
6th: Rahul after successfully connecting up the new unit in chamber.
7th (photo by Betsy): Elenna (front) is checking the QPD centering, Rahul (a shadow in the back in this photo) is manually moving the pico mirror from -Y door, and I'm somewhere inbetween just observing the two doing a good job.
epo tagging for photos!
Attaching two pictures in reference to Keita's comment above - "The beam was very high on the left hole of the two-hole baffle (Rahul has a good pic), high on the right hole (right_hole_after_new_array_QPD_centered.mp4)"
We concluded that the height of the baffle and the array unit are both correct, the beam is really too high on the 1" lens and we're shooting down from there to the QPD. (This should have been the case for a long time with the old unit. Right after the new unit was installed the beam was on QPD and the beam stayed on the QPD, the diameter of the QPD is 3mm, i.e. we haven't made any huge change on the height of the beam at the left baffle hole.)
With this information, what we'll do next is to gradually bring down the height of the beam on the left baffle hole using the first pico mirror, and use the second pico mirror to bring the beam back on the QPD, until the beam line into the array becomes level-ish with the ISI surface. It doesn't have to be perfect but we don't want to be this much tilted.
We started with yesterday's alignment. I checked flashes in ISS array PDs and didn't like that the balances between them were very much different from how they were when IMC was locked back in March.
Then we started changing IM2 and IM3 to see if we can get back, but I was appalled that the flashes became stronger and stronger on array PDs as we aligned, which probably means that the beam was almost falling off of the PDs when we started.
That shouldn't have stopped us because we don't know where the beam was on the array PDs when MC was locked (people gave up optimizing that path because things didn't make sense), it could have been falling off of the diode (because each diode is 2mm, QPD is 3mm, the beam size is ~250um or so, and the beam was almost in one quadrant of the QPD). But I started thinking about many what-ifs and wasted time.
After all, since IM4 TRANS and ISS array QPD are both reasonably close to March 2026 position, we know that the beam position as well as angle of the beam injected into ISS path from IM4 are already close to those when IMC was good in vacuum.
What we should do is this:
Other things to note:
This is not required for the alignment but it's helpful to know how much we can move the beam on QPD. In an unlikely event where we somehow lose the beam in vacuum on the array QPD after IMC is locked, we might be able to scan IM3/IM2 to regain the beam on QPD, and slowly move IM3/IM2 back to the nominal position while pico-ing so the beam isn't lost on the QPD. If the beam is not clipped, the beam displacement on the QPD is ~3mm per 1mrad of IM3 rotation using parameters collected from various documents, see attached script.
The same script shows you that the Gouy phase separation between two pico mirrors is 10 degrees (if we use the beam parameter in Matt Heintze's alog 12537, which was probably obtained by the measurement of the bypassed beam) or about 20 degrees (if we use IMC eigenmode parameter propagated to the ISS path using D1200693).
Another thing is, if we believe the design eigenmode number rather than the measured bypassed beam in Matt's alog, the beam waist will be smaller and at about 20cm upstream of the PDs. The beam size on the PDs is about twice as large as it should be (470um rather than 250um). I cannot measure the beamsize of the flashes so we won't do anything, but that's something to remember. If IM3 has enough actuation range, we can later lock the IMC, scan the beam across the PD until the beam falls off, see how sharp the fall-off is, and use the diameter of the PD (3mm) to determine the size of the beam. Maybe a good project for a fellow.
One of the things that bothered me (that isn't directly related to ISS alignment) is the fact that we had to rotate JM3 by a huge amount, i.e. negative 200um in PIT to "center" the MC2 trans QPD. This is the equivalent of the negative YAW rotation of the beam in IMC's coordinates (clockwise seen from the top). Since the distance between MC2 and JM3 is ~19m according to E2400218, this means that the MC2 beam position was moved by about ~7.6mm in -Y direction on MC2. This seems to roughly corroborate with the pictures in alog 90203 ("before" picture and "after", hard to tell how much it actually moved due to parallax but there's no doubt that the motion was large).
What if this is because something is wrong with the MC2 trans path? Like the pico mirror in front of the QPD was bumped (by a huge amount, however unlikely it is). My conclusion is that we can lock IMC in vacuum, use WFS with MC2 centering, measure the centering on MC2 using dither, and figure it out. If QPD center is grossly off from the MC2 center, we can pico.
Sorry the script in the above alog didn't work because it was missing one line.
Attached is a working version. You need a la mode matlab package https://github.com/nicolassmith/alm.
