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Revision 4 as of 2011-12-19 21:46:48
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Revision 6 as of 2011-12-19 21:47:42
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Deletions are marked like this. Additions are marked like this.
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 * [attachment:ass.png Conceptual Diagram]
 * See also the old [[Alignment Sensing and Control]].
   * [attachment:ass.png Conceptual Diagram]
   * See also the old [[Alignment Sensing and Control]].
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The input signals to ASS are:  . The input signals to ASS are:
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|| '''PD1''' || TRX ||
|| '''PD2''' || TRY ||
|| '''PD3''' || POX33I ||
|| '''PD4''' || POY33I ||
|| '''PD5''' || SP166Q ||
|| '''PD6''' || SPOB66 ||
|| '''PD7''' || AP DC ||
|| '''PD8''' || PO DC ||
 || '''PD1''' || TRX ||
 || '''PD2''' || TRY ||
 || '''PD3''' || POX33I ||
 || '''PD4''' || POY33I ||
 || '''PD5''' || SP166Q ||
 || '''PD6''' || SPOB66 ||
 || '''PD7''' || AP DC ||
 || '''PD8''' || PO DC ||
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These are displayed on the ASS MASTER display.  . These are displayed on the ASS MASTER display.

Alignment Sensing & Stabilization system

Overview

  • This is a dither based system. The idea is to dither (in pitch and yaw) all of the interferometer optics. We then read out the power (arm powers, PRC power, etc.) and demodulate at the dither frequencies. We can then feedback to control the full interferometer alignment.
  • The concept is the same as what we use to do the initial alignment of the interferometer. It was previously tried by Valera and Bram, but never worked for some reason...

Control Topologies

Input signals

  • The input signals to ASS are:

    PD1

    TRX

    PD2

    TRY

    PD3

    POX33I

    PD4

    POY33I

    PD5

    SP166Q

    PD6

    SPOB66

    PD7

    AP DC

    PD8

    PO DC

  • These are displayed on the ASS MASTER display.

ilog entries

BR BR


Thoughts in Early Time

  • Below are two diagrams which illustrate the proposed method to align the 40m IFO while it is locked. Currently the controls are done using Perl scripting.
  • In the diagrams the dither signals to the optics are in the YAW axis of the optics, but this is done in a similar manner in the PIT axis. The labels in the colored boxes are the channels (shown in YAW, but valid for PIT as well) to which the obtained error-signals, from the demodulation, are fed back to.

attachment:DC_ASC_Inline.png

  • Figure 1. Diagram of the 40m IFO in-line arm cavity (XARM). The PRM and BS are omitted for clarity.

In-line cavity legend - Figure 1:

IP_POS

Otherwise known as PZT1, located in front of the PRM. Steers the beam into the IFO.

IP_ANG

Otherwise known as PZT2, located after IP_POS and before the PRM. Also, steers the beam into the IFO.

ITMx

The ITM of the x-arm, ITMX.

ETMx

The ETM of the x-arm, ETMX.

PDH-err

The demodulated length control signal, C1:LSC-XARM_IN1.

TRX

The transmitted power of the x-arm, C1:LSC-TRX_OUT.

L.O. ITMx

Modulation of the ITMx in PIT or YAW using tdssine.

L.O. ETMx

Modulation of the ETMx in PIt or YAW using tdssine.

attachment:DC_ASC_Perp.png

  • Figure 2. Diagram of the 40m IFO perpendicular arm cavity (YARM).

Perpendicular arm legend - Figure 2:

BS

Beamsplitter, steers the beam into the perpendicular arm cavity (y-arm).

ITMy

The ITM of the y-arm, ITMY.

ETMy

The ETM of the y-arm, ETMY.

PDH-err

The demodulated length control signal, C1:LSC-YARM_IN1.

TRY

The transmitted power of the y-arm, C1:LSC-TRY_OUT.

L.O. ITMy

Modulation of the ITMy in PIT or YAW using tdssine.

L.O. ETMy

Modulation of the ETMy in PIt or YAW using tdssine.


Diagram for digital dither alignment scheme of the DRFPMI attachment:40mASC.pdf

Dither_ASC (last edited 2012-01-03 23:02:43 by localhost)