Differences between revisions 3 and 34 (spanning 31 versions)

Interferometer Characterization at the 40m prototype

Goals

To help the DRMI commissioning that will be performed at LLO.

Motivations

In the aLIGO schedule a DRMI test will start on May 2011 at LLO. Prior to the DRMI test we, the 40m lab, should help their commissioning to make the things smooth and hence allow to finish the commissioning in the shortest time. Moreover any commissioning tests that will be performed at LLO should be well predicted and tested at the 40m so that the people at the site can easily pass through all the commissioning tests and possibly can spend time for a real trouble shooting (commissioning) to fix unexpected issues.
So for this purpose some recipes must be prepared by the 40m lab. Each recipe includes descriptions about how to make a commissioning test, how to estimate important parameters and the results at the 40m. Additionally some useful scripts must be developed at the 40m.

BR BR

Contents

Interferometer Characterization at the 40m prototype
1. Goals
2. Motivations
DRMI Characterization Plan at the 40m
References

DRMI Characterization Plan at the 40m

Schnupp asymmetry measurement and its adjustment

Requirement

 Schnupp asymmetry = 0.0342 [m] +/- XXX [mm]

The Schnupp asymmetry determines the reflectivity r and transmissivity t of the Michelson for the f1 and f2 sidebands when the carrier is kept in the dark condition. In the design the f2 sideband should be critical coupling in the dual recycling cavity [#ref1 [1]] [#ref2 [2]]. To achieve the critical coupling we should adjust r and t properly.
According to a simulation the asymmetry should be within the precision of XXX mm to achieve more than 95 % of the power build up.

How to

Here is an instruction how to measure the Schnupp asymmetry.

Results

The result at the 40m was ... and the precision was +/- XXX mm. This implies us to fix the length of the asymmetry.

BR BR

PRC length measurement and its adjustment

Requirements

{{{ lprc = 6.7538 [m] +/- XXX [mm]

}}}

In order to resonate both f1 and f2 sidebands the length should be adjusted to ..
In addition to that the arm makes the non-zero phase shift on these sidebands and makes the ..

How to

To measure the length of the recycling cavity,

Results

BR BR

SRC length measurement

Requirements

{{{ lsrc = 5.39915 [m] +/- XXX mm }}}

How to

Results

BR BR

Recycling gain measurements

Since the recycling gain is related to loss in the recycling cavity,...

How to

Results

 Carrirer    = XX
 f1 sideband = YY
 f2 sideband = ZZ

BR BR

Beam spot position on BS

Requirements

{{{ off-centering < XXX mm }}}

To get a clean AS signal

How to

results

BR BR

Reflectivity check

How to

Results

BR BR

Sensing matrix check

How to

Results

BR BR

Calibration of Actuator responses

How to

Results

BR BR

f2a filter adjustment

Requirement

How to

Results

BR BR

IFO modeling

How to

Results

BR BR

Locking procedure

How to

BR BR

MICH actuator decoupling

Requirements

{{{ Precision < 1 % (?)

}}}

When the DRMI is locked the MICH control signal is fed back to the BS actuator, but the actuation on BS intrinsically changes the PRC and SRC length as well as the MICH length ( lx-ly). This means the noise from MICH can be transferred to the PRC and SRC, resulting in the degradation of noise performance in the PRC and SRC [#ref3 [3]].
To avoid the coupling the MICH control should also actuate on PRM and SRM to minimize the coupling.

How to

BR BR BR BR

References

[1] [2] [3] [#plantop back to top]

-  ⇤ ← Revision 3 as of 2011-06-06 20:55:09 → 
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+   ← Revision 34 as of 2011-06-07 21:01:35 → ⇥
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-= Interferometer Characterization =
== Goals and Motivations ==
+= Interferometer Characterization at the 40m prototype =
== Goals ==
 . ''''' To help the DRMI commissioning that will be performed at LLO.'''''
== Motivations ==
 . In the aLIGO schedule ''''' a DRMI test will start on May 2011 at LLO. ''''' Prior to the DRMI test we, the 40m lab, should help their commissioning to make the things smooth and hence allow to finish the commissioning in the shortest time. Moreover any commissioning tests that will be performed at LLO should be well predicted and tested at the 40m so that the people at the site can easily pass through all the commissioning tests and possibly can spend time for a real trouble shooting (commissioning) to fix unexpected issues.
 . So for this purpose some recipes must be prepared by the 40m lab. Each recipe includes descriptions about how to make a commissioning test, how to estimate important parameters and the results at the 40m. Additionally some useful scripts must be developed at the 40m.
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-[[BR]]
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+Line 12:
+[[BR]]
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-[[BR]]
= Characterization Plan at the 40m =
== Schnupp asymmetry ==
+ <<Anchor(plantop)>>
= DRMI Characterization Plan at the 40m =
== Schnupp asymmetry measurement and its adjustment ==
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+  . {{{ 
 Schnupp asymmetry = 0.0342 [m] +/- XXX [mm]
}}}
 . The Schnupp asymmetry determines the reflectivity '' r ''and transmissivity '' t '' of the Michelson for the f1 and f2 sidebands when the carrier is kept in the dark condition. In the design ''' the f2 sideband should be critical coupling in the dual recycling cavity '''[#ref1 [1]] [#ref2 [2]]. To achieve the critical coupling we should adjust '' r '' and '' t'' properly.

 . According to a simulation the asymmetry should be within the precision of XXX mm to achieve more than 95 % of the power build up.

=== How to ===
 . Here is an instruction how to measure the Schnupp asymmetry.
=== Results ===
 . The result at the 40m was ... and the precision was +/- XXX mm. This implies us to fix the length of the asymmetry.


[[BR]][[BR]]

------
== PRC length measurement and its adjustment ==
=== Requirements ===
 . {{{ lprc = 6.7538 [m] +/- XXX [mm]
}}}
 . In order to resonate both f1 and f2 sidebands the length should be adjusted to ..

 . In addition to that the arm makes the non-zero phase shift on these sidebands and makes the ..

=== How to ===
 . To measure the length of the recycling cavity,

=== Results ===
 .
[[BR]][[BR]]

------
== SRC length measurement ==
=== Requirements ===
 . {{{ lsrc = 5.39915 [m] +/- XXX mm
 }}}
=== How to ===
 . 
=== Results ===
 .
[[BR]][[BR]]


------
== Recycling gain measurements ==
 . Since the recycling gain is related to loss in the recycling cavity,...
=== How to ===
 .
=== Results ===
 . {{{
 Carrirer    = XX
 f1 sideband = YY
 f2 sideband = ZZ
}}}
[[BR]][[BR]]

------
== Beam spot position on BS ==
=== Requirements ===
{{{ off-centering < XXX mm
}}}
 . To get a clean AS signal

=== How to ===
=== results ===

[[BR]][[BR]]
------
== Reflectivity check ==
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-[[BR]]
+[[BR]][[BR]]
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-== Cavity length ==
=== Requirements ===
+------
== Sensing matrix check ==
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-[[BR]]
+[[BR]][[BR]]
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-== Recycling gains ==
+------
== Calibration of Actuator responses ==
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-[[BR]]
+[[BR]][[BR]]
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-== Sensing matrix ==
=== How to ===
=== Results ===
[[BR]]

== Actuator responses ==
=== How to ===
=== Results ===
[[BR]]
+------
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+[[BR]][[BR]]

------
== IFO modeling ==
=== How to ===
=== Results ===
[[BR]][[BR]]

------
== Locking procedure ==
=== How to ===

[[BR]][[BR]]
------
== MICH actuator decoupling ==
=== Requirements ===
 . {{{ Precision  < 1 % (?)
}}}

 . When the DRMI is locked the MICH control signal is fed back to the BS actuator, but the actuation on BS intrinsically changes the PRC and SRC length as well as the MICH length ('' lx-ly''). This means the noise from MICH can be transferred to the PRC and SRC, resulting in the degradation of noise performance in the PRC and SRC [#ref3 [3]].
 . To avoid the coupling the MICH control should also actuate on PRM and SRM to minimize the coupling.

=== How to ===
[[BR]]
[[BR]]
[[BR]]
[[BR]]
------
= References =
<<Anchor(ref1)>>
[1]
<<Anchor(ref2)>> 
[2]
<<Anchor(ref3)>>
[3]
[#plantop back to top]