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Allen Telescope Array

Allen Telescope Array. Harvard-Smithsonian April 3, 2001. Jill Tarter Director, SETI Research Bernard M. Oliver Chair SETI Institute. Allen Telescope Array. SETI 2020. Dedicated telescope for microwave SETI with 10 4 m 2 collecting area – One Hectare Telescope (1hT) Optical SETI

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Allen Telescope Array

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  1. Allen Telescope Array Harvard-Smithsonian April 3, 2001 Jill Tarter Director, SETI Research Bernard M. Oliver Chair SETI Institute

  2. Allen Telescope Array SETI 2020 • Dedicated telescope for microwave SETI with 104 m2 collecting area – One Hectare Telescope (1hT) • Optical SETI • Omni-directional Sky Survey Telescope

  3. The Allen Telescope Array (ATA) • Large, massively parallel array of “TV” dishes • 350 elements each 6.1 m in diameter • total collecting area larger than 100 m dish • 0.5 - 11 GHz simultaneously • multiple beams • Must be much cheaper than existing arrays • Joint project of SETI Institute and UCB • Private $ from Allen, Myhrvold, stakeholders, and others

  4. 25m 6m Economies Of Cheap Electonics

  5. The ATA at Hat Creek

  6. Steer the nullbeam 5 times Size of Full moon It’s Not Just Cheaper, It’s Better! • Exploits Large Primary FOV • Enables Simultaneous SETI and RA • Satellite Nulling

  7. The Design

  8. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  9. 6m Offset Gregorian Antenna 6m x 7m primary Shroud Log-periodic Feed with Actuator 2.4m secondary

  10. Selected Mount with 4.2m Anderson Dish

  11. Mount and Antenna Az-El Mount

  12. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  13. 15 cm 45 cm Ultrawideband Log Periodic Feed Dual polarization Cryogenic front end inside shield Fed at and radiates toward tip

  14. Prototype Feed for Tests

  15. Feed Tests • Excellent (20 dB) match • Agrees with EM calcs on • Impedance • Gain • Internal Loss • Range Tested (preliminary) • Optimizing with ridge

  16. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  17. Prototype InP MMIC LNA MMIC In-P PHEMT 0.18 microns Weinreb Model Tin ~ 10 K First try works fine Tin ~ 20 K

  18. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  19. 80 K Cryogenics • Must be • Small (to fit inside shield) • Reliable (> 10 yr MTBF) • Cheap (< few K$) • In-house solution • Clearance seal compressor with voice coil motor • “vacuum tube” style dewar with getter • Pulse tube cooler (no moving parts) NIST • Commercial solution also possible

  20. Cryogenics Inside Feed Electronics Package Dewer with LNA Inside Compressor Focus Drive

  21. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  22. 0.5-11 GHz Analog F/O Links • Off the shelf units too expensivenow • Reduced component costs soon due to recent massive investments by industry • Laser progress “Real Soon Now” • Cheaper DFB, e.g. Ortel “Daytona” • 1310 nm VCSEL (Gore, Novalux, Cielo, Agilent, Infineon) • External modulators as fallback

  23. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  24. Micro Photograph of Mixer Test Version

  25. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  26. Signal Processing • Up/down converter • DSP architecture in preliminary design • Cross correlator (imager) with BW set by $$ • Backends for synthesized beams • SETI • Pulsars • Spectral line • RFI mitigation and removal designed in

  27. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  28. RPA - Rapid Prototyping Array Russell Reservation in Lafayette CA

  29. Rapid Prototype Array (RPA) John Dreher • RFI Mitigation Experiments • Calibration with GPS • Software Development Lafayette, California

  30. Antenna Gain Calibration

  31. Antenna Gain

  32. Inexpensive parabolic dishes Decade bandwidth feed Low noise amplifiers based on InP Commodity priced 80K cryogenics Wideband fiber optic links MMICs Cheap DSP/computing GPS for calibration Distributed control systems Enabling Technologies

  33. Software Technology • OO design • C++ • Java • Use standard tools and products (where possible) • Distributed, multiplatform design (where appropriate)

  34. Selected Configuration for ATA Nearly circular beam 76 arcsec Near-in sidelobes peak at 1% Far-out sidelobes ~ 1/N

  35. Timeline for ATA 1999-2000 • R&D Phase • Rapid Prototype Array of 7 antennas built • calibration, beam forming, RFI excision, telescope control • Selected site, began approval processes • PDRs : most done • Design staffing complete

  36. Timeline for ATA 2001-2002 • CDR • Build Production Test Array • Operational tests begin • Develop tools

  37. Timeline for ATA 2003-2004 • Begin construction • First use of partial array • Array complete - extensions begin • Feed into SKA technology decision point 2005

  38. Stay tuned!www.seti.org “The probability of success is difficult to estimate; but if we never search the chance of success is zero.” Cocconi and Morrison, Nature (1959) I Do Not Know When, Or If SETI Will SucceedBut The Cyclops Report Convinced Me That Cocconi and Morrison Were Right …

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