1 / 25

ST7 Concept

The ST7 Interferometer Andreas Kuhnert Robert Spero Jet Propulsion Laboratory California Institute of Technology. ST7 Concept. Measure suspended masses within spacecraft Test thruster performance in drag-free control Hitch ride on LISA Pathfinder. x 1. x 2. Optical bench. TM1. TM2.

Download Presentation

ST7 Concept

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. The ST7 InterferometerAndreas KuhnertRobert SperoJet Propulsion LaboratoryCalifornia Institute of Technology

  2. ST7 Concept • Measure suspended masses within spacecraft • Test thruster performance in drag-free control • Hitch ride on LISA Pathfinder x1 x2 Optical bench TM1 TM2 • Interferometer optical bench fixed to spacecraft • x1 and x2 measured separately; x1 + x2 is low-noise

  3. Optical Bench 20 cm Intensity Monitor Beam-splitter TM1 TM2 Quadrant photodiode Sensitive path Collimator Insensitive path Optical Fiber

  4. Interferometer Features Beam diameter 1 mm, Rayleigh range 70 cm, sensitive path lengths 10 cm. No modulators, phasemeters, intensity stabilization, or frequency stabilization. Requires test mass to be positioned near mid-fringe. Intensity monitored, noise removed in data analysis. Separate measurements of both bench/test-mass distances. Quadrant photodiodes monitor total fringe signal, and two axes of alignment. Automatic alignment, autonomous operation.

  5. Homodyne Signal Optical Bench Thermal Expansion l/2 A B A B Manual Alignment

  6. Contacted Optics in Vacuum Chamber

  7. Testbed Drift

  8. Testbed Noise 60 pm rms optical bench modulation 1000 Allocated noise 100 pm/rtHz 10 Measured noise 1 100 1 mHz

  9. Measurements Demonstrate: Analog electronics and ADC noise adequately low Thermal sensitivity probably adequately low Bench motion suppression typically x200, without calibration (x1000 needed) Frequency stabilization not needed Intensity noise can be suppressed in data analysis

  10. Alignment Sensitivity 1:Geometric error Dq Dq q0 s1 xc= p cosq xS= s1 sin q p Dxc= pq0Dq DxS= s1 Dq s1 = 40 m; p = 10 cm; q0 = 400 mrad Errors are correlated, and of same order: s1 ~ pq0

  11. Alignment Sensitivity 2:Fringe position error Dq q0 p + x Dxx= ax q0Dq, a = (pw/l)2 =2.2x106, w=beam radius

  12. Total angle-jitter noise Fringe center error, 30 nm Misalignment, 400 mrad Transverse error, 40 mm Test mass jitter, 1 mrad/rthz Displacement noise, 30 pm/rthz

  13. Initialization 1. Starting state 2. IFO finds bright fringe 4. IFO Aligns 3. GRS moves to quarter fringe 5. GRS to half fringe Position Intensity

  14. Dithered alignment -- concept

  15. Dithered alignment -- Simulink model

  16. Dithered alignment -- Simulink run

  17. Bright fringe finder -- Simulink model

  18. Bright fringe finder -- Simulink run

  19. QPD difference alignment -- Simulink model

  20. QPD difference alignment -- Experiment

  21. QPD difference signal alignment sensitivity

  22. Sum vs. difference signals at half-fringe

  23. Backups

  24. Intensity Pattern with Misalignment • Horizontal misalignment shown. • Pattern insensitive to fringe offset near mid-fringe. • Sample with 4 pixels (quadrant photodiode). Difference/sum response: dQ/dq = sqrt(8kw/p3)

  25. Static Misalignment and Static Longitudinal Error Fringe Visibility Error Sensitivity 1 w=0.5 mm w=1.0 mm Alignment noise w=2.0 mm Electronic noise 0 Misalignment (mrad) Bright Mid Dark

More Related