TL;DR - Don't worry about the new models and screens in /userapps/trunk/sus - Brian is developing these for the OSEM estimator project and none of these are (currently) linked to any observatory model.

--

FYI - As part of the project to see if we can improve the noise caused by the OSEMs, we are developing new models and medm screens for the HLTS. Tracking for this ECR is in FRS ticket 32526.  

We are running these at Stanford for testing, and putting them into userapps because we will be trying them on a triple at LHO soon (detail will be in a different log, they are still in flux a bit).

As such, I've created several new things in userapps. These are not linked to anything at either site - I'm putting this note here to reduce potential worry. These are still in development, so I suggest waiting a bit before you look at these.

New Files:

/userapps/trunk/sus/common/models/
HLTS_MASTER_W_EST.mdl   -  library part for M1 with the estimator calculation
SIXOSEM_T_STAGE_MASTER_W_EST.mdl - library part for upgraded HLTS model with the estimator included.

userapps/trunk/sus/common/medm/hxts/
SUS_CUST_HLTS_OVERVIEW_W_EST.adl - new overview screen with estimator

These files are copies of the existing parts as of March 2025, and I added _W_EST to the name of the copy.

userapps/trunk/sus/common/medm/estim/ - directory of new sub-screeens for the estimator

Updated files:

userapps/trunk/isi/common/models/
blend_switch_library.mdl - I added a new model to this library to allow smooth switching between the osem damping, the estimator damping, and OFF.

I'm running this from the new top-level model in

/userapps/trunk/isi/s1/s1suspr3.mdl

Closes FAMIS 26371. Last checked in alog 83630,

Everything is under threshold. H0:VAC-MX fans had a sudden increase in noise character and signal 6 days ago.

Closes FAMIS 26832, last checked in alog 83610
 

Laser Status:
    NPRO output power is 1.829W
    AMP1 output power is 70.43W
    AMP2 output power is 141.1W
    NPRO watchdog is GREEN
    AMP1 watchdog is GREEN
    AMP2 watchdog is GREEN
    PDWD watchdog is GREEN

PMC:
    It has been locked 1 days, 20 hr 16 minutes
    Reflected power = 22.99W
    Transmitted power = 105.7W
    PowerSum = 128.7W

FSS:
    It has been locked for 0 days 20 hr and 13 min
    TPD[V] = 0.8222V

ISS:
    The diffracted power is around 4.1%
    Last saturation event was 1 days 20 hours and 15 minutes ago

Possible Issues: None reported

Thu Apr 03 10:05:16 2025 INFO: Fill completed in 5min 13secs

Yesteerday I noticed that the CS pump could only pull 18inHg (nominal 19) even with the bleed valve closed. There was lots of carbon dust around the exhaust and the filter tumb screws were tight, all signs that it was time for a rebuild. Today, Ryan C and I swapped it with the spare, which fired right up and pulled to well above 20inHg before I adjusted the bleed valve and brought it back to 19.

Two safety notes:

1. The out plastic on the spade connectors look like they have been damaged from recent swaps (attachment 1). Since we have to feed these through a 90deg elbow and then fish them out of the housing before pluging them in, I'm not surprised that it could have been damaged. We will talk with Fil or similar to find a better solution.
2. These pumps get very hot, >130F at times, and the foam it sits on to damp it has started to melt and burn (attachment 2). I'll find a new material for it to sit on and update.

Closes FAMIS 26037. Last checked in alog 83671.

Expectedly, all plots have elevated signals. This is because we are venting in the LVEA and sensor correction is not in the nominal state. PDF Attached

TITLE: 04/03 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: 5mph Gusts, 3mph 3min avg
    Primary useism: 5.75 μm/s
    Secondary useism: 1.85 μm/s
QUICK SUMMARY:

IFO is in PLANNED ENGINEERING for the VENT

Today's planned activities:

• Kim/Nellie - 2nd Cleaning HAM1
• Randy - Trailer in ISI middle gantry and crane over for fit check at HAM1 +Y
• Randy - Crane out 3IFO Flange Crate
• Randy - Ameristat HAM1 HEPI grout areas
• 5 People - Move HAM1 cleanroom into final place
• VAC - Checklist for corner vent
• VAC - Leak check corner under vent
• HAM1 +Y Door Removal
• VAC - HAM1 Remove 16" Top Flange forklift down for work
• VAC - HAM1 Top Flange guague work table side

Work safe!

Today's activities:

- HAM1 was vented, the bolts of both the Y+ and Y- doors have been taken off (besides 4 bolts/door, see aLog 83704), in preparation for removing one of the doors tomorrow
- After the installation of a faulty gauge on HAM6, today it was replaced with a functional one (same type), leak checked, and found OK. No further pumping on this gauge, it will be valved together with the corner during the pumpdown
- Some leak checking was done, in detail:
 - BSC8: Y- X- side flanges (3 pcs.)
 - BSC2: Y+ X- side flanges (3 pcs.)
 - HAM4: X- door flanges (5 pcs.)
 - HAM5: X- door flanges (5 pcs.); top flanges - and adjacent sub-flanges (3 pcs.); X+ door flanges (5 pcs.)
 - HAM6: X- door flanges (5 pcs.); top flanges - and adjacent sub-flanges (2 pcs. - the turbo will be replaced later, so no leak check there); Y- door flanges (3 pcs.); X+ door flanges (5 pcs.)
 - HAM4-HAM5 spool piece: Y- side X- and top flanges (6 pcs.); top flanges (4 pcs.); Y+ side X- and bottom flanges (4 pcs.); vent valve (1 pc.); IP3 and IP4 flanges (2 pcs.). This spool piece is now complete, as other flanges have been leak-tight verified earlier according to aLog 45415

WP 12424

List of work for PMI and RMI1/2:

1. Both Sat Amplifier Chassis now installed in SUS-R1
2. Cables for RM1/2 have been terminated
3. Cables for PM1 pulled from SUS-C4 to SUS-R1
4. Cabling from Amplifier chassis for PMI/RM1/RM2 pulled to HAM1 Flange D6

Coil drivers need to be relocated in CER to lastest D0902810 drawing.

F. Clara, M. Pirello

TITLE: 04/02 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
INCOMING OPERATOR: None
SHIFT SUMMARY:

Extremely productive day in which we finished most of our activities, listed below:

• Crane engine hoist to BSC8 (FAC) - DONE
• Inspect HAM1 and BSC8 final cleanroom (FAC) - DONE
• Turn on HAM1 cleanroom and garb room (FAC) - DONE
• Power down ISC chassis that will be recabled (Fil/EE) - DONE
• Pull ISC cables - NOT COAX yet and work to relabel (Fil/EE) - DONE
• HAM1 Offload HEPI Setup (SEI/Jim/Mitchell)
• Leak check corner under vac (VAC)
• Prep for corner vent (VAC)
• Checklist for HAM1 vent (VAC) - DONE
• HAM1 1st cleaning (Kim/Nellie/FAC) - DONE
• Clean out recieving for ISI (FAC) - DONE
• HAM6 Guage Work (VAC) - DONE
• Checklist for corner vent (VAC)
• Move forklift to HAM1 south bay area (FAC)
• Crane or move power bang box to southbay for cleanrooms (FAC) - DONE
• Replace ~3ft of cleanroom panel for HAM2 +Y-X (FAC) - DONE
• Vent HAM1 (VAC) - DONE
• Start HAM1 bolt/door removal (VAC/Randy/Tony/Corey) - DONE - alog 83704
• Move HAM1 cleanroom into final place (5 people)
• Stock garb room by HAM3 (FAC/Kim)
• Prep laydown areas for stack deinstall, setup door pallet at HAM3+Y - DONE
• Get dust mons working and trending (OPS/RyanC) - DONE - alog 83706, alog 83694

Relevant alogs pertaining to today:

• HEPI/ISI Pointing after locking: alog 83705
• Sush7 timing glitch model restart: alog 83698
• High Voltage Shutoff Prep: alog 83695

Attached is a picture of our SEI/SUS Guardian configurations

LOG:

R. Crouch, J. Oberling, M. Robinson, T. Guidry, T. O'Hanlon

Incoming wall of text, but here's the short, short version:  Over the past ~15 months during available Tuesday maintenance windows we have been working the FARO around the LVEA, setting alignment nests so we have the ability to drop the FARO almost anywhere in the LVEA and have it aligned to the local LVEA coordinate system.  I'm happy to report that, after working through and around unavoidable delays (mostly the emergency vent for OFI repair and the PSL frequency noise issues from the latter half of 2024, as well as several maintenance periods where IAS personnel were unavailable due to other required maintenance work) this effort is finally complete.  There are now 53 bright red Spherically-Mounted Retroflector (SMR) nests around the LVEA, and a number around the frame of the high-bay rollup door and the nearby wall; these nests have been aligned to the LVEA local coordinate system.  The naming scheme is F-CSXXX: F for FARO, CS for the building (Corner Station in this case), and XXX is the monument number.

As a brief reminder of where things were left before we started moving the FARO around the LVEA, we had found what appeared to be a good alignment to our West Bay alignment monuments (BTVE-1, PSI-1, PSI-2, PSI-6, and height marks 901, 902, and 903 (for z-axis alignment only)).  We had found multiple errors in z-axis coordinates for the 4 alignment monuments, eventually having to perform a water tube level survey of the BSC2 door flanges to re-establish our Z=0, then propagate that measurement to our alignment monuments to establish accurate z-axis coordinates w.r.t. WBSC2.  Alogs from that work for some "light" reading: 75669, 75771, 75974, 76889, and 77216.

Jumping the X-arm Beam Tube

Our main challenge with this effort was moving the FARO to the other side of the X-arm beam tube (BT).  Our most readily-accesible alignment monuments for the FARO are all in the West Bay, with no access back to these monuments once we had moved to the outside of the BT; this simple fact makes an accurate device move for the FARO very difficult (a device move is most accurate when we can shoot a mixture of nests at the new position and at the previous position(s) ).  We had set several nests along the wall near the X-arm BT to assist in making the move, as well as using existing nests along the frame of the High-Bay rollup door, but still our position errors for the device move were >0.5 mm.  TJ O'Hanlon was visiting in June 2024 and we brainstormed several methods to tighten up this positional uncertainty.  Ultimately we decided to place temporary nests on the BTs themselves to aid in the initial and final device moves (temporary because as soon as we vent the nests move with the vacuum system, and don't necessarily return to the same spot once the vertex is back under vacuum).  We set 4 nests along the top of the X-arm BT, 6 nests along the top of the Y-arm BT, and a single lonely nest on the bottom of the Y-arm BT; the Y-arm BT nests we to allow us to close the circle once we moved from the input arm area back into the West Bay.  At this point we were interrupted for some PSL work (PMC swap, early July), the vertex vent for the OFI repair (July - August), and then the PSL frequency noise issues (late-September to December).  We were finally able to restart this effort in mid-December 2024 and test our "new" method for jumping the BT.  And it worked!  Our first positional uncertainty was <0.1 mm, so we began setting alignment nests and moving the FARO around the LVEA.

Moving Around the LVEA

We started in the High-Bay area, setting nests as needed and moving to the next position to set more nests, then moving to the next position to set more...  You get the idea.  Our route took us around the outside of the LVEA.  Starting in the High-Bay area, we proceeded down the +X side of the output arm (WHAM 5/6) and back up the -X side towards WHAM3; then down the -Y side of the input arm, around the PSL enclosure, and then back up the +Y side; and finally back in the West Bay to tie back into our original nests and apply the alignment to the LVEA local coordinate system.  The issue here is the FARO really likes a large volume for accurate device moves, and this is something we definitely do not have along the outside edge of the LVEA (this is also where most IAS work takes place).  We are essentially moving down a series of hallways, the hallways being the narrow walking areas between the vacuum chambers and the LVEA walls.  These narrow corridors restrict the volume we can use for setting nests, which means device position errors begin stacking up as we continue to move around the LVEA.  In addition, due to the vacuum equipment restricting line of sight we quickly lose sight of nests at previous device positions, which in turn causes position errors to begin stacking up; for most of our trip around the LVEA we only had sight to the device position immediately preceding the current one, and nothing further back.  This is, unfortunately, unavoidable due to the physical layout of the LVEA.  In an ideal world we would be able to do all of this with an empty LVEA, but that's not possible so we deal with what we have.

PolyWorks can estimate the device position error, so the 1st attached picture shows the results after we completed our circuit around the LVEA and tied back into our initial monuments in the West Bay.  Ignore the Pass/Fail under the Test column, I didn't change PolyWorks' default of 0.25 mm and we don't really have a metric for this right now, the important thing here is the value in the Uncertainty column.  PolyWorks uses a Monte Carlo simulation to calculate device position uncertainty, defaults to 100 simulations per device position; these results are given as 2 standard deviations (PolyWorks default) for each position from the instrument origin.  This means that ~95% of the device's calculated positions from the simulations are within the listed uncertainty.  Position 1 is our starting point by WBSC4 (old H2 BS chamber), with a view of our temporary nests on the X and Y BT, as well as the nests on the wall across the X BT and the High-Bay rollup door frame; position 2 is our jump over the X-arm BT; positions 3 through 6 are down the output arm and back up the other side to WHAM3; positions 7 through 10 are down the input arm, around the PSL enclosure, and back up the +Y side; position 11 is the final position we used before moving back into the West Bay, near the TCSy table (with a view of the monuments we placed on the Y-arm BT); position 12 is back in the West Bay close to the biergarten, and positions 13 and 14 are near the mechanical test stand by the West wall of the LVEA (14 is a repeat of 13 to account for device drift after sitting overnight).  As can be seen, the estimated positional uncertainty grows as we move down the "hallways" of the output and input arms, with the worst uncertainty at the positions furthest from our starting point (positions 7-10, around the input arm).  At this time I'm not sure we can do much better, given the constraints of the physical layout of the LVEA; we spoke with LLO at the last IAS meeting and they reported seeing similar numbers in their LVEA circuit.  With the LVEA circuit complete, we moved back into the West Bay to grab the last nests there that couldn't see from our initial position and to align to the LVEA local coordinate system.

Aligning to the LVEA Local Coordinate System

Back in the West Bay we collected the last of the red nests for FARO alignment and our alignment monuments (BTVE-1, PSI-1, PSI-2, PSI-6, and height marks 901, 902, and 903).  We used the 5" sphere fit rod to grab BTVE-1 and the PSI monuments.  We replaced the magnetic nests we had been using for the 3 height marks with glue nests, and glued them down.  Using an autolevel and a scale we measured the difference between where the nest ended up and where the height marks were (since the glue sets fast we couldn't sight the nests in directly inline with the height marks):

• Nest z-axis position w.r.t. height mark
  • 901: +0.5 mm
  • 902: -1.7 mm
  • 903: -0.5 mm

As done back in April 2024 (alog 77216), we used the z-axis coordinate for the BTVE and PSI monuments that had been corrected for the depth of the punch in the monument (since the sphere fit rod measures to the point at the base of the rod, which sits in the punch, and not the monument surface) and that had been corrected by our water tube level survey of WBSC2.  We used BTVE and the 3 PSI monuments to get a rough X,Y,Z alignment (again, not using PSI-6 for z-axis alignment since we do not trust its z-axis coordinate).  This rough alignment was then used to capture X and Y coordinates for the nests at the height marks, then the height marks were used to enhance the z-axis alignment (not used for X and Y).  The results of this alignment are shown in the 2nd attached picture; for ease of comparison I've included the alignment results from April 2024, see the 3rd attached picture.  This alignment is similar to the one we had back in April 2024, with a couple of differences that at first glance look large.  The X and Y coordinates for height marks 901, 902, and 903 deviate by large amounts compared to what we had measured with our rough, BTVE/PSI only alignment, which was not the case in our April 2024 alignment.  But if you look closely, you see that the measured components for the height marks in both alignments (March 2025 and April 2024) are very similar; this is what is important.  We don't really care about the X and Y coordinates for the 3 height marks as we aren't using them in the alignment, and they were only captured using a rough alignment to begin with.  The fact the measured components are matching fairly well lends some confidence to this alignment.  The difference between the 2 that has the most potential impact is in the measured z-axis coordinates of the BTVE/PSI monuments.  These z-axis coordinates are all roughly a factor of 2 worse in the March 2025 alignment vs the April 2024 one.  In addition, the alignment statistics on the left side of the screenshot are all better in the April 2024 alignment.  The only explanation I have for this is in April 2024 we were working in the West Bay and only the West Bay, while here and now we moved the tracker all over the LVEA, thereby carrying around some positional error in the device that wasn't present in the April 2024 alignment.  The only way to really test this alignment is to measure some monuments/features in the LVEA with known coordinates and see how they match.  The upcoming pre-deinstall FARO shots to the WHAM1 passive stack will be a good test of this alignment.  Another good monument to look at would be BTVE-5, over by the X-arm termination slab (by the cryopump/OpLev area).

As another test, since we haven't exactly trusted the repeatability of the sphere fit rod in the past, we tried using points for PSI-1 and PSI-2 and applying the alignment using those; we still had to use the sphere fit rod on BTVE-1 due to its dome shape and on PSI-6 due to it sitting inside an electronics rack in the biergarten (the bottom rail of the rack blocks direct line of sight to the monument, but the 5" sphere fit rod clears the top of it).  The results of this are shown in the 4th attached picture.  Right away it's clear this alignment is not as good as the one shown in the 2nd picture.  The statistics are all worse, and the match between measured coordinates is worse as well.  This one gets discarded and we move ahead with the previous alignment using sphere fit rods for the BTVE/PSI monuments.  Next we tested importing our move device targets into a blank PolyWorks file and aligning to them.

Global Target Test

PolyWorks allows you to import global targets from a text file.  In PolyWorks, a global target is one whose position is precisely known and does not change.  Now that we've applied our alignment to our list of device position targets we have [X,Y,Z] coordinates in the LVEA local coordinate system for all of them.  These coordinates can be exported into an Excel spreadsheet and formatted into a text file for import into a future PolyWorks project.  We did a test of this, using a duplicate of our working PolyWorks project to keep from accidentally modifying our working project file.  The format for the text file is 4 columns: X position, Y position, Z position, monument name.  The file can have no headers (PolyWorks gets mad if there are headers), and the units must be consistent (we use mm).  When importing the text file you have to specify the units used on the Import Global Target window (again, we use mm).  Once the targets have been imported into the new PolyWorks project, you set the tracker somewhere in the workspace with a good view of global target nests and measure them.  The tracker then automatically aligns to the coordinates of the global targets, thereby automatically aligning itself to the LVEA local coordinate system.  We did this using a blank project, and the results are shown in the 5th attached picture.  For the height marks we used the same nominal coordinates from the alignment (2nd picture again).  This is why they look so far off at first glance, but if you compare the measured coordinates they match really good.  For the PSI monuments we used a different toolilng to take those measurements.  Instead of the sphere fit rod we used our Hubbs Center Punch Nest (CPN).  This nest has a 2" vertical offset (the center of the SMR sits 2" above the bottom of the nest) and a built-in center punch for either making punch marks in monuments or accurately setting the nest in an existing punch mark.  Because of this we had to remove the z-axis correction for the punch depth we needed for the sphere fit rod, as the Hubbs CPN measures to the monument surface not the bottom of the punch.  These also look really good, with the exception of the measured z-axis coordinate for PSI-2.  At this time I don't really have an explanation for this discrepancy.

We also used these test coordinates to take some preliminary shots of the 2 accessible -X WHAM1 support tube ends; details of that in a future alog (this one is long enough already).

While pulling screenshots off of the FARO laptop for this alog I also exported the device position targets from our main working file, as these are the global targets we are going to use going forward (FARO_CS_LVEA_Global_Targets_v1.xlsx).  Between the main working file and the test file used to generate the global target list for the test in the two immediately preceding paragraphs, the only difference is a new device position in the main file, position 14; position 14 was necessary in the main working file as the FARO was sitting in the same spot for a week between maintenance windows (March 18 to March 25) and had therefore drifted in that timeframe (the FARO and tripod stand are heavy and slowly sink into the vinyl floor of the LVEA).  The fix for this is to do a Move Device action without actually moving the device, which accounts for any drift from the previous position.  The starting, unaligned coordinates of the red nests (which we turn into global targets) are the same, the alignment results are the same; again the only difference is that new position 14 in the main working file.  While removing the BT nests from the target list (since we are not going to use these for placing the FARO) I noticed that the coordinates looked a little different than I remembered.  So I threw together a quick and dirty comparison spreadsheet to calculate the differences (Global_Target_Coordinate_Differences.xlsx).  The first 4 columns of data are from the main working file, the next r columns of data are from the test file, and the final 3 columns are the difference (test - main).  Sure enough, the coordinates from the main file differ from the test file.  I set conditional formatting to turn red for any differences outside of +/-0.1 mm.  The largest differences are all in z-axis coordinates, and the largest of these are all nests placed along the input arm of the IFO (WHAM1/2/3) where are device position uncertainties are the largest.  These are small differences, the largest being on the order of 0.25 mm, spread out over 10s of meters of LVEA space, so I don't think this is a big issue, but interesting to note nonetheless.

And that's it!  I'll write another alog detailing the preliminary shots of the WHAM1 -X support tube ends.  The FARO is ready to go for the upcoming pre-deinstall shots of the WHAM1 passive stack (currently slated for Monday on the Trello).  This finally closes LHO WP 11757.

Matt, Camilla

While looking into a reason that we needed to continually increase EY RH over the last 6 months to avoid PIs, we've attached some trends.

In the past ~6 months there there was a 2% decrease in circulating power corresponding with a kappa_c decrease, Sheila and Dana found the same in 2023 75193. Plot here. Sheila and Dana thought this was as the OMC throughput has degraded since installation but we haven't re-checked that the balance of the two OMC DCPDs.

There is two distinct changes in PRG over the last 6 months: 10th Dec 2024 and 1st Feb 2025, I initially though they were conveniently a week or so before the EY RH increase, however they are when IM4 trans was centered 81735 / re-calibrated 82260 which probably cannot cause a physical change.

Interestingly the OM2 temperature is an interesting measure of the in change in temperature and that does change over the last 6 months, it's not clearly correlated with the circulating power change. Bottom trend of attached plot.

Ibrahim, Ryan S, Betsy, Sheila, Camilla

Getting a baseline for how much the HAM chambers have moved since they were locked.

• HAM4
  • HEPI RX,RY,RZ changed by 5urad, 6urad, 0.2urad
  • ISI RX,RY,RZ changed by 5urad, 1urad, 26urad
• HAM5
  • HEPI RX,RY,RZ changed by 4urad, 0.3urad, 0.7urad
  • ISI RX,RY,RZ changed by 7urad, 3urad, 45urad
• HAM6
  • HEPI RX,RY,RZ changed by 18urad, 2urad, 6urad
  • ISI RX,RY,RZ changed by 6urad, 3urad, 30urad

Highlighted the highest changes but none of these look particularly large.

HAM5 and HAM6 tripped just at the end of these trends too, not included in differences above, maybe a WD trip when a SEI is locked doesn't matter anyway.

I set up an internally pumped dust monitor, that I borrowed from the FCES (it was off down there). I used LVEA10's network cable from the Biergartens dust monitor so BSC8s cleanroom dust monitor is trendable as Dust mon LVEA10. The pumpless dust monitor in the biergarten is still taking samples but they're not being written to epics.

Tony, Corey:  HAM1 E/W Door bolts mostly removed; except for a set of 4-bolts on each door which were detorqued and their nut backed off a 1/2 turn.

Janos, Gerardo, Dave:

Following some alarms overnight we have decided to remove the LVEA gauges from VACSTAT for the duration of the vent. The other gauges which will remain under vacuum continue to be monitored, but without the increased sensitivity settings.

In order to keep the EDC green, a vacstat_dummy_ioc.py is running on opslogin0 to simulate the channels associated with the removed gauges (HAM1, HAM6, BSC2, BSC3).

The cell phone alarms to the vacuum group on multiple vacstat detections has also been disabled.

TJ and I completed a rough balance of the VOPO platform in the optics lab.

Done without cables as they and mounting hardware are not yet ready. We struggled to get the H1,V1 side of the platform up high enough. Platform was floating with 25-75g mass on OPO lid but H1,V1 bottoms out with 125g.  We will have some play of where we route the cables on the OPO lid which can help us. Attached are photos of the vertical alignment at the 3 blade posts, 1 and 2 were centered, 3 was a very little low.