Understanding Cabling Noise in LIGO Chihyu Chen Lafayette College Mentors: Mark Barton Norna Robertson Helpful Researcher:Calum Torrie Co-SURF:Julian Freed-Brown.

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Presentation transcript:

Understanding Cabling Noise in LIGO Chihyu Chen Lafayette College Mentors: Mark Barton Norna Robertson Helpful Researcher:Calum Torrie Co-SURF:Julian Freed-Brown

Cabling connecting the OMC bench to the cage

Pendulum as a vibration isolator Single pendulum resonant at 1 Hz How would the cabling deteriorate the isolation?

For structural damping For velocity damping

Method Experimental characterization of the cabling’s damping function. -Jimmy Chen Computer modeling to apply the damping function to specific cabling-attached-to- suspension systems. -Julian Freed-Brown

Apparatus Two wire torsion pendulum Support structure for the pendulum Cabling Apparatus Design Goals 1. An order of magnitude variability in yaw and pitch frequency 2. Cases that can be easily modeled 3. Stiff support structure

Yaw frequency range: 0.14 Hz – 1.27 Hz Pitch frequency range: 0.41 Hz Hz Varying pitch frequency Varying yaw frequency

1.Clamps ensure straight connection pts. 2.Optics table helps stiffen the support structure

Data Collecting Equipment used: – Kaman eddy current displacement sensor – LabVIEW data logging system

Data Analysis Data analysis method and computer program by Mark Barton

Results Model predictions by Julian Freed-Brown, based on equations by Calum Torrie. frequency measuredpredicted measuredpredicted n=1 cm plate n=3 cm plate n=5 cm plates n=7 cm plates n=9 cm plates Yaw mode Pitch mode

Results pitch mode n = 5 cm without cabling with cabling frequencyQ QQ^0.5 0 plate plate plates plates plates

Results Future Work 1.Feed results into Julian’s Mathematica model 2.Check for agreement between the model and experiment frequency results. 3.Study the resulting transfer functions and make recommendations on cabling dressing.