[Tanaka,Hirose,Saito]

Abstract:

We fitted the beam profile of the IR laser on the POS optical table measured in klog: 36724. The waist position was found to be 259 mm, and the waist size was 0.054 mm. Based on these results and the fitted beam profile of the sub-laser, we calculated the positions of two lenses required for mode matching. Furthermore, we developed an optical layout plan for the measurements of PRCL and SRCL.

Detail:

First, we fitted the beam profile of the IR laser on the POS optical table measured in klog: 36724 (Fig.1). The points represent the measurement results, and the lines represent the fitting results. The green and orange points were used for the fitting, while the blue and red points were excluded because their behavior differed from the other measurement points.

The measurement points around 300 mm deviate significantly from the fitting curve because, as shown in Photo 2 of klog: 36724, the beam split into two, and both spots were simultaneously fitted with a Gaussian. The apparently reasonable behavior around 350 mm is because only one of the split beams was successfully fitted with a Gaussian. However, since the beam was distorted as shown in Photo 3 of klog:36724, it should have been compared with the beam between 100 mm and 250 mm to determine whether to include it in the fitting; unfortunately, no photos were taken in that range. In addition, when the mesurement points around 350 mm are included in the fitting (Fig.2), the mesurement points between 100 mm and 250 mm deviate from the fitting curve compared to Fig.1. Therefore, we decided to use the results from Fig.1 to determine the positions of the two lenses for mode matching. (For the measurements of PRCL and SRCL, it is sufficient to observe the resonance of the TEM00 mode, so a slight mismatch in mode matching is considered acceptable.)

The waist position and waist size obtained from the fitting in Fig.1 are as follows:

Major : waist position = 264.3 ± 5.1 mm, waist size = 0.0526 ± 0.0025 mm
Minor : waist position = 253.6 ± 2.3 mm, waist size = 0.0555 ± 0.0013 mm
→ Average: waist position = 259 mm, waist size = 0.054 mm

The laser to be newly installed on the POS optical table must be mode-matched to this waist position and size. Therefore, its beam profile was measured in advance in Kashiwa and fitted (Fig.3). The origin is defined as the point where the laser is emitted.

The waist position and waist size obtained from the fitting in Fig.3 are as follows:

Major : waist position = −118.8 ± 1.9 mm, waist size = 0.1469 ± 0.0008 mm
Minor : waist position = −127.8 ± 1.8 mm, waist size = 0.1562 ± 0.0008 mm
→ Average: waist position = −123 mm, waist size = 0.1516 mm

Next, based on these waist positions and waist sizes, we determined the positions of two lenses for mode matching (Fig.4). The origin is defined as the point where the laser is emitted. The orange line represents the beam profile of the laser, the green line represents the beam profile after passing through the first lens, the red line represents the beam profile after passing through the second lens, and the blue line represents the target beam profile of the infrared laser on the POS optical table. 

The focal lengths and positions of the two lenses are as follows:

Lens 1: focal length = 200 mm, position = 1426 mm
Lens 2: focal length = 500 mm, position = 2363 mm

Finally, based on the calculated lens positions, we designed an optical layout for a phase-locked loop (PLL) used in the measurements of PRCL and SRCL (Fig.5). The right-hand side of Fig.5 corresponds to the optical system designed in this work.

[Washimi, Takahashi]

We replaced the satellite box for the IM H OSEMs. The previous box is  S1604901 (Pic. 1 and 2). The new box is  S1807635 (Pic. 3 and 4). The OSEM outputs were changed as follows (Pic. 5). The transfer functions for H2 (Pic. 7), H3 (Pic. 8), and Y (Pic. 10) were the same as the previous measurements. The DC gain of the transfer functions for H1 (Pic. 6) and L (Pic. 9) was increased by 5dB. The H1 OFFSET in "K1 SRM IM OSEMINF FILTERS" was returned from -3700 to -6315.5.

I added the F0 transfer function measured with a modified template.

I checked the transfer functions of F1, BF, IM, and TM. The states during the measurement were READY for F1 and BF, TWR_FLOAT for IM and TM. The diaggui for F0 did not work. 

[Tanaka,Hirose,Saito]

In preparation for the measurements of PRCL and SRCL, we measured the IR laser power and beam profile on the POS optical table.
The laser power was approximately 15μW.

• On the POS optical table, the IR laser passed through a periscope, a beam splitter that separates the green laser and IR laser, and a lens. It was then reflected by a mirror and finally directed toward PDs for S-polarization and P-polarization. We placed a power meter in front of the mirror to measure the laser power, which was approximately 15μW.
• Next, we placed an additional mirror in front of the original mirror (at a position approximately 450 mm from the lens)(Photo 1) and measured the beam profile of the IR laser. In this measurement, the origin was defined as the center of the hole on the optical table where the additional mirror was placed. A beam waist was observed at approximately 263 mm, but the beam split into two at around 300 mm (Photo 2). Even at 575 mm, the beam remained distorted (Photo 3). The measurement was initially performed in the single bounce configuration. Considering the possibility of birefringence effects, the Y-arm was then locked. However, almost no change was observed (Photo 4).

The fitting results of the beam profile will be posted later.

[Washimi, Takahashi]

• We removed the 1kg ballast ring from the IP. The resonant frequencies for L and T were close to the reference (klog).
• We investigated the IM H1 OSEM. Details are here.
• We adjusted the H1 OSEM position to 2800 (near the middle of the dynamic range). The H1 OFFSET in "K1 SRM IM OSEMINF FILTERS" was changed from -6315.5 to -3700.
• We checked the height of the TM/RM. One laser leveler (red) was set to the height reference on the chamber (Pic. 1). The other laser leveler (green) was set to the red line (Pic. 2). The red line consisted of the X+ side wire breaker on the RM (Pic. 3), and was 0.5mm higher than the marker on the front ring of the RM (Pic. 4). The green line also consisted of the X- side wire breaker on the RM (Pic. 5), and consisted of the marker on the front ring of the RM (Pic. 6).
• We adjusted the gap of the EQ stops and took pictures of them.

This afternoon, I entered PSL and offloaded manually IP1 PZT PIT and YAW, which are used as DOF4 PIT and YAW controls. After that, IMC seems to be stable without any satuaration.

We checked the IP transfer functions after removing the third 1kg ballast ring.  The resonant frequencies of the IP were changed from 59 to 66mHz for L and from 66 to 70mHz for T. They were close to the reference (63mHz for L, 70mHz for T).

[Washimi, Takahashi]

We investigated the IM H1 OSEM. The transfer function was recovered when the OSEM position was in the linear range, 5600 (Pic. 1). We swapped the stellite box channel for H1 and H2. The output was changed (Pic. 2) as shown in the table. Ch. 1 output was smaller than that of Ch. 2 in both cases. The satellite box has a problem. The transfer function of H1 using Ch. 2 showed a gain higher than the reference (Pic. 3).

I offloaded the BF GAS with the FR.

[Washimi, Takahashi]

We adjusted the suspension.

• After offloading the BF and F1 GAS filters, we adjusted the V1/2/3 OSEM positions to the center of the range.
• We removed the 1kg ballast ring from the IP. The resonant frequencies for L and T were changed (klog).
• We investigated the small gain of the H1 OSEM in the IM transfer functions (Pic. 1). We checked the forward voltage of the diodes and resistance at the feedthrough flange (Table). They were normal. We calibrated the OSEM output by moving the IM body in the 1/4 pitch of the M4 screw for the EQ stop (Pic. 2). The maximum value was 7500 counts (Pic. 3). The calibrated coefficient was 0.136 um/count (Pic. 4). The original coefficient was 0.299 um/count.

[Tanaka, Ushiba, Hirose]

In preparation for the PRCL and SRCL measurements, we replaced the PDH Local Oscillator(LO) for the GRX with the measurement LO and checked the number of optical components.

• We prepared an LO to do phase-locked loop (PLL) using the sub-laser and main-laser beams by combining them in the POS table. A phase-locked loop (PLL) cannot operate properly unless the LO has a lower noise level than the phase noise. The LO for the GRX’s PDH is a High-spec LO (photo1 below) that can also be used for the PLL, so we will use this one. We replaced the LO for the PDH with a new one(photo1 above, photo2, photo3) that satisfied for PDH.
• For this experiment, we plan to use the mirrors, HWP, PBS, and lenses stored in the front room of the PSL. Mirror mounts, lens mounts, HWP mounts, IRIS, and other items will be taken from the areas around the POP and IMCREFL.
• We confirmed the number of optical components(excluding the 2-inch mirror) in the current PSL front room, so I posted the details(JGW-T2415582-v6) on JGWdoc.

I checked the IP transfer functions after removing the second 1kg ballast ring.  The resonant frequencies of the IP were changed from 55 to 59mHz for L and from 63 to 66mHz for T. They are still lower than the reference (63mHz for L, 70mHz for T).

I offloaded the F0 GAS with the FR.

[Ikeda, YamaT]
 

Abstract

In recent these days, we replaced IO chassis from V1 to V2.
(K1TEST0 in klog#33560, K1IX1 in klog#36572, K1IY1 in klog#36625, K1EX0 in klog#36654, and K1EY0 in klog#36692).
Real-time models on these front-ends seemed to work well.
But they had a problem that a IRIG-B timing took so long time to be stable when the cold boot of the front-end computer was performed.

Last weekend, we realized that this might be caused by a mix-up of different fiber-optic cables.
So we replaced fiber-optic cables of K1TEST0, K1IX1, K1IY1, and K1EX0 to the correct combination.
After then, the issue of the timing synchronization taking too long no longer occurred.

We had no enough time to go to Y-end today, so we will do same thing for K1EY0 tomorrow.
 

Details

The V2 IO chassis uses a new cable connection standard, and some of its specifications are different from those of the V1 IO chassis. The most significant difference is that the data transfer cable between the front-end computers and the IO chassis has been changed from custom-made HIB optical fiber to standard MTP fiber (OM3). Thanks to this change, we are no longer constrained by the limited availability of HIB cables and we can provide additional IO chassis as spare ones and/or for new instruments in future e.g. filter cavity.

In addition to this change, timing fiber cable in the IO chassis was also changed to the OM3 cable. Strictly speaking, the SFP port of the timing slave was directly accessible from the front panel on V1 IO chassis and any SFP module could be attached, so there were no internal cables. In other words, it is more accurate to say that the interface was changed rather than the cable standard.

Until now, OM1 cables have been installed for multimode optical fiber, not just for timing signals. (Since single-mode fiber, OS1, is used for long-distance connections, this is slightly off-topic.) So the most of timing slaves in the V1 IO chassis were connected to the timing fanout with OM1 cable and we had reused them for V2 IO chassis when we had replaced IO chassis from V1 to V2.

Although the real-time models themselves were running well also in this configuration, there remained a mystery as to why it took several hours for the IRIG-B timing to stabilize after a cold boot of the front-end computer. Figures 1 and 2 show the fluctuations in the IRIG-B value following a cold boot on EY0 and IX1, respectively. Both of them shows that it takes o(hours) time to stabilize the IRIG-B value within normal range (5-20us). And also, for EY0 (Fig.1), it's reproduced in 3 times trial.

The IRIG-B value is not the primary source of timing synchronization but merely serve as a cross-check. However, if they fall outside the normal range, RFM and Dolphin communication will fail. As a result, a global control cannot be done. Even if it took so long time to stabilize IRIB-B value, it finally went to normal range. So we was able to resume global control by waiting this fantastic time. But waiting time as o(hours) was serious from the view point of effective downtime of the digital system for keeping commissioning time and also observing time.

At first, we didn’t realize the relation between the IRIG-B issue and fiber cables standard, but we finally noticed that OM1 and OM3 cables have different core diameters (62.5 μm and 50 μm, respectively) and that mixing them can cause speed reductions and instability especially for the long distance connection in Ethernet case. To be honest, I wasn’t sure if the same discussion applied to Timing synchronization, but We decided to try unifying the fiber cable as OM3.

After replacing the fiber cable, we didn't need to wait that IRIG-B timing was stabilized. And it's not reproduced in a few times power-cycle. After replacing the fiber cable, we didn't need to wait that IRIG-B timing was stabilized. And it didn't appear also in a few times power-cycle. So we concluded that the IRIG-B issue was induced by the mismatch of the optical fiber standard. Today, we was able to complete a replacement work for K1TEST0, K1IX1, K1IY1, and K1EX0. Reaming K1EY0 will be processed tomorrow.

[Washimi, Takahashi]

We recovered the flags touching the OSEM bodies in the IM. We rotated the IM with the yaw picomotor, aligning the TM with the F0 yaw FR. The H3 flag was released easily (Pic. 1 and 2), then the H1 (Pic. 3) and V2 (Pic. 4) flags touched the OSEM bobies. Though we tried to find good relative geometry between the IM and the IRM, we could not find it. The strategy was changed; we adjusted the positions of the OSEM bodies, moving the base panel of the OSEMs. The axial positions of the H1, H3, and V1 OSEMs were also adjusted. We rotated the H2, H3, and V3 flags to be perpendicular to the LED-PD line in the OSEM.