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LIGO-G09xxxxx-v1
Form F0900043-v1 LIGO Laboratory 1
Designing a frequency offset locking loop
for the 40m prototype
Arm Length Stabilization System
Sai Akhil Reddy
Indian Institute of Technology , Patna
Mentors: Manasa T., Eric Quintero, Koji Arai
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Outline of the Talk
What is Arm Length Stabilization (ALS)? Issues in the ALS system. Solving the issue: Frequency Offset Locking (FOL)
Loop. Building the FOL control loop. Challenges faced. Testing and Commissioning
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Advanced LIGO Optical Configuration
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Arm Length Stabilization (ALS)
Precise length measurements ⇔ Lock acquisition of the interferometer.
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Arm Length Stabilization (ALS)
Precise length measurements ⇔ Lock acquisition of the interferometer.
Problems: Higher degrees of freedom due to coupling of cavities, non-linearities in length measurement and noise.
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Arm Length Stabilization (ALS)
Precise length measurements ⇔ Lock acquisition of the interferometer.
Problems: Higher degrees of freedom due to coupling of cavities, non-linearities in length measurement and noise.
Multicolour laser interferometry technique
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Arm Length Stabilization (ALS)
Precise length measurements ⇔ Lock acquisition of the interferometer.
Problems: Higher degrees of freedom due to coupling of cavities, non-linearities in length measurement and noise.
Multicolour laser interferometry technique. Length information from Pound Drever Hall (PDH)
scheme.
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Pound Drever Hall (PDH) Scheme
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Arm Length Stabilization (ALS)
Precise length measurements ⇔ Lock acquisition of the interferometer.
Problems: Higher degrees of freedom due to coupling of cavities, non-linearities in length measurement and noise.
Multicolour laser interferometry technique Length information from Pound Drever Hall(PDH)
scheme. Beat note between the Green Auxiliary(AUX) laser
and the infrared Pre-Stabilised(PSL) used to stabilize the length of the cavity using a digital servo.
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Arm Length Stabilization (ALS)
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Issues in the ALS system
Frequencies of two lasers hugely different (could vary by few GHz).
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Issues in the ALS system
Frequencies of two lasers hugely different (could vary by few GHz).
The PDH control loop of the AUX laser allows its frequency to follow the motion of the cavity length.
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Issues in the ALS system
Frequencies of two lasers hugely different (could vary by few GHz).
The PDH control loop of the AUX laser allows its frequency to follow the motion of the cavity length.
The laser cavity Piezoelectric(PZT) actuator has a control range of a few hundred MHz and an actuator response of around 5 MHz/V.
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Issues in the ALS system
Frequencies of two lasers hugely different (could vary by few GHz).
The PDH control loop of the AUX laser allows its frequency to follow the motion of the cavity length.
The laser cavity Piezoelectric(PZT) actuator has a control range of a few hundred MHz and an actuator response of around 5 MHz/V.
The PZT control becomes ineffective when the beat note between the lasers crosses the actuator range mainly due to green PD range.
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Motivation of FOL Loop
Slow control: Temperature Actuation -- larger response (1 GHz/K).
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Motivation of FOL Loop
Slow control: Temperature Actuation -- larger response (1 GHz/K).
Tracks the infrared (PSL) beat note frequency and pushes it within the efficient working range of ALS (<100 MHz).
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Motivation of FOL Loop
Slow control: Temperature Actuation -- larger response (1 GHz/K).
Tracks the infrared (PSL) beat note frequency and pushes it within the efficient working range of ALS (<100 MHz).
So we build an automated Servo using a Proportional-Integral-Derivative controller (PID).
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Motivation of FOL Loop
Slow control: Temperature Actuation -- larger response (1 GHz/K).
Tracks the infrared (PSL) beat note frequency and pushes it within the efficient working range of ALS (<100 MHz).
So we build an automated Servo using a Proportional-Integral-Derivative controller (PID).
FOL Works even when the green arm is not locked unlike the already existing temperature loop.
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FOL Loop
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Building the Digital Feedback System
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ARM Processor
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Control Sensor
RF Frequency Counter-Mini-Circuits Model UFC-6000 RF Frequency Counter
Frequency range of 1 MHz- 6000 MHz.
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Resolving Timing Issues of R Pi and FC
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Raspberry Pi: not an RTOS
Issues in clock synchronization
of R Pi and FC.
Setup external clock to
synchronously read data from
the FC
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Transfer Function of the Frequency Counter
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Noise Characterization in FC
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Transfer Function of the Plant: Thermal Actuator
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Thermal Actuator- Slow control actuator : Actuates on the temperature of the NPRO
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Interface with EPICS Channels
Experimental Physics and Industrial Control System (EPICS): set of software components and tools used to create control systems.
IOC: Input / Output Controller - Network and device interface
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PID Controller Design
P =
I =
D =
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Installed FOL Box
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Testing and Commissioning
Setup tested with existing green laser beat note.
To be tested with the infrared PSL after completion of optics installation.
The FOL box will be permanently placed inside the 40m and the software issues can be remotely debugged.
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Acknowledgements
Mentors: Manasa T., Eric Q, Koji A. 40m folks: Rana A., Jamie, Jenne D., Steve V. Co-Interns: Harry, Nichin, Andres Organizations: Caltech and NSF
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Thank You
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