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The Laser Guide Star Adaptive Optics (LGS AO) at the W.M. Keck Observatory is the first system of its kind being used to conduct routine science on a ten-meter telescope. In 2005, more than fifty nights of LGSAO science and engineering were carried out using the NIRC2 and OSIRIS science instruments. In this paper, we report on the typical performance and operations of its LGS AO-specific sub-systems (laser, tip-tilt sensor, low-bandwidth wavefront sensor) as well as the overall scientific performance and observing efficiency. We conclude the paper by describing our main performance limitations and present possible developments to overcome them.
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We present first results from the Multi-Conjugate and Multi-Object Adaptive Optics (MCAO and MOAO) testbed, at the UCO/Lick Laboratory for Adaptive Optics (LAO) facility at U.C. Santa Cruz. This testbed is constructed to simulate a 30-m telescope executing MCAO and/or open loop MOAO atmospheric compensation and imaging over 5 arcminutes. It is capable of performing Shack-Hartmann wavefront sensing on up to 8 natural or laser guide stars and 2-3 additional tip/tilt stars. In this paper, we demonstrate improved on-axis correction relative to ground layer adaptive optics (~ 15% Strehl relative to ~ 12%) with a simulated 28-m aperture at a D/r0 corresponding to a science wavelength of 2.6 microns using three laser guide stars on a simulated 41 arcsec radius with a central science object and one deformable mirror at the ground layer.
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Experiments have been carried out at the MMT telescope in June 2005 and again in April 2006 to validate open loop tomographic wavefront reconstruction using five dynamically refocused Rayleigh laser beacons (RLGS) and multiple tilt natural guide stars (NGS). Wavefront sensing in this manner is recognized as a critical precursor to the development of adaptive optics for Extremely Large Telescopes. At the MMT, wavefronts from the laser beacons are recorded by five 60-element Shack-Hartmann sensors implemented on a single CCD. A wide-field camera measures image motion from multiple field stars to calculate global tilt and distinguish effects of contributions to second order aberrations from low and high altitude turbulence. Together, the signals from these sensors are used to estimate the first 45 Zernike modes in the wavefront of a star within the LGS constellation. The reconstruction is compared off line to simultaneous wavefront measurements made of the star with a separate Shack-Hartmann sensor. We will present the results in this paper and quantify the wavefront improvement expected from tomographic adaptive optics correction.
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After the successful demonstration of the solar multi-conjugate adaptive optics (MCAO) system at the German 70cm Vacuum Tower Telescope (VTT), Observatorio del Teide, Tenerife, in the last years, we are continuing the development of the system as a testbed for the future MCAO of the 150cm GREGOR solar telescope. We describe an improved reconstruction scheme that increases the number of
corrected off-axis degrees of freedom and will be tested at the VTT
in September 2006. We present a modified optical setup of the GREGOR MCAO that has the advantage of being adjustable to a wide height range of the turbulence.
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We have implemented a MCAO experiment at the Dunn Solar Telescope. The MCAO system uses 2 deformable mirrors, one conjugated to the telescope entrance pupil and other one conjugated to a layer in the upper atmosphere. For our initial experiments we have used a staged approach in which the 97 actuator, 76 subaperture correlating Shack-Hartmann solar adaptive optics system normally operated at the DST is followed by the second DM and the tomographic wavefront sensor, which used three "solar guide stars". We have successfully and stably locked the MCAO system on solar structure. We varied the height of the upper conjugate between 3km and 9 km. A large number of images were recorded in order to evaluate the performance of the system. The data analysis is still ongoing. We present preliminary results and discuss future plans.
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Laser Guide Star and Multi-Conjugate AO Field Tests II
Two teams of scientists and engineers at Max Planck Institut fuer Extraterrestrische Physik and at the European Southern Observatory have joined forces to design, build and install the Laser Guide Star Facility for the VLT.
The Laser Guide Star Facility has now been completed and installed on the VLT Yepun telescope at Cerro Paranal. In this paper we report on the first light and first results from the Commissioning of the LGSF.
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The purpose of this paper is to report on new adaptive optics (AO) developments at the W. M. Keck Observatory since the 2004 SPIE meeting.1 These developments include commissioning of the Keck II laser guide star (LGS) facility, development of new wavefront controllers and sensors, design of the Keck I LGS facility and studies in support of a next generation Keck AO system.
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The paper is describing the present status of the LBT first light AO system. The system design started in January 2002 and is now approaching the final test in the Arcetri solar tower. Two key features of this single conjugate AO system are the use of an adaptive secondary mirror having 672 actuators and a pyramid wavefront sensor with a maximum sampling of 30x30 subapertures. The paper is reporting about the adaptive secondary mechanical electrical and optical integration, and the wavefront sensor unit integration and acceptance test. Finally some lab test of the AO system done using an adaptive secondary prototype with 45 actuators, the so called P45 are described. The aim of these test was to get an estimate of the system limiting magnitude and to demonstrate the feasibility of a new technique able to measure AO system interaction matrix in a shortest time and with higher SNR with respect to the classical interaction matrix measurement. We are planning to use such a technique to calibrate the AO system in Arcetri and later at the LBT telescope.
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The Adaptive Optics Facility is a project to convert one VLT-UT into a specialized Adaptive Telescope. The present
secondary mirror (M2) will be replaced by a new M2-Unit hosting a 1170 actuators deformable mirror. The 3 focal
stations will be equipped with instruments adapted to the new capability of this UT. Two instruments are in
development for the 2 Nasmyth foci: Hawk-I with its AO module GRAAL allowing a Ground Layer Adaptive Optics
correction and MUSE with GALACSI for GLAO correction and Laser Tomography Adaptive Optics correction. A
future instrument still needs to be defined for the Cassegrain focus. Several guide stars are required for the type of
adaptive corrections needed and a four Laser Guide Star facility (4LGSF) is being developed in the scope of the AO
Facility. Convex mirrors like the VLT M2 represent a major challenge for testing and a substantial effort is dedicated to
this. ASSIST, is a test bench that will allow testing of the Deformable Secondary Mirror and both instruments with
simulated turbulence. This article describes the Adaptive Optics facility systems composing associated with it.
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The laser guide star adaptive optics (AO188) system for Subaru Telescope is presented. The system will be installed at the IR Nasmyth platform of Subaru 8 m telescope, whereas the current AO system with 36 elements is operating at the Cassegrain focus. The new AO system has a 188 element wavefront curvature sensor with photon counting APD modules and 188 element bimorph mirror. The laser guide star system has a 4.5 W solid state sum-frequency laser on the Nasmyth platform. The laser launching telescope with 50 cm aperture will be installed at behind the secondary mirror. The laser beam will be transferred to the laser launching telescope using photonic crystal single mode fiber cable. The instrument with the AO system is IRCS, infrared camera and spectrograph which has been used for Cassegrain AO system and new instrument, HiCIAO, high dynamic range infrared camera for exsolar planet detection. The first light of the AO system is planned in 2006.
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In this paper, we provide an overview of the adaptive optics (AO) program for the Thirty Meter Telescope (TMT) project, including an update on requirements; the philosophical approach to developing an overall AO system architecture; the recently completed conceptual designs for facility and instrument AO systems; anticipated first light capabilities and upgrade options; and the hardware, software, and controls interfaces with the remainder of the observatory. Supporting work in AO component development, lab and field tests, and simulation and analysis is also discussed. Further detail on all of these subjects may be found in additional papers in this conference.
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The Giant Magellan Telescope (GMT) includes adaptive optics (AO) as an integral component of its design. Planned
scientific applications of AO span an enormous parameter space: wavelengths from 1 to 25 μm, fields of view from 1
arcsec to 8 arcmin, and contrast ratio as high as 109. The integrated systems are designed about common core elements.
The telescope's Gregorian adaptive secondary mirror, with seven segments matched to the primary mirror segments, will
be used for wavefront correction in all AO modes, providing for high throughput and very low background in the
thermal infrared. First light with AO will use wavefront reconstruction from a constellation of six continuous-wave
sodium laser guide stars to provide ground-layer correction over 8 arcmin and diffraction-limited correction of small
fields. Natural guide stars will be used for classical AO and high contrast imaging. The AO system is configured to feed
both the initial instrument suite and ports for future expansion.
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PALM-3000 is proposed to be the first visible-light sodium laser guide star astronomical adaptive optics system. Deployed as a multi-user shared facility on the 5.1 meter Hale Telescope at Palomar Mountain, this state-of-the-art upgrade to the successful Palomar Adaptive Optics System will have the unique capability to open the visible light spectrum to diffraction-limited scientific access from the ground, providing angular imaging resolution as fine as 16 milliarcsec with modest sky coverage fraction.
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Astronomical Results and Performance Characterization
We briefly discuss the past, present, and future state of astronomical science with laser guide star adaptive optics (LGS AO). We present a tabulation of refereed science papers from LGS AO, amounting to a total of 23 publications as of May 2006. The first decade of LGS AO science (1995-2004) was marked by modest science productivity (≈1 paper/year), as LGS systems were being implemented and commissioned. The last two years have seen explosive science growth (≈1 paper/month), largely due to the new LGS system on the Keck II 10-meter telescope, and point to an exciting new era for high angular resolution science. To illustrate the achievable on-sky performance, we present an extensive collection of Keck LGS performance measurements from the first year of our brown dwarf near-IR imaging survey. We summarize the current strengths and weaknesses of LGS compared to Hubble Space Telescope, offer a list of desired improvements, and look forward to a bright future for LGS given its wide-scale implementation on large ground-based telescopes.
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We present astronomical results from K-band adaptive optics (AO) observations of the wide binary system σ Corona Borealis with the Lick Observatory natural guide star adaptive optics system on 2004 August 27-29. Seeing conditions were excellent and the AO compensation was very good, with Strehl ratios reaching 50% at times. The stellar images were reduced using three different analysis techniques: (1) Parametric Blind Deconvolution, (2) Multi-Frame Blind Deconvolution, and (3) the MATPHOT stellar photometry code. The relative photometric and astrometric precision achievable with these three analysis methods are compared. Future directions that this research can go towards achieving the goal of routinely obtaining precise and accurate photometry and astrometry based on near-infrared AO observations are described.
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We have investigated both the temporal and spatial structure of the point spread function (PSF) produced by the Lick
Observatory adaptive optics (AO) system using the FastSub readout mode of the IRCAL camera using short-exposure
images with exposure times of 22ms at a frame rate of ~ 20Hz suitable for "freezing" the compensation under typical K-band
observing conditions. These short exposures are a useful diagnostic tool for determining the system performance
and permit measurement of the instantaneous Strehl ratio. Data taken from a number of observing runs, spanning over
four months, show the underlying morphology of the PSF to be very stable with instantaneous Strehl ratios varying from
~ 20%-70% in NGS mode. Estimates of the instantaneous Strehl distribution have also been obtained from which we
have determined the probability density function for the distribution of the instantaneous Strehl ratios.
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The SPHERE system aims at the detection of extremely faint sources (giant extra-solar planet) in the vinicity of bright stars. Such a challenging goal automatically requires the use of a coronagraphic device to cancel out the flux coming from the star and smart imaging technics which have to be added to reach the required contrast for exo-planet detection (typically 10-6 - 10-7 in contrast). In this frame of the SPHERE project a global system study has demonstrated the feasibility of an AO system for the direct exoplanets detection. A detailed description of this system is proposed in this paper. The main trade-offs are discussed and justified and all the subsystems briefly presented. The realization phase has begun in 2006 and we foresee to obtain a first light at the VLT in 2010.
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The next major frontier in the study of extrasolar planets is direct imaging detection of the planets themselves. With high-order adaptive optics, careful system design, and advanced coronagraphy, it is possible for an AO system on a 8-m class telescope to achieve contrast levels of 10-7 to 10-8, sufficient to detect warm self-luminous Jovian planets in the solar neighborhood. Such direct detection is sensitive to planets inaccessible to current radial-velocity surveys and allows spectral characterization of the planets, shedding light on planet formation and the structure of other solar systems. We have begun the construction of such a system for the Gemini Observatory. Dubbed the Gemini Planet Imager (GPI), this instrument should be deployed in 2010 on the Gemini South telescope. It combines a 2000-actuator MEMS-based AO system, an apodized-pupil Lyot coronagraph, a precision infrared interferometer for real-time wavefront calibration at the nanometer level, and a infrared integral field spectrograph for detection and characterization of the target planets. GPI will be able to achieve Strehl ratios > 0.9 at 1.65 microns and to observe a broad sample of science targets with I band magnitudes less than 8. In addition to planet detection, GPI will also be capable of polarimetric imaging of circumstellar dust disks, studies of evolved stars, and high-Strehl imaging spectroscopy of bright targets. We present here an overview of the GPI instrument design, an error budget highlighting key technological challenges, and models of the system performance.
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The Exo-Planets Imaging Camera and Spectrograph (EPICS), is the Planet Finder Instrument concept for the European
Extremely Large Telescope (ELT). The study made in the frame of the OWL 100-m telescope concept is being up-dated
in direct relation with the re-baselining activities of the European Extremely Large Telescope.
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Direct detection of extrasolar Jovian planets is a major scientific motivation for the construction of future extremely
large telescopes such as the Thirty Meter Telescope (TMT). Such detection will require dedicated high-contrast AO
systems. Since the properties of Jovian planets and their parent stars vary enormously between different populations, the
instrument must be designed to meet specific scientific needs rather than a simple metric such as maximum Strehl ratio.
We present a design for such an instrument, the Planet Formation Imager (PFI) for TMT. It has four key science
missions. The first is the study of newly-formed planets on 5-10 AU scales in regions such as Taurus and Ophiucus -
this requires very small inner working distances that are only possible with a 30m or larger telescope. The second is a
robust census of extrasolar giant planets orbiting mature nearby stars. The third is detailed spectral characterization of
the brightest extrasolar planets. The final targets are circumstellar dust disks, including Zodiacal light analogs in the
inner parts of other solar systems. To achieve these, PFI combines advanced wavefront sensors, high-order MEMS
deformable mirrors, a coronagraph optimized for a finely- segmented primary mirror, and an integral field spectrograph.
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The Multi-Conjugate Adaptive Optics Demonstrator (MAD) built by ESO with the contribution of two external consortia is a powerful test bench for proving the feasibility of Ground Layer (GLAO) and Multi-Conjugate Adaptive Optics (MCAO) techniques both in the laboratory and on the sky. The MAD module will be installed at one of the VLT unit telescope in Paranal observatory to perform on-sky observations. MAD is based on a two deformable mirrors correction system and on two multi-reference wavefront sensors (Star Oriented and Layer Oriented) capable to observe simultaneously some pre-selected configurations of Natural Guide Stars. MAD is expected to correct up to 2 arcmin field of view in K band. MAD is completing the test phase in the Star Oriented mode based on Shack-Hartmann wavefront sensing. The GLAO and MCAO loops have been successfully closed on simulated atmosphere after a long phase of careful system characterization and calibration. In this paper we present the results obtained in laboratory for GLAO and MCAO corrections testing with bright guide star flux in Star Oriented mode paying also attention to the aspects involving the calibration of such a system. A short overview of the MAD system is also given.
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Although many of the instruments planned for the TMT (Thirty Meter Telescope) have their own closely-coupled adaptive
optics systems, TMT will also have a facility Adaptive Optics (AO) system, NFIRAOS, feeding three instruments
on the Nasmyth platform. This Narrow-Field Infrared Adaptive Optics System, employs conventional deformable mirrors
with large diameters of about 300 mm. The requirements for NFIRAOS include 1.0-2.5 microns wavelength range,
30 arcsecond diameter science field of view (FOV), excellent sky coverage, and diffraction-limited atmospheric turbulence
compensation (specified at 133 nm RMS including residual telescope and science instrument errors.) The reference
design for NFIRAOS includes six sodium laser guide stars over a 70 arcsecond FOV, and multiple infrared tip/tilt sensors
and a natural guide star focus sensor within instruments. Larger telescopes require greater deformable mirror (DM)
stroke. Although initially NFIRAOS will correct a 10 arcsecond science field, it uses two deformable mirrors in series,
partly to provide sufficient stroke for atmospheric correction over the 30 m telescope aperture, but mainly to improve
sky coverage by sharpening near-IR natural guide stars over a 2 arcminute diameter "technical" field. The planned upgrade
to full performance includes replacing the ground-conjugated DM with a higher actuator density, and using a deformable
telescope secondary mirror as a "woofer." NFIRAOS feeds three live instruments: a near-Infrared integral field
Imaging spectrograph, a near-infrared echelle spectrograph, and after upgrading NFIRAOS to full multi-conjugation, a
wide field (30 arcsecond) infrared camera.
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The Thirty Meter Telescope (TMT), the next generation giant segmented mirror telescope, will have unprecedented
astronomical science capability. Since science productivity is greatly enhanced through the use of adaptive optics, the
TMT science team has decided that adaptive optics should be implanted on all the IR instruments. We present the
results of a feasibility study for the adaptive optics systems on the infrared multi-object spectrograph, IRMOS and
report on the design concepts and architectural options. The IRMOS instrument is intended to produce integral field
spectra of up to 20 objects distributed over a 5 arcminute field of regard. The IRMOS adaptive optics design is unique
in that it will use multiple laser guidestars to reconstruct the atmospheric volume tomographically, then apply AO
correction for each science direction independently. Such a scheme is made technically feasible and cost effective
through the use of micro-electromechanical system (MEMS) deformable mirrors.
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We present a design of a thermal-infrared optimized adaptive optics system for the TMT 30-meter telescope. The
approach makes use of an adaptive secondary but during an initial implementation contains a more conventional
ambient-temperature optical relay and deformable mirror. The conventional optical relay is used without sacrificing the
thermal background by using multiple off-axis laser guide stars to avoid a warm dichroic in the common path. Three
laser guide stars, equally spaced 75" off axis, and a "conventional" 30×30 deformable mirror provide a Strehl > 0.9 at
wavelengths longer than 10 microns and the LGS beams can be passed to the LGS wavefront sensors with pickoff
mirrors while a one-arcminute field is passed unvignetted to the science instrument and NGS WFSs. The overall design
is relatively simple with a wavefront correction similar to existing high-order systems (e.g. 30×30) but still provides
competitive performance over the higher-order TMT NIR AO design at wavelengths as short as 3 microns due to its
reduced thermal emissivity. We present our figures of merit and design considerations within the context of the science
drivers for high-spectral resolution NIR/MIR spectroscopy at 5-28 microns on a 30-meter ground-based telescope.
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ONIRICA, standing for OWL Near InfraRed Imaging Camera, is a pre-Phase A, conceptual design study to assess the feasibility of an imaging camera for a 100m class telescope. In this paper the main scientific driven and the adopted preliminary choices for its optomechanical implementation are reviewed.
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We describe the manufacture of thin shells for the deformable secondary mirrors of the LBT adaptive optics system. The secondary mirrors are thin shells, 910 mm in diameter and 1.6 mm thick. Each mirror will have its shape controlled by 672 voice-coil actuators. The main requirement for manufacture of the shell is smoothness on scales too small to be adjusted by the actuators. An additional requirement is that the rear surface match the reference body within 30 μm peak-to-valley. A technique was developed for producing smooth surfaces on the very aspheric surfaces of the shells. We figure the optical surfaces on a thick disk of Zerodur, then turn the disk over and thin it to 1.6 mm from the rear surface. Figuring is done primarily with a 30 cm diameter stressed lap, which bends actively to match the local curvature of the aspheric surface. For the thinning operation, the mirror is blocked with pitch, optical surface down, onto a granite disk with a matching convex surface. Because the shell may bend during the blocking operation and as its thickness is reduced to 1.6 mm, figuring of the rear surface is guided by precise thickness measurements over the surface of the shell. This method guarantees that both surfaces of the finished shell will satisfy their requirements when corrected with small actuator forces. Following the thinning operation, we edge the shell to its final dimensions, remove it from the blocking body, and coat the rear surface with aluminum to provide a set of conductive plates for capacitive sensors.
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ESO has initiated in June 2004 a feasibility study to investigate the possibility to retro-fit one of the VLT 8 m telescope with a deformable secondary mirror (DSM). The scope of this effort has been broadened to a concept of Adaptive Optics Facility (adaptive telescope with adapted instrument park). The feasibility study, conducted by MicroGate, ADS Intl and the INAF-Osservatorio Astrofisico di Arcetri, has been successful (no show stopper identified) and has provided an elegant design of an alternate M2-Unit for the VLT. It features a 1170 actuators DSM based on the voice coil force actuators coupled with capacitive sensors. An 80 kHz internal control loop allows implementing of electronic damping. The simulations performed have shown a fitting error of 62.5 nm rms (ro = 12.1 cm @ 30 deg. zenith) with a 2mm thin shell and 1.5 kW of heat dissipation. The design shall provide a full stroke of ~50 μm and a rise time of < 1 msec. The DSM will be focused and "centered" by a Hexapod and a bi-positions electro-mechanism will allow switching from Nasmyth to Cassegrain focus configuration. Several features are planned to ease maintenance and diagnostic.
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The next generation of large telescopes now on the drawing boards (30-100 m. diam) will need adaptive optics to deliver
their full potential. Today the thin glass meniscus necessaries for example for the adaptive secondary mirrors are
produced by tinning conventional thick mirrors: a technique expensive and time consuming. A cost effective technique
for the manufacturing of these components is here proposed that will deliver thin (few mm) lightweight optics made in
glass. The technique under investigation foresees the thermal slumping of thin glass segments using a high quality
ceramic mold (master). The sheet of glass is placed onto the mold and then, by means of a suitable thermal cycle, the
glass is softened and its shape is changed copying the master shape. At the end of the slumping the correction of the
remaining errors will be performed using the Ion Beam Figuring technique, a non-contact deterministic technique. To
reduce the time spent for the correction it will be necessary to have shape errors on the segments after the slumping as
small as possible. To investigate this technique INAF-OAB (Astronomical Observatory of Brera) is building the
necessaries facilities, in particular the oven and mold for the slumping and the Ion Beam Figuring system. The paper
describes the process of production of the optical segments and the status of the investigation.
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For extremely large telescopes, there is strong need for thin deformable mirrors in the 3-4 m class. So far, feasibility of such mirrors has not been demonstrated. Extrapolation from existing techniques suggests that the mirrors could be highly expensive. We give a progress report on a study of an approach for construction of large deformable mirrors with a moderate cost. We have developed low-cost actuators and deflection sensors that can absorb mounting tolerances in the millimeter range, and we have tested prototypes in the laboratory. Studies of control laws for mirrors with thousands of sensors and actuators are in good progress and simulations have been carried out. Manufacturing of thin, glass mirror blanks is being studied and first prototypes have been produced by a slumping technique. Development of polishing procedures for thin mirrors is in progress.
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In telescopes with a Deformable Secondary Mirror, the testing and calibration of both the DSM itself as well as the instruments using this DSM are expensive and time consuming processes. Especially in telescopes without an intermediate focus before the DSM, a number of calibrations can only be performed on a real star during night time. A full suite of Adaptive Optics systems and AO-assisted instruments is currently under development for the VLT, also know as the VLT Adaptive Telescope. ASSIST was developed to assist in the integration and testing of three elements of the VLT Adaptive Telescope Facility; the DSM; the MUSE AO system 'GALACSI' and the HAWK-I AO system 'GRAAL.' The core of ASSIST is a support infrastructure to integrate the DSM in a compact and stable test setup. A Nasmyth rotator simulator will be provided for attaching the two AO systems, while ASSIST will be fed by a star simulator and turbulence generator for realistic performance measurements of both the DSM as well as the AO system under test. An on-axis high-speed interferometer will be used for additional testing of the functional operation of the DSM. In this paper we present the requirements and design of ASSIST and the projected performance of the test bench for both the testing and calibration of the DSM as well as for the two AO systems under test.
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ESO is starting a number of new projects collectively called Second Generation VLT instrumentation. Several of them will use Adaptive Optics (AO). In comparison with today's ESO AO systems, the 2nd Generation VLT AO systems will be much bigger (in terms of degrees of freedom) and faster (in terms of loop frequency). Consequently the Real-Time Computer controlling these AO systems will be significantly bigger and more challenging to build compared with today's AO systems in operation. To support the new requirements ESO started the development of a common flexible platform called SPARTA for Standard Platform for Adaptive optics Real Time Applications. The guidelines along which SPARTA is developed recognize the importance of industry standards over custom development to lower the development costs, ease the maintenance and make the system upgradeable thus delivering the performance required. SPARTA is based on a hybrid architecture that comprises all the major computing architectures available today: the high computational throughput is achieved through the combination of FPGA and DSP usage, where DSP are used as fast coprocessors and FPGA are used as front and as communication infrastructure, thus guaranteeing also the low latency. The flexibility is spread between the usage of both high-end CPUs and again the DSPs. All three technologies are organized in a parallel system interconnected by fast serial fabrics based on standard protocols. External input / output interfaces are also based on industry standard protocols, thus enabling the usage of commercially available tools for development and testing.
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Achieving the science goals of TMT will require AO subsystems of unprecedented power and sophistication, including a
Real Time Controller (RTC) subsystem that will implement wavefront reconstruction and control algorithms for up to
four different laser guide star (LGS) AO systems. The requirements for the RTC represent a significant advance over the
current generation of astronomical AO control systems, both in terms of the wavefront reconstruction algorithms to be
employed and the new hardware approaches that will be required. Additionally, the number of active components
included in the AO systems and the complexity of their interactions will require a highly automated AO Sequencer that
will work in concert with the TMT Telescope and Instrument Sequencers. In this paper, we will describe the control and
software requirements for the whole AO system, and in particular for the RTC and the AO Sequencer. We will describe
the challenges involved in developing these systems and will present a conceptual design.
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An important part of a large solar telescope is the ability to correct, in real time, optical alignment errors caused by gravitational bending of the telescope structure and wavefront errors caused by atmospheric seeing. The National Solar Observatory is currently designing the 4 meter Advanced Technology Solar Telescope (ATST). The ATST wavefront correction system, described in this paper, will incorporate a number of interacting wavefront control systems to provide diffraction limited imaging performance. We will describe these systems and summarize the interaction between the various sub-systems and present results of performance modeling.
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The Large Synoptic Survey Telescope (LSST) is a three mirror modified Paul-Baker design with an 8.4m primary, a
3.4m secondary, and a 5.0m tertiary followed by a 3-element refractive corrector producing a 3.5 degree field of view.
This design produces image diameters of <0.3 arcsecond 80% encircled energy over its full field of view. The image
quality of this design is sufficient to ensure that the final images produced by the telescope will be limited by the
atmospheric seeing at an excellent astronomical site. In order to maintain this image quality, the deformations and rigid
body motions of the three large mirrors must be actively controlled to minimize optical aberrations. By measuring the
optical wavefront produced by the telescope at multiple points in the field, mirror deformations and rigid body motions
that produce a good optical wavefront across the entire field may be determined. We will describe the details of the
techniques for obtaining these solutions. We will show that, for the expected mirror deformations and rigid body
misalignments, the solutions that are found using these techniques produce an image quality over the field that is close to
optimal. We will discuss how many wavefront sensors are needed and the tradeoffs between the number of wavefront
sensors, their layout and noise sensitivity.
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Large degree-of-freedom real-time adaptive optics control requires reconstruction algorithms computationally
efficient and readily parallelized for hardware implementation. Lysa Poyneer (2002) has shown that the wavefront
reconstruction with the use of the fast Fourier transform (FFT) and spatial filtering is computationally
tractable and sufficiently accurate for its use in large Shack-Hartmann-based adaptive optics systems (up to
10,000 actuators). We show here that by use of Graphical Processing Units (GPUs), a specialized hardware
capable of performing FFTs on big sequences almost 7 times faster than a high-end CPU, a problem of up to
50,000 actuators can be already done within a 6 ms limit. The method to adapt the FFT in an efficient way for
the underlying architecture of GPUs is given.
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The adaptive optics MACAO has been implemented in 6 focii of the VLT observatory, in three different flavors. We present in this paper the results obtained during the commissioning of the last of these units, MACAO-CRIRES. CRIRES is a high-resolution spectrograph, which efficiency will be improved by a factor two at least for point-sources observations with a NGS brighter than R=15. During the commissioning, Strehl exceeding 60% have been observed with fair seeing conditions, and a general description of the performance of this curvature adaptive optics system is done.
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We present results from our two year study of ground-layer turbulence as seen through the 6.5-meter Magellan
Telescopes at Las Campanas Observatory. The experiment consists of multiple, moderate resolution, Shack-
Hartmann wavefront sensors deployed over a large 16 arcminute field. Over the two years of the experiment,
the ground-layer turbulence has been sampled on eleven nights in a variety of seeing and wind conditions. On
most nights the ground-layer turbulence contributes 10% to the total visible-band seeing, although a few nights
exhibit ground-layer contributions up to 30%. We present the ground-layer turbulence on the sampled nights as
well as a demonstration of its strength as a function of field size. This information is combined with data from a
MASS-DIMM seeing monitor adjacent to the Magellan Telescopes to infer the annual ground-layer contribution
to seeing at Las Campanas.
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PYRAMIR is a pyramid wavefront sensor (PWFS) for the 97-actuator AO system installed on the Calar Alto 3.5 m
telescope. With its linear pupil sampling of 18 pixels, its maximum loop frequency of 140 Hz, and its sensing
wavelength range from 1.1 micron to 2.4 micron it should be able to deliver reasonably high Strehl ratios at the sensing
wavelength. This feature is still unique in the world of pyramid sensors. The first on-sky test of the system was carried
out in March 2006. In this paper we will present the first results of this test. Strehl measurements medium atmospheric
conditions, using reference stars of mJ=8mag and mJ=4 mag and were performed during this first on-sky run. A detailed
comparison to simulation results will also be presented in order to confirm whether the system works up to expectances.
While this experiment has not yet the potential to show for the very first time the superiority of the pyramid principle
over corresponding Hartmann-Shack systems in a real telescope environment, it was confirmed that PYRAMIR
performs up to expectances and a detailed comparison to the Shack-Hartmann system can be carried out in the next run.
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We propose analytical studies supported by simulation of various centroiding algorithms for Shack-Hartmann based wavefront sensor. We focused on the simple center of gravity as well as one of its optimization, the weighted center of gravity. Noise effects, as well as linearity issues and high flux bias induced by sub-aperture size and PSF structures are investigated. For each method, optimal parameters are defined in function of photon flux, readout noise, and turbulence level.
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This paper describes modeling and simulation results for the Thirty Meter Telescope on the degradation of
sodium laser guide star Shack-Hartmann wavefront sensor measurement accuracy that will occur due to the
spatial structure and temporal variations of the mesospheric sodium layer. Using a contiguous set of LIDAR
measurements of the sodium profile, the performance of a standard centroid and of a more refined noise-optimal
matched filter spot position estimation algorithm is analyzed and compared for a nominal mean signal level
equal to 1000 photo-detected electrons per subaperture per integration time, as a function of subaperture to
laser launch telescope distance and CCD pixel read out noise. Both algorithms are compared in terms of their
rms spot position estimation error due to noise, their associated wavefront error when implemented on the
Thirty Meter Telescope facility adaptive optics system, their linear dynamic range and their bias when detuned
from the current sodium profile.
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The fundamental task of AO system calibration is the acquisition of the Interaction Matrix (IM). This task is usually performed in a laboratory or at the telescope using a reference fiber illuminating both deformable mirror and wavefront sensor. The problem of measuring the IM on a bright reference star has been attacked by some authors. The principal problem of this measurement is to achieve a high SNR when atmospheric turbulence is present. This is very difficult if sensor signals are simply time averaged to get rid of the turbulence effects. The paper presents a new technique to perform an on sky measurement of the IM with high SNR and reducing the overall measurement time by an order of magnitude. This technique can be very useful for AO systems using large size DMs like MMT, LBT and possibly VLT and OWL. In these cases fiber-based IM measurements require challenging optical set-up that in some cases, like for OWL, are unpractical to build. The technique is still relevant for classical small DM AO systems that could be calibrated on sky avoiding misregistration errors. Finally this technique is valuable for laboratory measurements when the IM of an AO system has to be measured with great accuracy against external disturbances like bench vibrations, local turbulence effects and so on. Again IM measurement SNR is increased and the overall measurement time can be significantly reduced. The paper will introduce and detail the technique physical principle and quantify with numerical simulations the SNR improvement achieved using this technique. Finally laboratory results obtained during the test of the LBT AO system prototype are given and compared to simulations.
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The wavefront sensor camera and tip/tilt sensor APDs that were on Lick Observatory's Shane 3 Meter Adaptive Optics system were over a decade old and showing their age. They were recently upgraded. The first upgrade was to convert from quad-APDs in the laser guidestar mode natural star tip-tilt sensor to a sensitive low-noise CCD. The new CCD in this position, an 80x80 E2V CCD-39 inside a SciMeasure camera, has a low enough read noise, ~3 e-/pixel, that the tip/tilt measurement in closed-loop operation is photon noise limited and thus benefits from the improved quantum efficiency of the CCD. We have demonstrated on-sky up to two magnitudes of improvement in viable tip/tilt star brightness, which greatly extends the available sky coverage in the laser guidestar AO mode. Also, the increased field of view of the new tip/tilt sensor provides a much more reliable means of acquiring and locking on dim tip/tilt stars, making the whole system operationally more efficient. In the second phase of the upgrade project, the high order wavefront sensor has been replaced, also with a CCD-39 chip in a SciMeasure camera. In this paper we will describe these upgrades and present preliminary performance results.
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The most common detector configuration for Shack Hartmann (SH) wavefront sensors used for adaptive optics (AO)
wavefront sensing is the quad cell. Advances in detectors, such as the CCDs being developed in a project on which we
are collaborators (funded by the Adaptive Optics Development Program), make it possible to use larger pixel arrays.
The CCD designs incorporate improved read amplifiers and novel pixel geometries optimized for laser guide star (LGS)
AO wavefront sensing. While it is likely that finer sampling of the SH spot will improve the ability of the wavefront
sensor to accurately determine the spot displacement, particularly for elongated or aberrated spots such as those seen in
LGS AO systems, the optimal sampling is not dependent simply on the number of pixels but must also take into account
the effects of photon and detector noise. The performance of a SH wavefront sensor also depends on the performance
of the algorithm used to find the spot displacement. In the literature alternatives have been proposed to the common
center of mass algorithm, but these have not been simulated in detail. In this paper we will describe the results of our
study of the performance of a SH wavefront sensor with a well sampled spot. We will present results for simulations of
the wavefront sensor that enable us to optimize the design of the detector for varying conditions of signal to noise and
spot elongation. We will also discuss the application of correlation algorithms to SH wavefront sensors and present
results regarding the performance and statistics of this algorithm.
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Lockheed Martin Coherent Technologies (LMCT) is developing 20 W and 50 W commercial solid-state sodium beacon Guidestar Laser Systems (GLS) for the Keck I and Gemini South telescopes, respectively. This work represents a critical step toward addressing the need of the astronomical adaptive optics (AO) community for a standardized, robust, turn-key, commercial GLS that can be configured for different observatory facilities and for different AO formats - including multi-conjugate AO (MCAO) and future extremely large telescopes. These modular systems build on the proven laser technologies, user-friendly interface, and low maintenance design that were developed for the successful 12 W GLS delivered by LMCT to the Gemini North telescope in February 2005. This paper describes the GLS requirements for the Keck I and Gemini South telescopes, the design of the laser oscillators, amplifiers, sum-frequency generator, and diagnostics; the functionality of the automated remote laser control system; size, weight, power, and performance data; and the current status of the programs.
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The Thirty Meter Telescope (TMT) will utilize adaptive optics to achieve near diffraction-limited images in the near-infrared using both natural and laser guide stars. The Laser Guide Star Facility (LGSF) will project up to eight Na laser beacons to generate guide stars in the Earth's Na layer at 90 - 110 km altitude. The LGSF will generate at least four distinct laser guide star patterns (asterisms) of different geometry and angular diameter to meet the requirements of the specific adaptive optics modules for the TMT instruments. We describe the baseline concept for this facility, which draws on the heritage from the systems being installed at the Gemini telescopes. Major subsystems include the laser itself and its enclosure, the optics for transferring the laser beams up the telescope structure and the asterism generator and launch telescope, both mounted behind the TMT secondary mirror. We also discuss operational issues, particularly the required safety interlocks, and potential future upgrades to higher laser powers and precompensation of the projected laser beacons using an uplink adaptive optics system.
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Laser guide star (LGS) adaptive optics systems for extremely large telescopes must handle an important effect that is negligible for current generation telescopes. Wavefront errors, due to improperly focusing laser wavefront sensors (WFS) on the mesospheric sodium layer, are proportional to the square of the telescope diameter. The sodium layer, whose mean altitude is approximately 90 km, can move vertically at rates of up to a few metres per second; a few seconds lag in refocusing can substantially degrade delivered image quality (15 m of defocus can cause 120 nm residual wavefront error on a 30-m telescope.) As well, the range of temporal frequencies of sodium altitude focus, overlaps the temporal frequencies of focus caused by atmospheric turbulence. Only natural star wavefront sensors can disentangle this degeneracy. However, applying corrections with representative focus mechanisms having modest control bandwidths causes appreciable tracking errors. In principle, electronic offsets measured by natural guide star detectors could be rapidly applied to laser WFS measurements, but to provide useable sky coverage, integrating sufficient photons causes an unavoidable time delay, again resulting in potentially serious focus tracking errors. However, our analysis depends on extrapolating to temporal frequencies greater than 1 Hz from power spectra of sodium profile time series taken at 1-2 minute intervals. In principle, with a pulsed laser, (e.g. 3-μs pulses) and dynamic refocusing on a polar-coordinate CCD, this focus tracking error may be eliminated. This result is an additional benefit of dynamic refocusing beyond the commonly recognized amelioration of LGS WFS spot elongation.
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Lockheed Martin Coherent Technologies (LMCT) reports on the development of a compact, scalable versatile optical waveform sodium guidestar laser system (GLS) suitable for Adaptive Optics (AO) systems on Extremely Large Telescopes (ELT's) and smaller telescopes. We have successfully completed phase 1 of the three-phase, 4½ year, NSF funded, National Optical Astronomy Observatory (NOAO) sponsored program. The GLS can be optimized for efficient sodium layer interaction for each telescope / AO system with mitigation of parasitic effects such as Rayleigh or cirrus cloud scatter of adjacent beacon light in multi-conjugate adaptive optics (MCAO) and spot elongation in the sodium layer from off-axis light launch in an ELT. The proposed solid-state laser architecture incorporates patent-pending self-imaging waveguide technology and is based on a set of requirements that was determined after extensive discussions with the astronomy adaptive optics community. This paper presents data on single beacon, Rayleigh compensating, and elongation compensating waveforms that were demonstrated through all stages of the architecture, as well as demonstrated and anticipated 589 nm power levels for each waveform. The design of the master oscillator power amplifier (MOPA) architecture, modulation methodology, power amplification, and sum-frequency generation stages is also described. System attributes, including size, weight, and power will also be discussed.
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A computer-automated cw sodium guidestar FASOR (Frequency Addition Source of Optical Radiation) producing a
single frequency 589-nm beam with up to 50 W for mesospheric beacon generation has been integrated with the 3.5-m
telescope at the Starfire Optical Range, Kirtland AFB, New Mexico. Radiance tests have produced a peak guidestar V1
magnitude = 5.1 (~7000 photons/s/cm2 at zenith) for 30 W of circularly polarized pump power in November 2005. Estimated
theoretical maximum guidestar radiance is about 3 times greater than measured values indicating saturation due
to atoms possibly becoming trapped in F'=1 and/or atomic recoil. From sky tests over 3.5 years, we have tracked the
annual variation of the sodium column density by measuring the return flux as a function of fasor power and determining
the slope at zero power. The maximum occurs on October 30 and the minimum on May 30, with corresponding predicted
returns of 8000 (V1 = 4.8) and 3000 (V1 = 5.8) ph/s/cm2 with 50 W of fasor power and circular polarization. The
effect of the Earth's magnetic field on the radiance of the sodium laser guidestar (LGS) from various azimuths and elevations
has been measured. The peak return flux over our observatory occurs at [az=198o; el=+71o], compared with the
direction of the magnetic field lines at [190o; +62o], and it can vary by a factor of 3 over the sky above el = 30o. First
results for non-optimized sodium LGS adaptive optics (AO) closed-loop operation have been obtained using binary
stars. Strehl ratios of 0.03 have been measured at 850 nm and a 0.14 arc second binary star has been resolved during
first closed loop observations. Guidestar characteristics, including radiance, size, and Rayleigh backscatter, the sodium
LGS wavefront sensor (WFS) AO system, and recent closed-loop results on binary stars are presented.
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Future adaptive optics systems will benefit from multiple sodium laser guide stars in achieving satisfactory sky coverage in combination with uniform and high-Strehl correction over a large field of view. For this purpose ESO is developing with industry AFIRE, a turn-key, rack-mounted 589-nm laser source based on a fiber Raman laser. The fiber laser will deliver the beam directly at the projector telescope. The required output power is in the order of 10 W in air per sodium laser guide star, in a diffraction-limited beam and with a bandwidth of < 2 GHz. This paper presents the design and first demonstration results obtained with the AFIRE breadboard. 4.2W CW at 589nm have so far been achieved with a ~20% SHG conversion efficiency.
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The wavefront control strategy for the proposed Gemini Planet Imager, an extreme adaptive optics coronagraph for planet detection, is presented. Two key parts of this strategy are experimentally verified in a testbed at the Laboratory for Adaptive Optics, which features a 32 × 32 MEMS device. Detailed analytic models and algorithms for Shack-Hartmann wavefront sensor alignment and calibration are presented. It is demonstrated that with these procedures, the spatially filtered WFS and the Fourier Transform reconstructor can be used to flatten to the MEMS to 1 nm RMS in the controllable band. Performance is further improved using the technique of modifying the reference slopes using a measurement of the static wavefront error in the science leg.
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An adaptive optics (AO) system is used to control the deformable mirror (DM) actuators for compensating the optical effects introduced by the turbulence in the Earth's atmosphere and distortions produced by the optical elements between the distant object and its local sensor. The typical AO system commands the DM actuators while minimizing the measured wave front (WF) phase error. This is known as the phase conjugator system, which does not work well in the strong scintillation condition because both amplitude and phase are corrupted along the propagation path. In order to compensate for the wave front amplitude, a dual DM field conjugator system may be used. The first and second DM compensate for the amplitude and the phase respectively. The amplitude controller requires the mapping from DM1 actuator command to DM2 intensity. This can be obtained from either a calibration routine or an intensity transport equation, which relates the phase to the intensity. Instead of a dual-DM, a single Spatial Light Modulator (SLM) may control the amplitude and phase independently. The technique uses the spatial carrier frequency and the resulting intensity is related to the carrier modulation, while the phase is the average carrier phase. The dynamical AO performance using the carrier modulation is limited by the actuator frequency response and not by the computational load of the controller algorithm. Simulation of the proposed field conjugator systems show significant improvement for the on-axis performance compared to the phase conjugator system.
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NFIRAOS is the facility AO system for TMT. NFIRAOS does not have a separate tip-tilt mirror. Instead one of its two deformable mirrors will be mounted on a tip-tilt platform, which, due to the weight of the deformable mirror, will only have a ~ 20 Hz bandwidth. This is too slow to correct the tip-tilt disturbance well enough, especially the windshake, which, in the case of TMT, is much more challenging to correct than the atmospheric tip-tilt. Tip-tilt can also be corrected directly on the deformable mirrors, but only a fraction of the incoming tip-tilt can be corrected that way, because of the limited stroke of the actuators. In this paper, we propose a woofer-tweeter approach, by which the high amplitude low temporal frequencies of tip-tilt are corrected by the tip-tilt platform, whereas the low amplitude high temporal frequencies are corrected by the deformable mirrors. This approach is based on a double integration control scheme and provides a much better attenuation of the windshake: 0.4 mas rms instead of 3.6, corresponding to an equivalent high order error of 20 nm rms instead of 180 nm rms. We find that only ~ 10% of the initial 25 mas rms windshake needs to be corrected by the DMs. With a 5-σ margin, this corresponds to only an extra ~1 micron of stroke for the actuators at the edge of the pupil, which are the most affected.
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This paper presents a nonlinear modification of the standard linear adaptive optics controller that greatly reduces the startup lag due to saturation in pyramid wavefront sensors (or any wavefront sensor with 4-cell subapertures). Whenever the pyramid sensor is saturated (as determined by an internal model of the saturation in the controller), the deformable mirror signal is adjusted to quickly remove the saturation of the sensor. When the pyramid sensor is not saturated, a standard linear adaptive optics controller is used to generate the deformable mirror signal. The nonlinear controller is compared with a standard linear controller using a CAOS simulation. It is shown that the startup lag is significantly reduced, and that the steady-state performance is identical to the linear controller.
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Classic Adaptive Optics (AO) is now successfully implemented on a growing number of ground-based imaging systems.
Nevertheless some limitations are still to cope with. First, the AO standard control laws are unable to easily handle
vibrations. In the particular case of eXtreme AO (XAO), which requires a highly efficient AO, these vibrations can thus
be much penalizing. We have previously shown that a Kalman based control law can provide both an efficient correction
of the turbulence and a strong vibration filtering. Second, anisoplanatism effects lead to a small corrected field of view. Multi-Conjugate AO (MCAO) is a promising concept that should increase significantly this field of view. We have shown
numerically that MCAO correction can be highly improved by optimal control based on a Kalman filter. This article
presents the first laboratory demonstration of these two concepts.
We use a classic AO bench available at Onera with a deformable mirror (DM) in the pupil and a Shack-Hartmann Wave
Front Sensor (WFS) pointing at an on-axis guide-star. The turbulence is produced by a rotating phase screen in altitude.
First, this AO configuration is used to validate the ability of our control approach to filter out system vibrations and improve
the overall performance of the AO closed-loop, compared to classic controllers. The consequences on the RTC design of
an XAO system is discussed. Then, we optimize the correction for an off-axis star although the WFS still points at the
on-axis star. This Off-Axis AO (OAAO) can be seen as a first step towards MCAO or Multi-Object AO in a simplified
configuration. It proves the ability of our control law to estimate the turbulence in altitude and correct in the direction of
interest. We describe the off-axis correction tests performed in a dynamic mode (closed-loop) using our Kalman based
control. We present the evolution of the off-axis correction according to the angular separation between the stars. A highly
significant improvement in performance is demonstrated.
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The UCO/Lick Observatory Laboratory for Adaptive Optics charter goal is to advancing the state of the art in
adaptive optics technology for instruments on the current and next generation of extremely large telescopes. We are
investigating the architecture and techniques for implementing wide field adaptive optics systems for general purpose
imaging and spectroscopy and high contrast adaptive optics systems for imaging extrasolar planets. The laboratory
has two testbeds, a high contrast extreme adaptive optics (ExAO) testbed and a multi-guidestar tomography adaptive
optics testbed. The later is reconfigurable between multi-conjugate AO (MCAO) and multi-object AO (MOAO)
architectures. The testbeds are scaled to emulate 10 to 30 meter aperture telescope AO systems and allow systematic
study of the performance and practicalities of such systems. Additionally, we are developing and testing new AO
component technologies including novel wavefront sensors and MEMS deformable mirrors. In this paper we
highlight the status and direction of the laboratory experiments and summarize the latest results.
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The Woofer-Tweeter experiment started in the Adaptive Optics Laboratory of the University of Victoria in February 2005 has recently achieved completion. The goal of this experiment is to validate the woofer-tweeter AO concept i.e. instead to have a single deformable mirror conjugated at the ground, two DMs conjugated at the ground are used to achieve both the necessary stroke and actuators density required for a single DM for an ELT. Recently, the loop has been closed on the turbulence with a loop rate of 100Hz. Two closed-loop controllers have been tested so far: a global integrator and a tweeter off-loading integrator. This paper describes the UVic Woofer-Tweeter bench layout and components and the Woofer-Tweeter simulation tool used to both model and control the experiment. A glimpse on the very first results from the closed-loop operations is also given.
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In objective or task-based assessment of image quality, figures of merit are defined by the performance of some specific observer on some task of scientific interest. This methodology is well established in medical imaging but is just beginning to be applied in astronomy. In this paper we survey the theory needed to understand the performance of ideal or ideal-linear (Hotelling) observers on detection tasks with adaptive-optical data. The theory is illustrated by discussing its application to detection of exoplanets from a sequence of short-exposure images.
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In the last few years, new Adaptive Optics [AO] techniques have emerged to answer new astronomical challenges:
Ground-Layer AO [GLAO] and Multi-Conjugate AO [MCAO] to access a wider Field of View [FoV], Multi-Object
AO [MOAO] for the simultaneous observation of several faint galaxies, eXtreme AO [XAO] for the detection
of faint companions. In this paper, we focus our study to one of these applications : high red-shift galaxy
observations using MOAO techniques in the framework of Extremely Large Telescopes [ELTs]. We present the
high-level specifications of a dedicated instrument. We choose to describe the scientific requirements with the
following criteria : 40% of Ensquared Energy [EE] in H band (1.65μm) and in an aperture size from 25 to 150 mas.
Considering these specifications we investigate different AO solutions thanks to Fourier based simulations. Sky
Coverage [SC] is computed for Natural and Laser Guide Stars [NGS, LGS] systems. We show that specifications
are met for NGS-based systems at the cost of an extremely low SC. For the LGS approach, the option of low
order correction with a faint NGS is discussed. We demonstrate that, this last solution allows the scientific
requirements to be met together with a quasi full SC.
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The performance of an adaptive optics system is typically given in terms of the Strehl ratio of a point spread function (PSF) measured in the focal plane of the system. The Strehl ratio measures the normalized peak intensity of the PSF compared to that of an ideal PSF, i.e. aberration-free, through the system. One advantage of this metric is that it has been shown to be proportional to the rms wavefront error via the Marechel approximation. Thus, Strehl ratio measurements are used to determine the performance of the system. Measurement of the Strehl ratio is frequently problematic in the presence of noise as can be the peak determination for critically sampled data. We have looked at alternative metrics, in particular the S1 sharpness metric. This metric measures the compactness of the PSF by the normalized sum of the squared image intensity and therefore relates to the intensity variance of the image. Using simulated AO PSFs, we show that there is a unique relationship between S1 and the Strehl ratio and we can therefore relate it back to the rms wavefront error.
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Spherical-wave scintillation is shown to impose multi-conjugate adaptive optics (MCAO) correctability limitations that are independent of wavefront sensing and reconstruction. Residual phase and log-amplitude variances induced by scintillation in weak turbulence are derived using (diffraction-based) diffractive MCAO spatial filters or (diffraction-ignorant) geometric MCAO proportional gains as linear open-loop control parameters. In the case of Kolmogorov turbulence, expressions involving the Rytov variance and/or weighted Cn2 integrals apply. Differences in performance between diffractive MCAO and geometric MCAO resemble chromatic errors. Optimal corrections based on least squares imply irreducible performance limits that are validated by wave-optic simulations.
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Several designs of future Adaptive Optics (AO) systems propose to use a large Deformable Mirror (DM), regarding the size as well as the number of actuators. Most of the time, there is no focal plane upstream the DM. Therefore, the classical way of calibrating the interaction matrix on an artificial source cannot be applied. Furthermore, the requirements in terms of calibration error budget are tight and the high order modes of such DMs are stiff and hence they achieve only a small stroke. This is why novel ways to determine the system Interaction Matrix (IM) have to be investigated. Several paths have been studied. One solution would be to simulate a synthetic IM. However, calibration on sky is also an option. Different techniques were simulated, tested and optimized on real AO systems. The results are presented in this paper.
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Current high-contrast "extreme" adaptive optics (ExAO) systems are partially limited by deformable mirror technology. Mirror requirements specify thousands of actuators, all of which must be functional within the clear aperture, and which give nanometer flatness yet micron stroke when operated in closed loop.1 Micro-electrical mechanical-systems (MEMS) deformable mirrors have been shown to meet ExAO actuator yield, wavefront error, and cost considerations. This study presents the performance of Boston Micromachines' 1024-actuator continuous-facesheet MEMS deformable mirrors under tests for actuator stability, position repeatability, and practical operating stroke. To explore whether MEMS actuators are susceptible to temporal variation, a series of long-term stability experiments were conducted. Each actuator was held fixed and the motion over 40 minutes was measured. The median displacement of all the actuators tested was 0.08 nm surface, inclusive of system error. MEMS devices are also appealing for adaptive optics architectures based on open-loop correction. In experiments of actuator position repeatability, 100% of the tested actuators returned repeatedly to their starting point with a precision of < 1 nm surface. Finally, MEMS devices were tested for maximum stroke achieved under application of spatially varying one-dimensional sinusoids. Given a specified amplitude in voltage, the measured stroke was 1 μm surface at the low spatial frequencies, decreasing to 0.2 μm surface for the highest spatial frequency. Stroke varied somewhat linearly as inverse spatial frequency, with a flattening in the relation at the high spatial frequency end.
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Next generation adaptive optical (AO) systems require deformable mirrors with very challenging parameters, up to
250 000 actuators and inter-actuator spacing around 500μm. MOEMS-based devices are promising for the development
of a complete generation of new deformable mirrors. We are currently developing a micro-deformable mirror (MDM)
based on an array of electrostatic actuators with attachments to a continuous mirror on top. The originality of our
approach lies in the elaboration of layers made of polymer materials. Mirrors with very efficient planarization and
active actuators have been demonstrated, with a piston motion of 2μm for 30V. Using our dedicated characterization
bench, we have measured a 6.5kHz resonance frequency, well suited for AO applications. Based on the design of this
actuator and our polymer process, realization of a complete polymer-MDM is under way.
The electrostatic force provides a non-linear actuation, while AO systems are based on linear matrices operations. Then,
we have developed a dedicated 14-bit electronics in order to "linearize" the actuation. After calibrating the behavior of
each actuator and fitting the curve by a sixth order polynomial, the electronics delivers a linearized output. The response
is nearly perfect over our 3×3 MDM prototype with a standard deviation of 3.5 nm, and we have then obtained the
influence function of the central actuator. First evaluation on the cross non-linarities has also been evaluated on the
OKO mirror and a simple look-up table is sufficient for determining the location of each actuator whatever the locations
of the neighbor actuators. Electrostatic MDM are particularly well suited for AO applications.
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In this paper we present a mathematical model for a point-actuated, continuous facesheet deformable mirror. The model consists of a single partial differential equation for the facesheet coupled with a number of nonlinear algebraic constraints (one constraint per actuator). We also present a nonlinearly constrained quadratic minimization problem whose solution gives the quasi-steady state control for the mirror, given a target wavefront aberration.
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A new analytic approach for the description of deformable mirror facesheet deformation is presented. This new approach contains a high degree of physics fidelity, yet is relatively simple to implement and quick to use when compared with the equally-accurate finite element approach. Modeled physics include thin plate treatment for the deformable mirror facesheet and full mechanical coupling between the facesheet and the underlying actuators. Example influence functions for a circular DM are presented.
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In the design of a large adaptive deformable membrane mirror, variable reluctance actuators are used. These consist of a
closed magnetic circuit in which a strong permanent magnet provides a static magnetic force on a ferromagnetic core
which is suspended in a membrane. By applying a current through the coil which is situated around the magnet, this force
is influenced, providing movement of the ferromagnetic core. This movement is transferred via a rod imposing the out-of-plane
displacements in the reflective deformable membrane. In the actuator design a match is made between the negative
stiffness of the magnet and the positive stiffness of the membrane suspension. If the locality of the influence functions,
mirror modes as well as force and power dissipation are taken into account, a resonance frequency of 1500 Hz and an
overall stiffness of 1000 N/m for the actuators is needed. The actuators are fabricated and the dynamic response tested in a
dedicated setup. The Bode diagram shows a first eigenfrequency of 950 Hz. This is due to a lower magnetic force than
expected. A Helmholtz coil setup was designed to measure the differences in a large set of permanent magnets. With the
same setup the 2nd quadrant of the B-H curve is reconstructed by stacking of the magnets and using the demagnetization
factor. It is shown that the values for Hc and Br of the magnets are indeed lower than the values used for the initial design.
New actuators, with increased magnet thickness, are designed and currently fabricated.
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In this paper we present an overview of the construction and implementation of the unmodulated infrared pyramid wavefront sensor PYRAMIR at the Calar Alto 3.5 m telescope. PYRAMIR is an extension of the existing visible Shack-Hartmann adaptive optics system ALFA, which allows wavefront sensing in the near-infrared wavefront regime. We describe the optical setup and the calibration procedure of the pyramid wavefront sensor. We discuss possible drawbacks of the calibration and show the results gained on Calar Alto.
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The Multiconjugate Adaptive optics Demonstrator (MAD) for ESO-Very Large Telescopes (VLT) will demonstrate on sky the MultiConjugate Adaptive Optics (MCAO) technique. In this paper the laboratory tests relative to the first preliminary acceptance in Europe of the Layer Oriented (LO) Wavefront Sensor (WFS) for MAD will be described: the capabilities of the LO approach have been checked and the ability of the WFS to measure phase screens positioned at different altitudes has been experimented. The LO WFS was opto-mechanically integrated and aligned in INAF - Astrophysical Observatory of Arcetri before the delivering to ESO (Garching) to be installed on the final optical bench.
The LO WFS looks for up to 8 reference stars on a 2arcmin Field of View and up to 8 pyramids can be positioned where the focal spot images of the reference stars form, splitting the light in four beams. Then two objectives conjugated at different altitudes simultaneously produce a quadruple pupil image of each reference star.
An optical bench setup and transparent plastic screens have been used to simulate telescope and static atmospheric layers at different altitudes and a set of optical fibers as (white) light source.
The plastic screens set has been characterized using an inteferometer and the wave-front measurements compared to the LO WFS ones have shown correlation up to ~95%.
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The two-sided pyramid wavefront sensor has been extensively simulated in the direct phase mode using a wave optics code. The two-sided pyramid divides the focal plane so that each half of the core only interferes with the speckles in its half of the focal plane. A relayed image of the pupil plane is formed at the CCD camera for each half. Antipodal speckle pairs are separated so that a pure phase variation causes amplitude variations in the two images. The phase is reconstructed from the difference of the two amplitudes by transforming cosine waves into sine waves using the Hilbert transform. There are also other corrections which have to be applied in Fourier space. The two-sided pyramid wavefront sensor performs extremely well: After two or three iterations, the phase error varies purely in y. The twosided pyramid pair enables the phase to be completely reconstructed. Its performance has been modeled closed loop with atmospheric turbulence and wind. Both photon noise and read noise were included. The three-sided and four-sided pyramid wavefront sensors have also been studied in direct phase mode. Neither performs nearly as well as does the two-sided pyramid wavefront sensor.
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LINC-NIRVANA is an infrared camera that will work in Fizeau interferometric way at the Large Binocular Telescope (LBT). The two beams that will be combined in the camera are corrected by an MCAO system, aiming to cancel the turbulence in a scientific field of view of 2 arcminutes. The MCAO wavefront sensors will be two for each arm, with the task to sense the atmosphere at two different altitudes (the ground one and a second height variable between a few kilometers and a maximum of 15 kilometers). The first wavefront sensor, namely the Ground layer Wavefront sensor (GWS), will drive the secondary adaptive mirror of LBT, while the second wavefront sensor, namely the Mid High layer Wavefront Sensor (MHWS) will drive a commercial deformable mirror which will also have the possibility to be conjugated to the same altitude of the correspondent wavefront sensor. The entire system is of course duplicated for the two telescopes, and is based on the Multiple Field of View (MFoV) Layer Oriented (LO) technique, having thus different FoV to select the suitable references for the two wavefront sensor: the GWS will use the light of an annular field of view from 2 to 6 arcminutes, while the MHWS will use the central 2 arcminutes part of the FoV. After LINC-NIRVANA has accomplished the final design review, we describe the MFoV wavefront sensing system together with its current status.
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The 8 m SUBARU telescope atop Mauna Kea on Hawaii will shortly be equipped with a 188 actuator adaptive optics system (AO 188). Additionally it will be equipped with a Laser guide star (LGS) system to increase the sky coverage of that system. One of the additional tip-tilt sensor which is required to operate AO 188 in LGS mode will be working in the infrared to further enhance the coverage in highly obscured regions of the sky. Currently, various options for this sensor are under study, however the baseline design is a pyramid wavefront sensor. It is currently planned to have this sensor be able to provide also information on higher modes in order to feed AO 188 alone, i.e. without the LGS when NIR-bright guide stars are available. In this paper, we will present the results of the basic design tradeoffs, the performance analysis, and the project plan. Choices to be made concern the number of subapertures available across the primary mirror, the number of corrected modes, control of the AO system in combination with and without LGS, the detector of the wavefront sensor, the operation wavelength range and so forth. We will also present initial simulation results on the expected performance of the device, and the overall timeline and project structure.
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The direct imaging from the ground of extrasolar planets has become today a major astronomical and biological focus. This kind of imaging requires simultaneously the use of a dedicated high performance Adaptive Optics [AO] system and a differential imaging camera in order to cancel out the flux coming from the star. In addition, the use of sophisticated post-processing techniques is mandatory to achieve the ultimate detection performance required. In the framework of the SPHERE project, we present here the development of a new technique, based on Maximum A Posteriori [MAP] approach, able to estimate parameters of a faint companion in the vicinity of a bright star, using the multi-wavelength images, the AO closed-loop data as well as some knowledge on non-common path and differential aberrations. Simulation results show a 10-5 detectivity at 5σ for angular separation around 15λ/D with only two images.
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High-contrast imaging, particularly direct detection of extrasolar planets, is a major science driver for the next
generation of extremely large telescopes such as the segmented Thirty Meter Telescope. This goal requires
more than merely diffraction-limited imaging, but also attention to residual scattered light from wavefront errors
and diffraction effects at the contrast level of 10-8-10-9. Using a wave-optics simulation of adaptive optics
and a diffraction suppression system we investigate diffraction from the segmentation geometry, intersegment
gaps, obscuration by the secondary mirror and its supports. We find that the large obscurations pose a greater
challenge than the much smaller segment gaps. In addition the impact of wavefront errors from the primary
mirror, including segment alignment and figure errors, are analyzed. Segment-to-segment reflectivity variations
and residual segment figure error will be the dominant error contributors from the primary mirror. Strategies to
mitigate these errors are discussed.
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We discuss contrast limits obtained during a survey of young (<300 Myr), close (<50 pc) stars with the Simultaneous Differential Extrasolar Planet Imager (SDI) implemented at the VLT and the MMT. SDI uses a double Wollaston prism and a quad filter to take images simultaneously at 3 wavelengths surrounding the 1.62 μm methane bandhead found in the spectrum of cool brown dwarfs and gas giants. By performing a difference of images in these filters, speckle noise from the primary can be significantly attenuated, resulting in photon noise limited data. In our survey data, we achieved H band contrasts >25000 (5σ ΔF1(1.575μm)>10 mag, ΔH>10.6 mag for a T6 spectral type) at a separation of 0.5" from the primary star. With this degree of attenuation, we can image (5σ detection) a 2-4 Jupiter mass planet at 5 AU around a 30 Myr star at 10 pc. We are currently completing our survey of young, nearby stars. We have obtained complete datasets for 40 stars in the southern sky (VLT) and 11 stars in the northern sky (MMT). We believe that our SDI images are the highest contrast astronomical images ever made from ground or space for methane rich companions.
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A simple analytic form for the intensity point spread function is obtained in terms of the power spectral density function for the phase. Two fourier transforms are required to compute the psf from the psd (A third fourier transform is needed to give the fraction of the light in the core). The analytic form is an infinite sum of convolution integrals of increasing order in the psd function multiplied by the simple renormalization factor exp(-sigma^2), where sigma^2 is the two-dimensional integral of the psd in radians squared. Computationally, the psf is evaluated on a discrete grid in kx-ky space. This infinite sum can be evaluated at all pixels other than the zero frequency pixel by taking the two-dimensional complex fourier transform X of the psd, computing exp(X)-1, and then taking the inverse fourier transform. There is also a simple expression for the value at the zero spatial frequency pixel. Like the psd, the psf is smooth because the psf is an ensemble average over all realizations for the phase: Each realization of the phase gives an intensity speckle pattern in the focal plane. The psf is the ensemble average over all realizations. This transformation has been extensively tested for azimuthally symmetric phase psd functions by comparing the computed psf using the analytic transformation with the azimuthally averaged psf computed using a specific realization for the phase. The psd functions that were compared this way were all azimuthally symmetric, but the analytic transformation from psd to psf doesn't require this. The final result for the halo is equivalent to the result in Hardy1 when the pupil is infinite. The derivation in this paper is simple and direct.
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Atmospheric dispersion represents a relatively overlooked problem in connection with the ultimate quality of ELT images corrected by adaptive optics (AO). The aim of this paper is to evaluate the contribution from atmospheric dispersion to the background level of the point-spread function (PSF). Since proper suppression of this level is important for the prospects for direct exo-planet observation, it is necessary to quantify the contributions from all possible sources to it. Atmospheric dispersion will in principle result in three different kinds of contributions. The first one is related to the fact that two rays of different color following the same path through the atmosphere to the telescope do not have the same optical path-length difference (OPD). The second one is related to the fact that two coinciding rays of different color entering the atmosphere at a non zero zenith angle will be separated due to refraction before they reach the telescope. The third one is related to the fact that rays are diffracted by inhomogeneities in the atmosphere and that the diffraction angle is dependent on color. This last effect is small and will not be treated here. As a consequence of dispersion phase fluctuations can, in principle, only be compensated at a single wavelength by AO systems with deformable mirrors (DMs). Hence looking for an exo-planet in a certain spectral bandwidth there will be a contribution from the parent star uncorrected background level. Hence it will be crucial to perform observations in a narrow spectral bandwidth and to ensure that the wavefront measurements used for AO correction are performed within the same narrow bandwidth. The last point affects the needed magnitude of the parent star, which is used for wavefront measurements.
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The Adaptive Optics Module of the Telescopio Nazionale Galileo (AdOpt@TNG) has enjoyed a huge refurbishment. A new WaveFront Sensing CCD (EEV39 80x80pixels by SciMeasure) has been mounted, allowing for up to 1KHz frame rate. Thanks to the versatility of the pyramid wavefront sensor, the fast changing of the 4x4 and 8x8 pupil sampling has been easily and successfully implemented. A dual pentium processor PC with Real-Time Linux has substituted the old VME as Real Time Computer. The implementation of the new Deformable Mirror by Xinetics will be also discussed. A new Graphical User Interface has been built to allow for user-friendly utilization of the module by astronomers. On-sky observations will be presented in terms of FWHM and Strehl Ratio for different values of guiding star magnitudes and seeing conditions. The encouraging on-sky results and overall system stability pushed to offer AdOpt@TNG to the international astronomical community.
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The GLAS (Ground-layer Laser Adaptive-optics System) project is to construct a common-user Rayleigh laser beacon that will work in conjunction with the existing NAOMI adaptive optics system, instruments (near IR imager INGRID, optical integral field spectrograph OASIS, coronagraph OSCA) and infrastructure at the 4.2-m William Herschel Telescope (WHT) on La Palma. The laser guide star system will increase sky coverage available to high-order adaptive optics from ~1% to approaching 100% and will be optimized for scientific exploitation of the OASIS integral-field spectrograph at optical wavelengths. Additionally GLAS will be used in on-sky experiments for the application of laser beacons to ELTs. This paper describes the full range of engineering of the project ranging through the laser launch system, wavefront sensors, computer control, mechanisms, diagnostics, CCD detectors and the safety system. GLAS is a fully funded project, with final design completed and all equipment ordered, including the laser. Integration has started on the WHT and first light is expected summer 2006.
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Building on an extensive and successful experience in Adaptive Optics (AO) and on recent developments made in its funding nations, the Canada-France-Hawaii-Telescope Corporation (CFHT) is studying the VASAO concept: an integrated AO system that would allow diffraction limited imaging of the whole sky in the visible as well as in the infrared. At the core of VASAO, Pueo-Hou (the new Pueo) is built on Pueo, the current CFHT AO bonnette. Pueo will be refurbished and improved to be able to image the isoplanetic field at 700 nm with Strehl ratios of 30% or better, making possible imaging with a resolution of 50 milliarcseconds between 500 and 700nm, and at the telescope limit of diffraction above. The polychromatic tip-tilt laser guide star currently envisioned will be generated by a single 330nm mode-less laser, and the relative position of the 330nm and 589nm artificial stars created on the mesosphere by the 330nm excitation of the sodium layer will be monitored to provide the atmospheric tip-tilt along the line of sight, following the philosophy developed for the ELP-OA project. The feasibility study of VASAO will take most of 2006 in parallel with the development of a science case making the best possible use of the unique capabilities of the system, If the feasibility study is encouraging, VASAO development could start in 2007 for a full deployment on the sky by 2011-2012.
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We present a summary of our current results from the Extreme Adaptive Optics (ExAO) Testbed and the design
and status of its coronagraphic upgrade. The ExAO Testbed at the Laboratory for Adaptive Optics at UCO/Lick
Observatory is optimized for ultra-high contrast applications requiring high-order wavefront control. It is being
used to investigate and develop technologies for the Gemini Planet Imager (GPI). The testbed is equipped with
a phase shifting diffraction interferometer (PSDI), which measures the wavefront with sub-nm precision and
accuracy. The testbed also includes a 1024-actuator Micro Electro Mechanical Systems (MEMS) deformable
mirror manufactured by Boston Micromachines. We present a summary of the current results with the testbed
encompassing MEMS flattening via PSDI, MEMS flattening via a Shack-Hartmann wavefront sensor (with and
without spatial filtering), the introduction of Kolmogorov phase screens, and contrast in the far-field. Upgrades
in progress include adding additional focal and pupil planes to better control scattered light and allow alternative
coronagraph architectures, the introduction and testing of high-quality reflecting optics, and a variety of input
phase aberrations. Ultimately, the system will serve as a full prototype for GPI.
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Extreme adaptive optics systems dedicated to the search for extrasolar planets are currently being developed for most 8-10 meter telescopes. Extensive computer simulations have shown the ability of both Shack-Hartmann and pyramid wave front sensors to deliver high Strehl ratio correction expected from extreme adaptive optics but few experiments have been realized so far. The high order test bench implements extreme adaptive optics on the MACAO test bench with realistic telescope conditions reproduced by star and turbulence generators. A 32×32 actuator micro deformable mirror, one pyramid wave front sensor, one Shack-Hartmann wave front sensor, the ESO SPARTA real time computer and an essentially read-noise free electron multiplying CCD60 (E2V CCD60) provide an ideal cocoon to study the different behavior of the two types of wave front sensors in terms of linearity, sensitivity to calibration errors, noise propagation, specific issues to pyramid or Shack-Hartmann wave front sensors, etc. We will describe the overall design of this test bench and will focus on the characterization of two essential sub-systems: the micro deformable mirror and the phase screens.
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Direct detection of exo-planets from the ground will become a reality with the advent of a new class of extreme-adaptive
optics instruments that will come on-line within the next few years. In particular, the Gemini Observatory will be
developing the Gemini Planet Imager (GPI) that will be used to make direct observations of young exo-planets. One
major technical challenge in reaching the requisite high contrast at small angles is the sensing and control of residual
wave front errors after the starlight suppression system. This paper will discuss the nature of this problem, and our
approach to the sensing and control task. We will describe a laboratory experiment whose purpose is to provide a means
of validating our sensing techniques and control algorithms. The experimental demonstration of sensing and control will
be described. Finally, we will comment on the applicability of this technique to other similar high-contrast instruments.
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The coronagraphic focal plane interferometer reflects away the core starlight with a mirror in the focal plane and uses it
to form a coherent interferometric reference beam. This is used in a Mach-Zehnder configuration with phase shifting to
measure the complex amplitude of the star halo speckles in the focal plane where the interference takes place. We
present results from a laboratory prototype in which the speckles are suppressed over half the field by modifying the
wavefront in a pupil plane with a MEMS deformable mirror, based on a Fourier transform of the complex halo derived
from the focal plane interferometric data. Even deeper suppression of the residual stellar halo over the full 360 degree
field will be possible by explicitly constructing an "anti-halo" from the reference beam; a new technique for exoplanet
imaging (Codona and Angel, 2004). We present the design and current status of a laboratory prototype to study antihalo
apodization. The spatially-filtered core starlight will be modulated by deformable mirrors in a Michelson
configuration to form a temporally-coherent copy of the measured residual complex halo, with the same amplitude but
opposite phase (i.e. an "anti-halo"). Using components with only modest control accuracy, the method has the potential
to reduce an already low residual halo by an additional two decades.
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We are developing a new class of deformable optic based on electrostatic actuation of nanolaminate foils. These foils are engineered at the atomic level to provide optimal opto-mechanical properties, including surface quality, strength and stiffness, for a wide range of deformable optics. We are combining these foils, developed at Lawrence Livermore National Laboratory (LLNL), with commercial metal processing techniques to produce prototype deformable optics with aperture sizes up to 10 cm and actuator spacing from 1 mm to 1 cm and with a range of surface deformation designed to be as much as 10 microns. The existing capability for producing nanolaminate foils at LLNL, coupled with the commercial metal processing techniques being used, enable the potential production of these deformable optics with aperture sizes of over 1 m, and much larger deformable optics could potentially be produced by tiling multiple deformable segments. In addition, based on the fabrication processes being used, deformable nanolaminate optics could potentially be produced with areal densities of less than 1 kg per square m for applications in which lightweight deformable optics are desirable, and deformable nanolaminate optics could potentially be fabricated with intrinsically curved surfaces, including aspheric shapes. We will describe the basic principles of these devices, and we will present details of the design, fabrication and characterization of the prototype deformable nanolaminate optics that have been developed to date. We will also discuss the possibilities for future work on scaling these devices to larger sizes and developing both devices with lower areal densities and devices with curved surfaces.
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Recently, a new type of liquid based deformable mirror has been proposed and demonstrated. The device consists of an array of vertically oriented open capillary channels immersed in a pool of two immiscible liquids and a free-floating reflective membrane, which serves as the reflecting surface. Liquid surface and membrane deformations are facilitated by means of electrocapillary actuation that induces upward or downward flow of liquid inside the capillary. This electrocapillary movement of liquid can be individually controlled. The advantages of this proposed device include high stroke dynamic range, low power dissipation, high number of actuators, fast response time, and reduced fabrication cost. The device is mainly suitable for dynamic wavefront correction. We present some aspects of the modeling of the device.
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Adaptive optics performance is essential for achieving the demanding science goals set for the ground-based optical telescopes
of the future - the so-called extremely large telescopes (ELTs). Research into novel technologies for lightweight
and robust active and adaptive mirrors is crucial for ensuring this capability. Surface quality, form, and a high level of
stability during operation are very important criteria for such mirrors. In 2004 we reported initial results from a project into
the design and manufacture of a prototype carbon fibre reinforced polymer (CFRP) deformable mirror. This system has
now been extensively characterised and tested, and results of dynamical testing and influence function measurements are
discussed here. Manual grinding and polishing resulted in a residual form error of the order of 10 μm P-V and a surface
roughness of approximately 5 nm rms. A good agreement was observed between the modeling data and experimental
results.
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Next generation adaptive-optics systems (AO) have unprecedented complexity. The proposed number of degrees-of-freedom has considerably increased, putting the focus on the real-time processing capabilities. Second generation instrumentation for the Very-Large Telescope (VLT) is one such case. We present a method capable of lowering the average computational effort (i.e. lowering the average frame-rate) and deliver the same performance figures. It consists of applying a distributed set of update rates to outperform the conventional vector-matrix multiplies (VMM) used for modal reconstruction and control in AO systems when Zernike polynomials or Karhunen-Loeve modes are used as basis. We analyse the low and high-noise regimes for which we outline the theoretical key points and present both semi-analytical and Monte-Carlo simulation results having the Planet-Finder (PF) as baseline system.
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Most adaptive optics systems (AO) are based on a simple control law that is unable to account for the temporal evolution of the wavefront. In this paper, a recently proposed data-driven Η2-optimal control approach is demonstrated on an AO laboratory setup. The proposed control approach does not assume any form of decoupling and can therefore exploit the spatio-temporal correlation in the wavefront. The performance of the optimal control approach is compared with a conventional method. An analysis of the dominant error sources shows that the optimal control approach leads to a significant reduction in the temporal error. Since the temporal error grows with the Greenwood to sampling frequency ratio, the performance gain is especially large at large ratios.
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In this paper we present a Fourier-domain preconditioned conjugate gradient algorithm for the fitting step in Multi-Conjugate Adaptive Optics (MCAO) for extremely large telescopes. This algorithm is fast and robust, and it is convenient to implement with parallel processing in a real-time system. Simulation results are presented for an MCAO system for a 30-meter telescope with 2 deformable mirrors.
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Adaptive optics (AO) systems under study for the future generation of telescopes have to cope with a huge number of degrees of freedom. This number N is typically 2 orders of magnitude larger than for the currently existing AO systems. An iterative method using a fractal preconditioning, has recently been suggested for a minimum-variance reconstruction in O(N) operations. We analyze the efficiency of this algorithm for both the open-loop and the closed-loop configurations. We present the formalism and illustrate the assets of this method with simulations. While the number of iterations for convergence is around 10 in open-loop, the closed-loop configuration induces a reduction of the required number of iterations by a factor of 3 typically. This analysis also enhances the importance of introducing priors to ensure an optimal command. Closed-loop simulations demonstrate the loss of performance when no temporal priors are used. Besides, we discuss the importance of an accurate model for both the system and its uncertainties, so as to ensure a stable behavior in closed-loop.
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The next generation of adaptive optics (AO) systems, often referred to as extreme adaptive optics (ExAO), will use higher numbers of actuators to achieve wavefront correction levels below 100 nm, and so enable a host of new observations such as high-contrast coronagraphy. However, the number of potential coronagraph types is increasing rapidly, and selection of the most advantageous coronagraph is subject to many factors. Here it is pointed out that experiments in the ExAO regime can already be carried out with existing hardware, by using a well-corrected subaperture on an existing telescope. For example, by magnifying a 1.5 m diameter off-axis subaperture onto the AO system's deformable mirror (DM) on the Palomar Hale telescope, we have recently achieved stellar Strehl ratios as high as 92% to 94%, corresponding to wavefront errors of 85 - 100 nm. Using this approach, a wide variety of ExaO experiments can thus be carried out well before "next generation" ExAO systems are deployed on large telescopes. The potential experiments include infrared ExAO imaging and performance optimization, a comparison of coronagraphic approaches in the ExAO regime, visible wavelength AO, and predictive AO.
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In the case where wind blown turbulence is mostly adhering to frozen flow conditions the use of the Kalman Filter in an adaptive optics controller is of interest because it incorporates prior the time history of wavefront measurements as additional information to be combined with the immediate measurement of the wavefront. In prior work we have shown that indeed there is a signal to noise advantage, however the extra real-time overhead of the Kalman Filter computations can become prohibitive for larger aperture systems. In this paper we investigate a Fourier domain implementation that might approximate, and gain the advantages of, the Kalman Filter while being feasible to implement in real time control computers. Most of the advantage of using the Kalman Filter comes from its ability to predict the wind blown turbulence for the next measurement step. For the photonic and instrumentation noise levels commonly found in astronomical AO systems, we find that most of the Strehl gain is achieved by simply translating the wavefront estimate the incremental distance.
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Previous experimental measurements and theoretical modelling indicate that atmospheric turbulence is expected
to show intermittency (or "clumpiness"). The impact that this intermittency has on simulated adaptive
optics (AO) and Lucky Imaging (LI) performance is assessed in this SPIE contribution using simulated phase
screens with Von Karman power spectra which incorporate turbulent intermittency. The statistics of the intermittency
model used are based as closely as possible on astronomical seeing measurements at real observatories.
The performance of realistic AO correction of large Taylor screens with intermittent turbulence is compared
directly with the performance given with traditional Gaussian random Taylor screens having the same Von
Karman power spectrum. Also discussed is the improvement in performance which can be obtained by modifying
the AO control parameters in response to the changing seeing conditions. Lucky Imaging simulations
indicate that the performance of this method can be significantly improved under intermittent seeing.
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In this paper we present a new stochastic model for time-varying turbulence. The model can be viewed as a linearization of the Navier-Stokes equation, with deterministic drift and diffusion terms, plus an additional stochastic driving term. Fixed-time realizations of the model have Kolmogorov statistics, but the diffusion and stochastic driving terms yield "boiling" behavior that is different from the Taylor frozen flow model.
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The image quality obtained using laser guide star adaptive optics (LGS AO) is degraded by the fact that the
wavefront aberrations experienced by light from the LGS and from the science object differ. In this paper we
derive an analytic expression for the variance of the difference between the two wavefronts as a function of angular
distance between the LGS and the science object. This error is a combination of focal anisoplanatism and angular
anisoplanatism. We show that the wavefront error introduced by observing a science object displaced from the
guide star is smaller for LGS AO systems than for natural guide star AO systems.
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A Monte Carlo sky coverage model for laser guide star adaptive optics systems is presented. This model provides
fast Monte Carlo simulations of the tip/tilt (TT) wavefront error calculated with minimum variance estimators
over natural guide star constellations generated from star models. With this simulation code we are able to
generate a TT error budget for the Thirty Metre Telescope (TMT) facility Narrow Field Infra-Red Adaptive
Optics System (NFIRAOS), and perform several design trade studies. With the current NFIRAOS design, the
median TT error at the galactic pole with median seeing is calculated to be 65 nm or 1.8 mas.
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A point source deconvolution technique is described that models the effects of anisoplanatism on the adaptive optics point spread function. This technique is used in the analysis of a quadruple system observed using the Palomar Adaptive Optics system on the Hale 5 meter telescope. Two members of this system reside in a .1 asec double. Deconvolution of this close double was performed using the PSF of a third member of the system, which was offset from the double by 12 asec. Incorporation of anisoplanatism into the deconvolution procedure requires knowledge of the turbulence profile, which was measured at the time of these observations using a DIMM/MASS unit at Palomar Observatory.
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In this article we summarize the parameter space exploration for several adaptive optics systems for a 42-m
European Extremely Large Telescope. These systems are modular, and based on a various number of identical
high order wavefront sensor. We explore a single natural guide star single conjugate AO and multi-laser guide
star systems: ground-layer AO, laser-tomography AO, and multi-conjugate AO. The performance estimates are
given in terms of Strehl ratio or, for the GLAO system in terms of ensquared energy.
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This paper describes wave-optics Monte Carlo simulation results to asses the impact of laser guide star wavefront
sensor nonlinearity with elongated sodium beacons on the residual wavefront error for the Thirty Meter Telescope
Narrow Field InfraRed Adaptive Optics System, which is a laser guide star multi-conjugate adaptive optics
system intended to provide near-diffraction limited performance in the near infrared over a 30 arcsec diameter
field of view.
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Results of numerical simulations of the performance of GLAS (Ground-layer Laser Adaptive optics System) are
presented. GLAS uses a Rayleigh laser guide star (LGS) created at a nominal distance of 20km from the 4.2m William
Herschel Telescope primary aperture and a semi-analytical model has been used to determine the observed LGS
properties. GLAS is primarily intended for use with the OASIS spectrograph working at visible wavelengths although a
wider-field IR imaging camera can also use the AO corrected output. Image quality metrics relating to scientific
performance for each instrument are used showing that the energy inside every OASIS lenslet across the 10" instrument
FOV is approximately doubled, irrespective of atmospheric conditions or wavelength of observation.
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This paper presents an equivalent discrete-time model that combines the D-A converter, DM, and WFS. The
performance of the adaptive optics loop can then be evaluated in terms of the discrete-time (Z) closed-loop transfer
functions of the feedback loop. The closed-loop transfer functions using this discrete-time model are compared to those
obtained from an analog model. A simulation shows that the digital model produces accurate stability evaluations.
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Numerical Simulation is an essential part of the design and optimisation of astronomical adaptive optics systems. Simulations of adaptive optics are computationally expensive and the problem scales rapidly with telescope aperture size, as the required spatial order of the correcting system increases. Practical realistic simulations of AO systems for extremely large telescopes are beyond the capabilities of all but the largest of modern parallel supercomputers. Here we describe a more cost effective approach through the use of hardware acceleration using field programmable gate arrays. By transferring key parts of the simulation into programmable logic, large increases in computational bandwidth can be expected. We show that the calculation of wavefront sensor images (involving a 2D FFT, photon shot noise addition, background and readout noise), and centroid calculation can be accelerated by factor of 400 times when the algorithms are transferred into hardware. We also provide details about the simulation platform and framework that we have developed at Durham.
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