PALM-3000 Status of the PALM-3000 high-order adaptive optics system A.H. Bouchez, R.G. Dekany, J.R. Angione, C. Baranec, K. Bui, R.S. Burruss, J.R. Crepp, E.E. Croner, J.L. Cromer, S.R. Guiwits, D.D.S. Hale, J.R. Henning, D. Palmer, J.E. Roberts, M. Troy, T.N. Truong, J. Zolkower SPIE Optics and Photonics, San Diego 8/3/2009
PALM-3000 Talk Outline Science Case –Performance predictions –Project 1640 coronagraphic IFS Subsystems –Optical Relay Design –Deformable Mirror Testing –High Order Wavefront Sensor Assembly –Wavefront Processor Computer Design Future plans
PALM-3000 The PALM-3000 upgrade The Palomar AO system 241 actuators, 16x16 sampling, 2 kHz max frame rate Typical perf.: 190 nm RMS WFE Instruments: –PHARO nIR imager & spectrometer –Project 1640 nIR coronagraphic IFS –SWIFT visible IFS –Visitor instruments The PALM-3000 upgrade 3388 active actuator deformable mirror Wavefront sensor with up to 63x63 pupil sampling Wavefront reconstructor computer to run at up to 2 kHz Expected performance: –90 nm RMS WFE in median conditions (r 0 =9.2 cm) –79 nm RMS WFE in 75th percentile conditions (r 0 =11.0 cm) Palomar AO & SWIFT installed on the 5.1m Hale telescope
PALM Science Drivers Galactic –Hot, young exo-Jupiter studies –Faint debris disks –Mass/luminosity of pre-main sequence binaries Require high contrast in the near-infrared Solar system –Io surface geology –Multiplicity of TNOs and asteroids –Surface minerology of large asteroids Require high Strehl in the visible PALM-3000 will deliver >50% Strehl in V band! 2.5” Brown et al., ApJ 639, 2006 Oppenheimer et al., AJ 679, 2008 Marois et al., Science 322, 2008
PALM The Project 1640 Instrument PI: Ben Oppenheimer, American Museum of Natural History Apodized Lyot coronagraph with a low-resolution ( / =30) J-H band integral field spectrograph back-end. Post-coronagraphic calibration wavefront sensor being developed by JPL. Expected flux ratio reached at 1.0” radius from bright stars (3 in 1 hr): –PALMAO8 x –P3K5 x –P3K + JPL Cal2 x Raw spectra of a broadband calibration source Project 1640 in the lab at AMNH
PALM-3000 Project 1640 early results Recently discovered companion, contrast ~10 -3 (Oppenheimer et al, in prep.)
PALM-3000 Optical Relay Reuses existing bench, off-axis parabolas, steering mirrors, tip/tilt mirror, science dichroics, DM (DM241). Retain current science focus position New HOWFS, high-order DM (DM3388), Acquisition Camera and Stimulus Passes 120” Ø field DM3388 located at pupil, 10.5° AOI DM241 located at +742 m conjugate, 16.0 ° AOI Requires 4 fold mirrors (meets 50% transmission requirement, incl. telescope) Acquisition camera rides on HOWFS focus stage DM3388 DM241 OAP1 TTM FM3 FM4 FM1 FM2 OAP2 SSM1 SSM2 HOWFS & ACam Science Instrument Volume
PALM-3000 Optical Relay Performance Corner of PHARO (20”, 20”) Corner of P1640 (2”, 2”) M1 aberration (2 µm P-V astigmatism)14 mas1.4 mas Atmosphere (median conditions, 2 ) 21 mas2.1 mas TT anisoplanatism20 mas2 mas Optical Performance On-axis aberrations corrected by DMs (astigmatism from dichroic, alignment errors) Field aberrations 30” off axis are ~32 nm RMS Woofer DM at non-pupil conjugate leads to focal plane distortion, on same scale as tip/tilt anisoplanatism Mechanical Tolerances <5 mas image drift over 300s in the focal plane Image shift induced by applying corrections for these errors at +742 m conjugate J band spot diagrams at science focus, using DMs to correct on-axis aberrations <5% misregistration of finest subaperture in 300s in pupil plane Requires both careful mechanical design and active, open-loop compensation
PALM-3000 High-Order Deformable Mirror Xinetics photonics module PMN World’s highest actuator count deformable mirror –66 x 66 = 4356 actuators on 1.8 mm pitch –We control 3388 on 112 mm Manufacturing completed in June 2009 –1.8 µm stroke measured –Restricted to 1.4 µm by HV supplies –9% stroke uniformity Currently undergoing final acceptance testing 66x66 actuator mirror before face sheet bonding
PALM-3000 Deformable Mirror Testing All actuators are functional Influence functions are ~1 actuator spacing FWHM Unpowered surface figure 150 nm RMS, significantly worse than expected but meets science requirements Zygo map of mirror surface, with ~100 nm surface actuation.
PALM-3000 DM Electronics and Cabling Implementation issues Driver electronics dissipate ~4 kW; must be mounted on telescope due to cable volume Cables require redesign to meet observatory operational requirements
PALM-3000 High Order Wavefront Sensor Shack-Hartmann design with selectable 8, 16, 32 or 63 samples across the pupil CCD50 detector (128x128 pixels) in SciMeasure Lil’ Joe camera Uses a tilted spherical collimator and cylindrical lens to match mircrolenses to DM3388 actuators at 10.5º AOI See Baranec, Proc. SPIE 7015, 2008.
PALM-3000 HOWFS microlens arrays Images of the microlens arrays in the assembled HOWFS arrays taken with a CMOS alignment camera.
PALM-3000 HOWFS alignment Spot patterns recorded with the CCD50 camera Preliminary alignment:
PALM-3000 HOWFS Subaperture Alignment 63 6332 3216 168 8 In the 63x63 subaperture mode, the pupil will be shifted with respect to the detector to preserve Fried geometry. In the other modes, we will use use modal control.
PALM-3000 Wavefront Processor Computer Perform full matrix multiplication reconstruction! Parallelize, and use off-the-shelf Graphics Processor Units for computation House GPUs in a remote cluster of low-cost desktop PCs (in observatory computer room) Implementation VMM calculations performed on 16 Nvidia GPUs in 8 PCs –Advantages: Low cost, simple software implementation, rapid upgrade cycle PC 0 provides the interface, scheduling, and control of the cluster PC 9 is dedicated to telemetry recording (1 Tb RAID, Berkeley DB) Communication provided by a Quadrics switch (latency measured to be 19 µs) All running Real-Time Linux Publish/subscribe environment Strategy Despite reconstruction problem being 250 times larger than for present-day systems… 8192 slopes x 3631 actuators, vs. 512 slopes x 243 actuators
PALM-3000 Servo Control Architecture Flexible control system Modes: 1.Control DM3388 & TTM, offload to DM241 2.Split modes btw. DM3388 & DM241, offload to TTM 3.Fixed DM241 (good seeing only) 4.Calibration WFS input to centroid offsets & DM3388 positions
PALM-3000 Future Plans PALM-3000 Testbed Demonstrate performance of all new components before taking Palomar AO system offline – Includes all PALM-3000 components except DM241, final optics (eg. off-axis parabolas, stimulus), and steering mirror mounts – Low-cost monochromatic source and refractive optics Beginning integration of testbed in August 2009 Goal is to demonstrate closed-loop operation at 2 kHz by February 2010 Future Milestones Project 1640 Cal WFS integrated with Palomar AO Dec PALM-3000 pre-ship review planned for June 2010 First light in February 2011