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Nick Kaiser Pan-STARRS, Institute for Astronomy, U. Hawaii Following the Photons

Configuring the Pan-STARRS Optics - From Simulations to Operational Control System. Nick Kaiser Pan-STARRS, Institute for Astronomy, U. Hawaii Following the Photons Edinburgh, Oct 10, 2011. Pan-STARRS PS4 Observatory. Haleakala Observatories, Maui, HI. Introduction.

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Nick Kaiser Pan-STARRS, Institute for Astronomy, U. Hawaii Following the Photons

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  1. Configuring the Pan-STARRS Optics - From Simulations to Operational Control System Nick Kaiser Pan-STARRS, Institute for Astronomy, U. Hawaii Following the Photons Edinburgh, Oct 10, 2011

  2. Pan-STARRS PS4 Observatory

  3. Haleakala Observatories, Maui, HI

  4. Introduction • The Pan-STARRS telescope has to deliver sub-arc-second images over a 3-degree diameter field of view • It has 2 mirrors, 3 lenses (several highly aspheric surfaces) and a focal plane • alt-az design with L3 and the camera behind the instrument rotator • That gives 5x5 + 3 - 1= 27 degrees of freedom (tilts, decenters and despaces) • to be adjusted to get all of the elements collimated and aligned with the rotator axis • Required precision is ~tens of micron • In addition, the primary mirror support system has 12 independently controllable pneumatic axial supports • total of 39 d.o.f. to be controlled

  5. Pan-STARRS Opical Design

  6. Mirror Support Systems

  7. PS-1 Primary Mirror Support System

  8. How do we configure the PS optics? • Advice from experts… not encouraging • Too many parameters • What about “degeneracies”? • Won’t you get stuck in a local minimum? • Or crawl along a valley? • Discouraging lessons from megaprime… • Try to “divide and conquer”? • Problem: M1/M2 system alone does not deliver images even on axis • M1/M2 system has real-time control of all d.o.f • Approach adopted (evolved) • 1) Solve 8 d.o.f problem of M1, M2 relative to L1+L2 • L1+L2 assembled at UW on turntable quite accurately • 2) Then fix any tilt of detector plane • L3 (dewar window) is relatively weak • Rotator allows this to be determined separately from any tilt introduced by M1+M2+L1+L2 system

  9. Initial configuration: • Plan: use auto-reflecting telescope • Mounted on a jig on the back of the telescope • Aligned with rotator axis • Used to align other elements with targets (M2) and fiducial marks (lenses) • First light (07/2007) gave ~10” IQ • Adjusting mirrors iteratively gave ~2” IQ • Field curvature and field dependent astigmatism diagnosed • Attributed to L1, L2 de-space • But still IQ was not adequate • Exploring 8 parameter M1, M2 til + decenter parameter space infeasible • Needed a more methodical approach

  10. Aberration diagnosis techniques • Traditional wave-front sensing approaches: • Shack-Hartmann imaging • Implemented in PS GPC1 as deployable probe • Hartman mask imaging • Knife-edge test • Rotational beam-shearing interferometry • Claude Roddier thesis • Other probes • Ghost image analysis • Direct (e.g. laser) metrology • Analysis of in-focus images • Highly non-linear dependence on positional d.o.fs • Too hard to explore big parameter space • Technique adopted: • Use M2 de-space to generate out-of-focus (a.k.a. donut) images • Thousands of stars per exposure => huge amount of information • At large enough defocus shapes become linearly dependent on misconfiguration parameters (like weak-lensing)

  11. Wavefront Aberrations from Out-of-Focus Images • Perfectly collimated (and designed) telescope gives donut images when defocused that are • Uniformly bright • Circularly symmetric • annular because of hole in primary • At large-enough defocus these are well described by geometric optics (images formed by “rays”) • Any aberrations (displacement of elements or figure errors) deflect rays and cause distortion of the shape of the out-of-focus image • Crowding or dilution of the density of rays modulated brightness a la Roddier (1990) • Brightness proportional to curvature (Laplacian) of converging wave-front aberration. • Hence “curvature sensing” • Pioneered by Roddier group at IfA for Adaptive Optics

  12. Illustration of the effect of a localized aberration on out-of-focus images

  13. Advantages: Linearity and Multiplexing • Donut shape statistics are a linear response to causes of aberrations • Linearity breaks down too close to focus. • Shadowing and flat fielding etc. become problematic too far from focus. • `Sweet spot' seems to be around 3mm defocus • may be possible to go closer for more sensitivity • But may require `physical optics' modelling • Solve a set of linear equations to find mirror displacements and actuator commands to cancel aberration • No iteration (in principal) - one step solution • No local minima - finds unique global minumum • Massively multiplexed - thousands of stars per image

  14. Separating Seeing and Mirror Wobbling from Aberrations • We want to obtain sub-seeing aberrations. • But seeing causes wavefront errors of many radians of phase • Causes donuts to wobble around like jello. • Averages out in long exposures • But leads to smearing. • Worse still, mirror oscillations will produce persistent anisotropies • Fortunately, such affects can be readily distinguished by using both pre- and post-focus image pairs.

  15. Symmetries Between Pre- and Post-Focus Image Statistics 1) Focus aberration

  16. Symmetries Between Pre- and Post-Focus Image Statistics2) Comatic (cos phi) aberration

  17. Symmetries Between Pre- and Post-Focus Image Statistics 3) Astigmatic (cos 2 phi) aberration

  18. Symmetries and anti-symmetries • Even angular harmonic change sign passing through focus, while the odd harmonics do not • If we rotate the post focus images by 180 degrees the sign always changes • This is the characteristic of wave-front phase errors • But wavefront amplitude errors have opposite symmetry • Easily distinguished • Can construct combinations of pre- and post focus image statistics that are blind to effects of telescope wobble, obscurations etc.

  19. What about “degeneracies”? • `Degeneracy' here means combinations of displacements that do not cause any measurable aberration • Terminology is sloppy: Technically, `degeneracy' means non-distinct eigenvalues • Here all decenter/tilts are degenerate in the proper sense. • `Quasi-degeneracy' arises if there are combinations that produce almost zero measurable effect. • These cause the linear equation solution (inversion of matrix) to be singular or ill conditioned. • Example: An exact degeneracy arises because IQ only depends on relative positioning of optical elements • But is easy to deal with • Quasi-degeneracies are a little more tricky.

  20. Dealing with quasi-degeneracies • Example: decenters and/or tilts of M1 nearly degenerate with decenter of M2 • Similar degeneracies for L3/focal-plane system • But quasi-degeneracies are not to be feared; they are our friends • Can be identified using elementary linear algebraic techniques • They allow one to correct for one misalignment that is difficult to cure by moving another element or combination of elements that are easier • Fundamental to Pan-STARRS design • real-time control over the configuration of the mirrors • but not of the other elements -- which will surely flex/expand etc

  21. Donut finding/analysis pipeline • The goal is to obtain, from an out of focus gigapixel camera image, a grid of donuts covering the focal plane. • Step 1: Determine the size of the donuts • Generate cleaned log-scaled image • Compute the autocorrelation function • Cross-correlate with theoretical model in log(r) space • Step 2: Determine location of the donuts • Generate an analytic model for the 2-D donut image. • Construct a regularized deconvolution filter • Apply to image to obtain the locations of candidate donuts • Filter candidates catalog to obtain tens of good donuts per OTA • Step 3: Generate robust (median) average • Candidates include some overlaps, cell boundaries etc. • Take median to get clean donut image • Result is a grid of 60 donuts per focal plane

  22. Log-scaled image

  23. Donut model and regularised deconvolution filter

  24. Deconvolved OTA Image

  25. Donut locations - one OTA

  26. Donuts sample - 1 OTA

  27. Median donuts grid - full field - one per OTA

  28. Donut shape statistics • We need to quantify the distortion of donuts and how this varies across the field. • What is a good set of statistics? • It is traditional to use Zernike polynomials • see Knoll, JOSA 66, p207 • We use something similar: angular Fourier expansion of radius, width and brightness of donuts • We first compute the centroid of the light in a postage stamp containing the donut • From the pixel locations, relative to the centroid, we define a radius r and azimuthal angle • Compute moments of donut radius, width and brightness • Typically cos 2, cos 3, cos 4 theta modes • Exploit symmetries in pre- and post-focus images to generate combined statistic that is independent of actual focus • Results in ~100 statistics for each of ~60 donuts across the focal plane.

  29. M1, M2 tilts and decenters

  30. M1, M2 strongest eigenmodes

  31. Donuts - observed vs model

  32. PS1 Residual Aberration Analysis

  33. PS1 Residual Aberration Analysis

  34. PS1 Residual Aberration Analysis

  35. PS1 Residual Aberration Analysis

  36. PS1 Residual Aberration Analysis

  37. PS1 Residual Aberration Analysis

  38. PS1 IQ – Smallest Image Median FWHM to Date NK FWHM = 0.69", JT FWHM = 0.63 q = measure of circularity of 2D PSF 39 UNIVERSITY OF HAWAII INSTITUTE FOR ASTRONOMY Project Proprietary Data – For Internal Use Only

  39. PS1 y-band – first 1 micron image of the sky

  40. PS1 z, i, r, g band coverage 2011-02-14

  41. PS1 3pi survey – 15 to 20 images in five bands,building astrometric catalog for re-processing

  42. PS1+2

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