Space Telescopes and Instrumentation 2018: Optical, Infrared, and Millimeter Wave 2018
DOI: 10.1117/12.2314368
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Phase-retrieval-based wavefront metrology for high contrast coronagraphy

Abstract: We discuss the use of parametric phase-diverse phase retrieval as an in-situ high-fidelity wavefront measurement method to characterize and optimize the transmitted wavefront of a high-contrast coronagraphic instrument. We apply our method to correct the transmitted wavefront of the HiCAT (High contrast imager for Complex Aperture Telescopes) coronagraphic testbed. This correction requires a series of calibration steps, which we describe. The correction improves the system wavefront from 16 nm RMS to 3.0 nm RM… Show more

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Cited by 8 publications
(8 citation statements)
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“…To shape the wavefront, HiCAT uses two continuous Boston kilo-DMs: DM1 in a pupil plane and DM2 out of a pupil plane to allow both phase and amplitude control. A prior calibration of HiCAT was performed to experimentally produce DM flat commands (or 'flat maps') that minimize the number of static aberrations on the testbed (Brady et al 2018). HiCAT also uses both of these DMs to further reject starlight and enhance the contrast in a given region of the coronagraphic image using DH optimization algorithms.…”
Section: Experimental Setup On Hicatmentioning
confidence: 99%
“…To shape the wavefront, HiCAT uses two continuous Boston kilo-DMs: DM1 in a pupil plane and DM2 out of a pupil plane to allow both phase and amplitude control. A prior calibration of HiCAT was performed to experimentally produce DM flat commands (or 'flat maps') that minimize the number of static aberrations on the testbed (Brady et al 2018). HiCAT also uses both of these DMs to further reject starlight and enhance the contrast in a given region of the coronagraphic image using DH optimization algorithms.…”
Section: Experimental Setup On Hicatmentioning
confidence: 99%
“…The testbed is calibrated to a final wavefront error of the order of 1 nm rms using the phase retrieval camera, which is used to measure the wavefront at a focal-plane mask (FPM) proxy location by introducing a high-quality flat mirror into the beam. 12 We have since then also implemented a dOTF calibration (differential Optical Transfer Function), 13 which is simpler operationally (E. Por, in prep). The dOTF calibration combines an image with a flat wavefront with an image where one of the Boston DM actuators is poked near the edge of the projected pupil to retrieve the complex amplitude of the pupil plane.…”
Section: Testbed Descriptionmentioning
confidence: 99%
“…The phase retrieval camera can be used to measure the wavefront at a focal plane mask (FPM) proxy location by introducing a high-quality flat mirror into the beam. 27,28 A Zernike wavefront sensor has been assembled as part of the low-order wavefront sensor, using the light rejected by the FPM. 29…”
Section: The Hicat Projectmentioning
confidence: 99%