Dr. Bijan Nemati Profile

Dr. Bijan Nemati

Principal Research Scientist at Tellus1 Scientific LLC

SPIE Involvement:

Author

Area of Expertise:

Interferometry , Metrology , Astrometry , Synthetic Tracking , Coronagraphy , Inverse Synthetic Aperture LIDAR

Profile Summary

Bijan Nemati is a senior engineer at JPL's advanced optics section. He received his Ph.D. in experimental particle physics from the University of Washington. His post-doctoral research was in the area of characterizing the decay properties of particles with the charm quark. Since 1997 he has been working on advanced optical instruments, first at Lockheed Martin and later at JPL. He developed technology for picometer-class optical truss metrology to be used for astrometric space instruments. He also co-developed the technique Synthetic Tracking for detecting very small, fast asteroids from the ground. He is currently the integrated modeling lead for the WFIRST AFTA coronagraph, scheduled to be launched in 2024.

Publications (89)

Proceedings Article | 1 October 2024 Presentation + Paper

GMT adaptive optics test camera: conceptual optical design

Tiago G. B. de Souza, Antonin Bouchez, Rafael A. Ribeiro, Tárcio Vieira, Bijan Nemati, Richard Demers

Proceedings Volume 13129, 1312905 (2024) https://doi.org/10.1117/12.3035469

KEYWORDS: Cameras, Adaptive optics, Sensors, Targeting Task Performance metric, Optical design, Design, Wavefront sensors

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Proceedings Article | 1 October 2024 Presentation + Paper

Mirror surface contamination specification derived from coronagraphy scatter error budget allocation

H. Philip Stahl, David Smith, Bijan Nemati

Proceedings Volume 13129, 1312906 (2024) https://doi.org/10.1117/12.3028546

KEYWORDS: Coronagraphy, Bidirectional reflectance transmission function, Optical surfaces, Particles, Contamination, Mirror surfaces, Mirrors, Wavefronts, Scattered light, Wavefront errors

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SPIE Journal Paper | 20 September 2024 Open Access

Current laboratory performance of starlight suppression systems and potential pathways to desired Habitable Worlds Observatory exoplanet science capabilities

Bertrand Mennesson, Ruslan Belikov, Emiel Por, Eugene Serabyn, Garreth Ruane, A. J. Eldorado Riggs, Dan Sirbu, Laurent Pueyo, Rémi Soummer, Jeremy Kasdin, Stuart Shaklan, Byoung-Joon Seo, Christopher Stark, Eric Cady, Pin Chen, Brendan Crill, Kevin Fogarty, Alexandra Greenbaum, Olivier Guyon, Roser Juanola-Parramon, Brian Kern, John Krist, Bruce Macintosh, David Marx, Dimitri Mawet, Camilo Mejia Prada, Rhonda Morgan, Bijan Nemati, Leonid Pogorelyuk, Susan Redmond, Sara Seager, Nicholas Siegler, Karl Stapelfeldt, Sarah Steiger, John Trauger, James Wallace, Marie Ygouf, Neil Zimmerman

JATIS, Vol. 10, Issue 03, 035004, (September 2024) https://doi.org/10.1117/12.10.1117/1.JATIS.10.3.035004

KEYWORDS: Coronagraphy, Planets, Signal to noise ratio, Telescopes, Point spread functions, Stars, Exoplanets, Wavefronts, Spectroscopy, Design

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We summarize the current best polychromatic (∼10% to 20% bandwidth) contrast performance demonstrated in the laboratory by different starlight suppression approaches and systems designed to directly characterize exoplanets around nearby stars. We present results obtained by internal coronagraph and external starshade experimental testbeds using entrance apertures equivalent to off-axis or on-axis telescopes, either monolithic or segmented. For a given angular separation and spectral bandwidth, the performance of each starlight suppression system is characterized by the values of “raw” contrast (before image processing), off-axis (exoplanet) core throughput, and post-calibration contrast (the final 1-sigma detection limit of off-axis point sources, after image processing). Together, the first two parameters set the minimum exposure time required for observations of exoplanets at a given signal-to-noise, i.e., assuming perfect subtraction of background residuals down to the photon noise limit. In practice, residual starlight speckle fluctuations during the exposure will not be perfectly estimated nor subtracted, resulting in a finite post-calibrated contrast and exoplanet detection limit whatever the exposure time. To place the current laboratory results in the perspective of the future Habitable Worlds Observatory (HWO) mission, we simulate visible observations of a fiducial Earth/Sun twin system at 12 pc, assuming a 6 m (inscribed diameter) collecting aperture and a realistic end-to-end optical throughput. The exposure times required for broadband exo-Earth detection (20% bandwidth around λ=0.55 μm) and visible spectroscopic observations (R=70) are then computed assuming various levels of starlight suppression performance, including the values currently demonstrated in the laboratory. Using spectroscopic exposure time as a simple metric, our results point to key starlight suppression system design performance improvements and trades to be conducted in support of HWO’s exoplanet science capabilities. These trades may be explored via numerical studies, lab experiments, and high-contrast space-based observations and demonstrations.

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Proceedings Article | 11 September 2024 Presentation + Paper

Development of the GMT telescope metrology system

Bo Xin, Bijan Nemati, Richard Demers, Patricio Schurter, Hugo Chiquito, William Schoenell, Josema Filgueira, Juan Pablo Haddad, Peter Thompson, Keath Beifus, Antonin Bouchez, Breann Sitarski, Joel Nissen, Heejoo Choi, Guillermo Gonzalez, David Nemati, Peter Williams

Proceedings Volume 13094, 1309424 (2024) https://doi.org/10.1117/12.3020638

KEYWORDS: Retroreflectors, Telescopes, Collimators, Design, Optical alignment, Wavefront sensors, Metrology, Mirrors, Wavefront errors

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Proceedings Article | 27 August 2024 Presentation + Paper

Adaptive optics development at the Giant Magellan Telescope: recent progress

Richard Demers, Fernando Quiros-Pacheco, Patricio Schurter, Bo Xin, Juan Pablo Haddad, Jordi Molgo, William Schoenell, Rod Conan, Rodrigo Romano, Antonin Bouchez, Marcos van Dam, Dan Catropa, Jan Kansky, Brian McLeod, Stuart McMuldroch, William Podgorski, Mark Witinski, Laird Close, Victor Gasho, Sebastiaan Haffert, Alex Hedglen, Maggie Kautz, Jared Males, Cédric Plantet, Alfio Puglisi, Fabio Rossi, Anne-Laure Cheffot, Nicolò Azzaroli, Luca Carbonaro, Tommaso Lapucci, Enrico Pinna, Simone Esposito, Celine D'Orgeville, Noelia Martinez Rey, Tony Travouillon, Bijan Nemati, Guillermo Gonzalez, Joel Nissen

Proceedings Volume 13097, 1309723 (2024) https://doi.org/10.1117/12.3020271

KEYWORDS: Adaptive optics, Telescopes, Wavefront sensors, Wavefronts, Wavefront errors, Sensors, Cameras, Turbulence, Stars, Calibration

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Proceedings Article | 23 August 2024 Poster + Paper

A parameter scan of dark zone maintenance for high-contrast imaging of exoplanets using theoretical and experimental implementations

Saikrishna Manojkumar, Christine Page, Leonid Pogorelyuk, Susan Redmond, Ajay Gill, Laurent Pueyo, Emiel Por, Iva Laginja, Raphael Pourcelot, Bryony Nickson, Ananya Sahoo, Meiji Nguyen, Rémi Soummer, Marshall Perrin, Bijan Nemati, Kerri Cahoy, Jeremy Kasdin

Proceedings Volume 13092, 1309269 (2024) https://doi.org/10.1117/12.3019008

KEYWORDS: Wavefronts, Wavefront sensors, Coronagraphy, Simulations, Electric fields, Cameras, Space telescopes, Signal to noise ratio, Exoplanets, Stars, Equipment, Imaging systems

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Proceedings Article | 23 August 2024 Poster + Paper

Leveraging the Roman coronagraph approach for the HWO error budget

Bijan Nemati, H. Philip Stahl

Proceedings Volume 13092, 130925J (2024) https://doi.org/10.1117/12.3021198

KEYWORDS: Signal to noise ratio, Planets, Speckle, Coronagraphy, Spectroscopy, Stars, Wavefronts, Exoplanets, Calibration, Point spread functions

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Proceedings Article | 23 August 2024 Poster + Paper

Impact of near-angle scatter on exo-Earth coronagraphy

H. Philip Stahl, David Smith, Bijan Nemati

Proceedings Volume 13092, 1309265 (2024) https://doi.org/10.1117/12.3021201

KEYWORDS: Optical surfaces, Coronagraphy, Mirrors, Bidirectional reflectance transmission function, Spatial frequencies, Mirror surfaces, Stars, Point spread functions, Wavefronts, Surface finishing

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Proceedings Article | 18 July 2024 Presentation + Paper

Science instruments for the Giant Magellan Telescope

R. Millan-Gabet, G. Rahmer, R. Bernstein, A. Souza, W. Schoenell, R. Demers, A. Szentgyorgyi, D. Fabricant, R. A. Ribeiro, R. Sharp, D. Jaffe, S. Lee, J. Lawrence, J. Crane, J. Males, B. Nemati

Proceedings Volume 13096, 130960X (2024) https://doi.org/10.1117/12.3019234

KEYWORDS: Equipment, Spectrographs, Design, Telescopes, Adaptive optics, Spectral resolution, Cameras, Stars, Imaging systems, Wavefront sensors

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SPIE Journal Paper | 11 October 2023 Open Access

End-to-end numerical modeling of the Roman Space Telescope coronagraph

John Krist, John Steeves, Brandon Dube, A.J. Eldorado Riggs, Brian Kern, David Marx, Eric Cady, Hanying Zhou, Ilya Poberezhskiy, Caleb Baker, James McGuire, Bijan Nemati, Gary Kuan, Bertrand Mennesson, John Trauger, Navtej Saini, Sergi Hildebrandt Rafels

JATIS, Vol. 9, Issue 04, 045002, (October 2023) https://doi.org/10.1117/12.10.1117/1.JATIS.9.4.045002

KEYWORDS: Coronagraphy, Actuators, Space telescopes, Numerical modeling, Wavefronts, Modeling, Stars, Monochromatic aberrations, Polarization, Simulations

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SPIE Journal Paper | 27 September 2023

Analytical performance model and error budget for the Roman coronagraph instrument

Bijan Nemati, John Krist, Ilya Poberezhskiy, Brian Kern

JATIS, Vol. 9, Issue 03, 034007, (September 2023) https://doi.org/10.1117/12.10.1117/1.JATIS.9.3.034007

KEYWORDS: Stars, Analytic models, Planets, Error analysis, Coronagraphy, Sensors, Performance modeling, Speckle, Signal to noise ratio, Calibration

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The Nancy Grace Roman Space Telescope (“Roman”), under development by NASA, will investigate possible causes for the phenomenon of dark energy and detect and characterize extrasolar planets. The 2.4 m space telescope has two main instruments: a wide-field, infrared imager and a coronagraph. The coronagraph instrument (CGI) is a technology demonstrator designed to help bridge the gap between the current state-of-the-art space and ground instruments and future high-contrast space coronagraphs that will be capable of detecting and characterizing Earth-like planets in the habitable zones of other stars. Using adaptive optics, including two high-density deformable mirrors and low- and high-order wavefront sensing and control, CGI is designed to suppress the star light by up to nine orders of magnitude, potentially enabling the direct detection and characterization of Jupiter-class exoplanets. Contrast is the measure of starlight suppression, and high contrast is the chief virtue of a coronagraph. But it is not the only important characteristic: contrast must be balanced against acceptance of planet light. The remaining unsuppressed starlight must also have a stable morphology to allow further estimation and subtraction. To achieve all these goals in the presence of the disturbance and radiation environment of space, the coronagraph must be designed and fabricated as a highly optimized system. The CGI error budget is the top-level tool used to guide the optimization, enabling trades of various competing errors. The error budget is based on an analytical model, which enables rapid calculation and tracking of performance for the numerous and diverse questions that arise in the system engineering process. We outline the coronagraph system engineering approach and the error budget. We then describe in detail the analytical model for direct imaging and spectroscopy and show how it connects to the error budget. We introduce a number of useful ancillary metrics that provide insight into the capabilities of the instrument. Since models always need to be validated, we describe the validation approach for the CGI analytical model.

SPIE Journal Paper | 19 March 2023 Open Access

Flight photon counting electron multiplying charge coupled device development for the Roman Space Telescope coronagraph instrument

Patrick Morrissey, Leon Harding, Nathan Bush, Michael Bottom, Bijan Nemati, Andrew Daniel, Bongim Jun, Luz Maria Martinez-Sierra, Niyati Desai, Dave Barry, Rhonda-Topaz Davis, Richard Demers, David Hall, Andrew Holland, Pete Turner, Brian Shortt

JATIS, Vol. 9, Issue 01, 016003, (March 2023) https://doi.org/10.1117/12.10.1117/1.JATIS.9.1.016003

KEYWORDS: Electron multiplying charge coupled devices, Design and modelling, Photon counting, Sensors, Cameras, Dark current, Imaging systems, Quantum efficiency, Tunable filters, Image sensors

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We describe the development of flight electron multiplying charge coupled devices (EMCCDs) for the photon-counting camera system of a coronagraph instrument (CGI) to be flown on the 2.4-m Nancy Grace Roman Space Telescope. Roman is a NASA flagship mission that will study dark energy and dark matter, and search for exoplanets with a planned launch in the mid-2020s. The CGI is intended to demonstrate technologies required for high-contrast imaging and spectroscopy of exoplanets, such as high-speed wavefront sensing and pointing control, adaptive optics with deformable mirrors, and ultralow noise signal detection with photon counting, visible-sensitive (350 to 950 nm) detectors. The camera system is at the heart of these demonstrations and is required to sense both faint and bright targets (10 − 4 − 107 counts-s − 1) adaptively at up to 1000 frames-s − 1 to provide the necessary feedback to the instrument control loops. The system includes two identical cameras, one to demonstrate faint light scientific capability, and the other to provide high-speed real-time sensing of instrument pointing disturbances. Our program at the Jet Propulsion Laboratory (Pasadena, California, United States) has evaluated the low-signal performance of radiation-damaged commercial EMCCD sensors and used those measurements as a basis for targeted radiation hardening modifications developed in partnership with the Open University (Milton Keynes, United Kingdom) and Teledyne-e2v (Chelmsford, United Kingdom). A pair of EMCCDs with test features was then developed and their low signal performance is reported here. The program has resulted in the development of a flight version of the EMCCD with low signal performance improved by more than a factor of three over the commercial one after exposure to 2.6 × 109 protons-cm − 2 (10 MeV equivalent). The flight EMCCD sensors are contributed by ESA through a contract with Teledyne-e2v (Chelmsford, United Kingdom). We will describe the program requirements, sensor design, test results and metrics used to evaluate photon counting performance.

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Proceedings Article | 30 August 2022 Presentation + Paper

Phasing the segmented Giant Magellan Telescope: progress in testbeds and prototypes

Richard Demers, Antonin Bouchez, Fernando Quiros-Pacheco, Patricio Schurter, Breann Sitarski, Marcos van Dam, Dan Catropa, Jan Kansky, Brian McLeod, Stuart McMuldroch, Bill Podgorski, Laird Close, Victor Gasho, Sebastiaan Haffert, Alex Hedglen, Maggie Kautz, Jared Males, Guido Agapito, Nicolò Azzaroli, Luca Carbonaro, Anne-Laure Cheffot, Simone Esposito, Tommaso Lapucci, Enrico Pinna, Cédric Plantet, Alfio Puglisi, Fabio Rossi, Guillermo Gonzalez, Bijan Nemati

Proceedings Volume 12185, 1218518 (2022) https://doi.org/10.1117/12.2630144

KEYWORDS: Prototyping, Wavefronts, Wavefront sensors, Telescopes, Sensors, Image segmentation, Adaptive optics, Device simulation, Stars, Cameras

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Proceedings Article | 29 August 2022 Presentation + Paper

The wide field phasing testbed for the Giant Magellan Telescope

Brian McLeod, Antonin Bouchez, Daniel Catropa, Peyton Benac, Daniel Durusky, Jan Kansky, Derek Kopon, Grant Meiners, Stuart McMuldroch, William Podgorski, Richard Demers, Fernando Quiros-Pacheco, William Schoenell, Patricio Schurter, Breann Sitarski, Guillermo Gonzalez, Bijan Nemati, Diogo Slepetys

Proceedings Volume 12182, 1218208 (2022) https://doi.org/10.1117/12.2630588

KEYWORDS: Mirrors, Wavefronts, Wavefront sensors, Telescopes, Relays, Prototyping, Sensors, Deformable mirrors, Actuators, Prisms

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Proceedings Article | 29 August 2022 Presentation + Paper

The GMT telescope metrology system design

Breann Sitarski, Andrew Rakich, Hugo Chiquito, Wylie Rosenthal, Antonin Bouchez, William Schoenell, Bo Xin, Priscila Pires, Joel Nissen, P. Schurter, Richard Demers, Peter Thompson, Brian McLeod, Bijan Nemati, Glenn Brossus, Brian Walls, Heejoo Choi, Guillermo Gonzalez, David Nemati

Proceedings Volume 12182, 1218207 (2022) https://doi.org/10.1117/12.2630598

KEYWORDS: Mirrors, Retroreflectors, Sensors, Telescopes, Error analysis, Collimators, Prototyping, Metrology, Laser metrology

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Proceedings Article | 27 August 2022 Presentation + Paper

Nancy Grace Roman Space Telescope coronagraph instrument observation calibration plan

Robert Zellem, Bijan Nemati, Guillermo Gonzalez, Marie Ygouf, Vanessa Bailey, Eric Cady, M. Mark Colavita, Sergi Hildebrandt, Erin Maier, Bertrand Mennesson, Lindsey Payne, Neil Zimmerman, Ruslan Belikov, Robert De Rosa, John Debes, Ewan Douglas, Julien Girard, Tyler Groff, Jeremy Kasdin, Patrick Lowrance, Bruce Macintosh, Daniel Ryan, Carey Weisberg

Proceedings Volume 12180, 121801Z (2022) https://doi.org/10.1117/12.2627567

KEYWORDS: Calibration, Stars, Coronagraphy, Planets, Sensors, Polarization, Point spread functions, Error analysis, Signal to noise ratio, Uranus

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Proceedings Article | 27 August 2022 Presentation + Paper

The Roman Space Telescope coronagraph technology demonstration: current status and relevance to future missions

B. Mennesson, V. Bailey, R. Zellem, S. Hildebrandt, M. Ygouf, J. Rhodes, N. Zimmerman, B. Nemati, G. Gonzalez, E. Cady, B. Kern, T. Koch, J. Krist, K. Heydorff, T. Luchik, F. Mok, P. Morrissey, I. Poberezhskiy, A. Riggs, F. Shi, F. Zhao, R. Akeson, L. Armus, A. Greenbaum, J. Ingalls, P. Lowrance

Proceedings Volume 12180, 121801W (2022) https://doi.org/10.1117/12.2629176

KEYWORDS: Coronagraphy, Wavefront sensors, Electron multiplying charge coupled devices, Imaging spectroscopy, Wavefronts, Stars, Spectroscopy, Performance modeling, Cameras, Observatories

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Proceedings Article | 27 August 2022 Presentation + Paper

Roman coronagraph instrument: engineering overview and status

Ilya Poberezhskiy, Kathryn Heydorff, Thomas Luchik, Feng Zhao, Eric Cady, Gasia Bedrosian, Mark Colavita, Brandon Creager, Renaud Goullioud, Tyler Groff, Amanda Grue, Brian Monacelli, Patrick Morrissey, Joshua Kempenaar, Brian Kern, Matthew King, Timothy Koch, John Krist, Gary Kuan, Jonathan Lam, Dorothy Lewis, Fai Mok, David Muliere, Bijan Nemati, Charley Noecker, Jeffrey Oseas, A.J. Riggs, Fang Shi, Belinda Shreckengost

Proceedings Volume 12180, 121801X (2022) https://doi.org/10.1117/12.2630540

KEYWORDS: Coronagraphy, Electronics, Cameras, Interfaces, Mirrors, Control systems, Optical alignment, Observatories, Space operations, Optical benches

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SPIE Journal Paper | 16 March 2022

Dark hole maintenance with modal pairwise probing in numerical simulations of Roman coronagraph instrument

Leonid Pogorelyuk, John Krist, Bijan Nemati, A. J. Eldorado Riggs, Sam Miller, Laurent Pueyo, N. Jeremy Kasdin, Kerri Cahoy

JATIS, Vol. 8, Issue 01, 019002, (March 2022) https://doi.org/10.1117/12.10.1117/1.JATIS.8.1.019002

KEYWORDS: Stars, Wavefronts, Numerical simulations, Sensors, Coronagraphy, Error analysis, Telescopes, Polarization, Electron multiplying charge coupled devices, Speckle

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We propose an efficient approach for focal-plane wavefront estimation for high-contrast imaging. It is designed for very low photon flux regimes with the Roman Space Telescope Coronagraph Instrument in mind. During days-long exposures of Roman, the starlight wavefront will drift due to the thermal instabilities of the optical tube assembly (OTA) and deformable mirror (DM) actuators. To correct the drift in high-order spatial wavefront modes, Roman will periodically be pointed to a bright reference star to sense the speckles in the dark hole (the high-contrast region of the image) and correct them. However, this maneuver decreases observation time by several hours a day and may lead to wavefront instability by causing structural and thermal stresses on the OTA. Instead, we propose maintaining the dark hole using the DM to modulate (probe) the speckles while observing the target star. Our proposed algorithm can then be used to directly estimate the DM commands that would create such speckles, rather than first estimating the electric field of the speckles. Applying the opposite commands on the DM reduces the intensity of the speckles without slewing to the reference star. Further, we analyze this dark-hole maintenance approach using data from Roman Observing Scenario 9 (OS9) simulations while assuming that the high-order wavefront control on Roman will be carried out from the Earth (ground-in-the-loop). In our simulations of Roman’s Hybrid Lyot Coronagraph, the high-order wavefront errors were sensed and corrected while observing a dim target, 47 UMa. Despite the DM probes, the photon flux in the dark hole remained close to that in OS9 and well below detector noise. In terms of planet-detectability, dark hole maintenance kept the post-processing contrast within 10% of OS9’s, even after pointing the telescope at the target star for 6 days. The OTA stability that dark hole maintenance provides compared to slewing the telescope potentially outweighs the small negative impact it has on the contrast.

Proceedings Article | 1 September 2021 Presentation + Paper

The Roman Space Telescope coronagraph technology demonstration: current status and relevance to future missions

B. Mennesson, V. P. Bailey, R. Zellem, N. Zimmerman, M. Ygouf, S. Hildebrandt, J. Rhodes, J. Kasdin, B. Macintosh, M. Turnbull, E. Douglas, A. Mandell, B. Nemati, G. Gonzalez, E. Cady, B. Kern, J. Krist, F. Shi, F. Mok, P. Morrissey, K. Heydorff, I. Pobereszhskiy, F. Zhao, T. Luchik, E. Maier, R. Akeson, L. Armus, J. Ingalls, P. Lowrance, T. Meshkat

Proceedings Volume 11823, 1182310 (2021) https://doi.org/10.1117/12.2603343

KEYWORDS: Coronagraphy, Electron multiplying charge coupled devices, Wavefront sensors, Cameras, Wavefronts, Imaging spectroscopy, Stars, Imaging systems, Spectroscopy, Polarimetry

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Proceedings Article | 5 August 2021 Presentation

Numerical Simulation of Dark Hole Maintenance and its Impact on Planet Detection for Roman Coronagraph Instrument Based on OS 9

Leonid Pogorelyuk, John Krist, Bijan Nemati, A. J. Riggs, Sam Miller, Laurent Pueyo, Jeremy Kasdin, Kerri Cahoy

Proceedings Volume 11823, 118230Z (2021) https://doi.org/10.1117/12.2594679

KEYWORDS: Wavefronts, Planets, Numerical simulations, Telescopes, Actuators, Wavefront sensors, Thermography, Stars, Space telescopes, Sensors

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Proceedings Article | 12 January 2021 Presentation + Paper

Roman space telescope coronagraph: engineering design and operating concept

Ilya Poberezhskiy, Thomas Luchik, Feng Zhao, Margaret Frerking, Scott Basinger, Eric Cady, M. Mark Colavita, Brandon Creager, Nanaz Fathpour, Renaud Goullioud, Tyler Groff, Patrick Morrissey, Joshua Kempenaar, Brian Kern, Timothy Koch, John Krist, Fai Mok, David Muliere, Bijan Nemati, A.J. Riggs, Byoung-Joon Seo, Fang Shi, Belinda Shreckengost, John Steeves, Hong Tang

Proceedings Volume 11443, 114431V (2021) https://doi.org/10.1117/12.2563480

KEYWORDS: Infrared telescopes, James Webb Space Telescope, Telescopes, Coronagraphy, Infrared radiation, Instrumentation engineering, Optical instrument design, Wavefronts, Imaging spectroscopy, Infrared imaging

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Proceedings Article | 16 December 2020 Poster + Paper

A review of simulation and performance modeling tools for the Roman coronagraph instrument

Ewan Douglas, Jaren Ashcraft, Ruslan Belikov, John Debes, Jeremy Kasdin, John Krist, Brianna Lacy, Bijan Nemati, Kian Milani, Leonid Pogorelyuk, A.J. Eldorado Riggs, Dmitry Savransky, Dan Sirbu

Proceedings Volume 11443, 1144338 (2020) https://doi.org/10.1117/12.2561960

KEYWORDS: Device simulation, Coronagraphy, Performance modeling, Exoplanets, Aerospace engineering, Diffraction, Instrument modeling, Speckle, Signal to noise ratio

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Proceedings Article | 15 December 2020 Presentation + Paper

The Nancy Grace Roman Space Telescope Coronagraph Instrument (CGI) technology demonstration

N. Jeremy Kasdin, Vanessa Bailey, Bertrand Mennesson, Robert Zellem, Marie Ygouf, Jason Rhodes, Thomas Luchik, Feng Zhao, A. J. Eldorado Riggs, Byoung-Joon Seo, John Krist, Brian Kern, Hong Tang, Bijan Nemati, Tyler Groff, Neil Zimmerman, Bruce Macintosh, Margaret Turnbull, John Debes, Ewan Douglas, Roxana Lupu

Proceedings Volume 11443, 114431U (2020) https://doi.org/10.1117/12.2562997

KEYWORDS: Coronagraphy, Imaging spectroscopy, Planets, Infrared telescopes, James Webb Space Telescope, Imaging systems, Wavefronts, Algorithm development, Jupiter, Infrared radiation

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Proceedings Article | 13 December 2020 Poster + Paper

Photon counting and precision photometry for the Roman Space Telescope Coronagraph

Bijan Nemati

Proceedings Volume 11443, 114435F (2020) https://doi.org/10.1117/12.2575983

KEYWORDS: Photon counting, Coronagraphy, Photometry, Electrons, Planets, Sensors, Stochastic processes, Space telescopes, Jupiter, Signal detection

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Proceedings Article | 13 December 2020 Presentation + Paper

The Micro-arcsecond Astrometry Small Satellite: MASS

Bijan Nemati, Michael Shao, Guillermo Gonzalez, Chengxing Zhai, Scott Miskovish, Patrick Reardon, Michael Graves, Kurt Knutson, Eduardo Bendek, Inseob Hahn

Proceedings Volume 11443, 114430O (2020) https://doi.org/10.1117/12.2574986

KEYWORDS: Satellites, Planets, Stars, Exoplanets, Solar system, Space telescopes, Distortion, Calibration, Mirrors, CMOS sensors

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Proceedings Article | 13 December 2020 Presentation + Paper

Deriving telescope Wavefront Error (WFE) stability error budget from coronagraph performance

H. Philip Stahl, Bijan Nemati, Mark Stahl

Proceedings Volume 11450, 114502Z (2020) https://doi.org/10.1117/12.2562818

KEYWORDS: Coronagraphy, Telescopes, Exoplanets, Wavefronts, Spectroscopy, Optical telescopes, Systems engineering, Zernike polynomials

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SPIE Journal Paper | 18 August 2020 Open Access

Method for deriving optical telescope performance specifications for Earth-detecting coronagraphs

Bijan Nemati, H. Philip Stahl, Mark Stahl, Garreth J. Ruane, Leah Sheldon

JATIS, Vol. 6, Issue 03, 039002, (August 2020) https://doi.org/10.1117/12.10.1117/1.JATIS.6.3.039002

KEYWORDS: Coronagraphy, Telescopes, Signal to noise ratio, Stars, Planets, Speckle, Wavefronts, Optical telescopes, Sensors

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Proceedings Article | 9 September 2019 Presentation + Paper

WFIRST Phase B HLC occulter mask baselining and testbed WFC performance validation

Hanying Zhou, John Krist, Brian Kern, Byoung-Joon Seo, Eric Cady, Bijan Nemati, Dwight Moody, A.J. Eldorado Riggs, David Marx, Daniel Wilson, Kunjithapatham Balasubramanian, Ilya Poberezhskiy, Scott Basinger

Proceedings Volume 11117, 111170H (2019) https://doi.org/10.1117/12.2530672

KEYWORDS: Wavefronts, Tolerancing, Coronagraphy, Telescopes, Performance modeling, Control systems, Mask making, Optical instrument design, Aerospace engineering, Space operations

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SPIE Journal Paper | 20 May 2019

ExoEarth yield landscape for future direct imaging space telescopes

Christopher Stark, Rus Belikov, Matthew Bolcar, Eric Cady, Brendan Crill, Steve Ertel, Tyler Groff, Sergi Hildebrandt, John Krist, P. Douglas Lisman, Johan Mazoyer, Bertrand Mennesson, Bijan Nemati, Laurent Pueyo, Bernard Rauscher, A. J. Riggs, Garreth Ruane, Stuart Shaklan, Dan Sirbu, Rémi Soummer, Kathryn St. Laurent, Neil Zimmerman

JATIS, Vol. 5, Issue 02, 024009, (May 2019) https://doi.org/10.1117/12.10.1117/1.JATIS.5.2.024009

KEYWORDS: Coronagraphy, Stars, Telescopes, Planets, Space telescopes, Optical instrument design, Point spread functions, Mirrors, Exoplanets, Sensors

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Proceedings Article | 17 September 2018 Presentation + Paper

HabEx Telescope WFE stability specification derived from coronagraph starlight leakage

Bijan Nemati, H. Philip Stahl, Mark Stahl, Garreth Ruane

Proceedings Volume 10743, 107430G (2018) https://doi.org/10.1117/12.2312662

KEYWORDS: Coronagraphy, Telescopes, Signal to noise ratio, Speckle, James Webb Space Telescope, Planets, Wavefronts, Stars, Point spread functions, Mirrors

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Proceedings Article | 1 August 2018 Presentation + Paper

The WFIRST coronagraph instrument: a major step in the exploration of sun-like planetary systems via direct imaging

Bertrand Mennesson, J. Debes, E. Douglas, B. Nemati, C. Stark, J. Kasdin, B. Macintosh, M. Turnbull, M. Rizzo, A. Roberge, N. Zimmerman, K. Cahoy, J. Krist, V. Bailey, J. Trauger, J. Rhodes, L. Moustakas, M. Frerking, F. Zhao, I. Poberezhskiy, R. Demers

Proceedings Volume 10698, 106982I (2018) https://doi.org/10.1117/12.2313861

KEYWORDS: Stars, Coronagraphy, Planets, Imaging systems, Solar system, Clouds, Spatial resolution, Mid-IR, Visible radiation, Exoplanets

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Proceedings Article | 10 July 2018 Presentation

Photon counting EMCCD developments for the WFIRST coronagraph (Conference Presentation)

Patrick Morrissey, Leon Harding, Michael Bottom, Rick Demers, Bobby Effinger, Don Nieraeth, Larry Hovland, Yuki Maruyama, Bijan Nemati, Nathan Bush, David Hall, Ross Burgon, Andrew Holland

Proceedings Volume 10709, 107090B (2018) https://doi.org/10.1117/12.2309387

KEYWORDS: Electron multiplying charge coupled devices, Coronagraphy, Photon counting, Sensors, Planets, Cameras, CCD cameras, Exoplanets, Imaging technologies, Stars

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Proceedings Article | 6 July 2018 Presentation + Paper

WFIRST coronagraph detector trap modeling results and improvements

Robert Effinger, Bijan Nemati, Maxime Rizzo, Patrick Morrissey, Leon Harding, Michael Bottom, Donald Pontrelli, Richard Demers, Nathan Bush, David Hall, Andrew Clarke, Andrew Holland

Proceedings Volume 10709, 1070917 (2018) https://doi.org/10.1117/12.2311408

KEYWORDS: Sensors, Signal attenuation, Point spread functions, Coronagraphy, TCAD, Exoplanets, Signal detection, Charge-coupled devices, Electron multiplying charge coupled devices, Instrument modeling

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Proceedings Article | 13 April 2018 Paper

Progress towards picometer accuracy laser metrology for the space interferometry mission: update

Peter Halverson, Oscar Alvarez-Salazar, Alireza Azizi, Frank Dekens, Bijan Nemati, Feng Zhao

Proceedings Volume 10568, 105682L (2018) https://doi.org/10.1117/12.2500128

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Proceedings Article | 18 October 2017 Presentation

IMPipeline: an integrated STOP modeling pipeline for the WFIRST coronagraph (Conference Presentation)

Navtej Saini, Kevin Anderson, Zensheu Chang, Gary Gutt, Bijan Nemati

Proceedings Volume 10400, 1040008 (2017) https://doi.org/10.1117/12.2274260

KEYWORDS: Thermography, Software development, Infrared telescopes, Space telescopes, Stars, Planets, Optical analysis, Error analysis, Integrated modeling, Infrared radiation

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Proceedings Article | 19 September 2017 Presentation

Science capabilities of the WFIRST coronagraph (Conference Presentation)

Bruce Macintosh, Margaret Turnbull, N. Jeremy Kasdin, John Debes, Tom Greene, Nikole Lewis, Mark Marley, Bijan Nemati, Aki Roberge, Tyler Robinson, Dmitry Savransky, Chris Stark

Proceedings Volume 10400, 1040002 (2017) https://doi.org/10.1117/12.2276969

KEYWORDS: Exoplanets, Spectroscopes, Spectroscopy, Telescopes, Imaging systems, Spectrographs, Photometry, Planets, Imaging spectroscopy, Polarimetry

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Proceedings Article | 5 September 2017 Presentation + Paper

The effects of space telescope primary mirror segment errors on coronagraph instrument performance

Bijan Nemati, Mark Stahl, H. Philip Stahl, Stuart Shaklan

Proceedings Volume 10398, 103980G (2017) https://doi.org/10.1117/12.2273072

KEYWORDS: Coronagraphy, Planets, Telescopes, Mirrors, Space telescopes, Point spread functions, Speckle, Wavefronts

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Proceedings Article | 1 September 2017 Presentation + Paper

Sensitivity of WFIRST coronagraph broadband contrast performance to DM actuator errors

Erkin Sidick, Byoung-Joon Seo, Brian Kern, Ilya Poberezhskiy, Bijan Nemati, John Trauger

Proceedings Volume 10400, 1040006 (2017) https://doi.org/10.1117/12.2274421

KEYWORDS: Actuators, Deformable mirrors, Space telescopes, Exoplanets, Coronagraphy, Adaptive optics, Performance modeling, Wavefronts, Control systems, Interferometry

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Proceedings Article | 1 September 2017 Paper

Optimizing the regularization in broadband wavefront control algorithm for WFIRST coronagraph

Erkin Sidick, Byoung-Joon Seo, Brian Kern, David Marx, Ilya Poberezhskiy, Bijan Nemati

Proceedings Volume 10400, 1040022 (2017) https://doi.org/10.1117/12.2274440

KEYWORDS: Coronagraphy, Performance modeling, Modeling and simulation, Wavefronts, Deformable mirrors, Space telescopes, Exoplanets, Process control, Control systems, Adaptive optics

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Proceedings Article | 1 September 2017 Presentation + Paper

Electric field conjugation in the presence of model uncertainty

David Marx, Byoung-Joon Seo, Brian Kern, Erkin Sidick, Bijan Nemati, Ilya Poberezhskiy

Proceedings Volume 10400, 104000P (2017) https://doi.org/10.1117/12.2274541

KEYWORDS: Calibration, Space telescopes, Point spread functions, Imaging systems, Adaptive optics, Deformable mirrors, Infrared telescopes, Data modeling, Coronagraphy, Nonlinear optics

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Proceedings Article | 1 September 2017 Paper

Shaped pupil coronagraph design improvements for the WFIRST coronagraph instrument

A. J. Eldorado Riggs, Neil Zimmerman, Bijan Nemati, John Krist

Proceedings Volume 10400, 104000O (2017) https://doi.org/10.1117/12.2274437

KEYWORDS: Exoplanets, Planets, Diffraction, Monochromatic aberrations, Tolerancing, Interferometry

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Proceedings Article | 1 September 2017 Presentation + Paper

Wavefront control performance modeling with WFIRST shaped pupil coronagraph testbed

Hanying Zhou, Bijian Nemati, John Krist, Eric Cady, Brian Kern, Ilya Poberezhskiy

Proceedings Volume 10400, 1040005 (2017) https://doi.org/10.1117/12.2274391

KEYWORDS: Performance modeling, Wavefronts, Wavefront sensors, Control systems, Systems modeling, Exoplanets, Monte Carlo methods, Imaging systems, Space telescopes, Stars

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Proceedings Article | 1 September 2017 Presentation + Paper

WFIRST coronagraph optical modeling

John Krist, A. J. Riggs, James McGuire, Hong Tang, Nikta Amiri, Gary Gutt, Luis Marchen, David Marx, Bijan Nemati, Navtej Saini, Erkin Sidick, Hanying Zhou

Proceedings Volume 10400, 1040004 (2017) https://doi.org/10.1117/12.2274792

KEYWORDS: Performance modeling, Systems modeling, Exoplanets, Spectrographs, Mirrors, Telescopes, Wavefront sensors, Polarization, Tolerancing, MATLAB

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Proceedings Article | 1 September 2017 Presentation + Paper

Sensitivity of the WFIRST coronagraph performance to key instrument parameters

Bijan Nemati, John Krist, Bertrand Mennesson

Proceedings Volume 10400, 1040007 (2017) https://doi.org/10.1117/12.2274396

KEYWORDS: Signal to noise ratio, Stars, Coronagraphy, Planets, Speckle, Spectroscopy, Sensors, Point spread functions, Imaging spectroscopy

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Proceedings Article | 9 August 2016 Paper

Diffraction modeling of finite subband EFC probing on dark hole contrast with WFIRST-CGI shaped pupil coronagraph

Hanying Zhou, John Krist, Bijan Nemati

Proceedings Volume 9911, 99111S (2016) https://doi.org/10.1117/12.2232129

KEYWORDS: Diffraction, Bandpass filters, Wavefront sensors, Optical filters, Coronagraphy, Error analysis, Wavefronts, Infrared telescopes, Stars, Telescopes

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Proceedings Article | 5 August 2016 Paper

Cryogenic irradiation of an EMCCD for the WFIRST coronagraph: preliminary performance analysis

Nathan Bush, David Hall, Andrew Holland, Ross Burgon, Neil Murray, Jason Gow, Douglas Jordan, Richard Demers, Leon Harding, Bijan Nemati, Michael Hoenk, Darren Michaels, Pavani Peddada

Proceedings Volume 9915, 99150A (2016) https://doi.org/10.1117/12.2234628

KEYWORDS: Cryogenics, Imaging systems, Electron multiplying charge coupled devices, Sensors, Coronagraphy, Temperature metrology, Signal processing, Interference (communication), Silicon, X-rays

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The Wide Field Infra-Red Survey Telescope (WFIRST) is a NASA observatory scheduled to launch in the next decade that will settle essential questions in exoplanet science. The Wide Field Instrument (WFI) offers Hubble quality imaging over a 0.28 square degree field of view and will gather NIR statistical data on exoplanets through gravitational microlensing. An on-board coronagraph will for the first time perform direct imaging and spectroscopic analysis of exoplanets with properties analogous to those within our own solar system, including cold Jupiters, mini Neptunes and potentially super Earths.

The Coronagraph Instrument (CGI) will be required to operate with low signal flux for long integration times, demanding all noise sources are kept to a minimum. The Electron Multiplication (EM)-CCD has been baselined for both the imaging and spectrograph cameras due its ability to operate with sub-electron effective read noise values with appropriate multiplication gain setting. The presence of other noise sources, however, such as thermal dark signal and Clock Induced Charge (CIC), need to be characterized and mitigated. In addition, operation within a space environment will subject the device to radiation damage that will degrade the Charge Transfer Effciency (CTE) of the device throughout the mission lifetime. Irradiation at the nominal instrument operating temperature has the potential to provide the best estimate of performance degradation that will be experienced in-flight, since the final population of silicon defects has been shown to be dependent upon the temperature at which the sensor is irradiated.

Here we present initial findings from pre- and post- cryogenic irradiation testing of the e2v CCD201-20 BI EMCCD sensor, baselined for the WFIRST coronagraph instrument. The motivation for irradiation at cryogenic temperatures is discussed with reference to previous investigations of a similar nature. The results are presented in context with those from a previous room temperature irradiation investigation that was performed on a CCD201-20 operated under the same conditions. A key conclusion is that the measured performance degradation for a given proton fluence is seen to measurably differ for the cryogenic case compared to the room temperature equivalent for the conditions of this study.

Proceedings Article | 1 August 2016 Paper

The effect of radiation-induced traps on the WFIRST coronagraph detectors

Bijan Nemati, Robert Effinger, Richard Demers, Leon Harding, Patrick Morrissey, Nathan Bush, David Hall, Jesper Skottfelt

Proceedings Volume 9915, 99150M (2016) https://doi.org/10.1117/12.2235278

KEYWORDS: Sensors, Charge-coupled devices, Electrons, Exoplanets, Coronagraphy, Electrodes, Electron multiplying charge coupled devices, Planets, Image quality, Electronic imaging

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Proceedings Article | 29 July 2016 Paper

Closing the contrast gap between testbed and model prediction with WFIRST-CGI shaped pupil coronagraph

Hanying Zhou, Bijan Nemati, John Krist, Eric Cady, Camilo Prada, Brian Kern, Ilya Poberezhskiy

Proceedings Volume 9904, 990419 (2016) https://doi.org/10.1117/12.2232211

KEYWORDS: Speckle, Actuators, Error control coding, Coronagraphy, Wavefronts, Error analysis, Control systems, Data modeling, Monochromatic aberrations, Phase measurement

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Proceedings Article | 29 July 2016 Paper

Data processing and algorithm development for the WFIRST coronagraph: comparison of RDI and ADI strategies and impact of spatial sampling on post-processing

Marie Ygouf, Neil Zimmerman, Laurent Pueyo, Rémi Soummer, Marshall Perrin, Bertrand Mennesson, John Krist, Gautam Vasisht, Bijan Nemati, Bruce Macintosh

Proceedings Volume 9904, 99045M (2016) https://doi.org/10.1117/12.2231581

KEYWORDS: Exoplanets, Point spread functions, Space telescopes, Telescopes, Point spread functions, Stars, Algorithm development, Coronagraphy, Speckle, Planets, Iterated function systems

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Direct detection and characterization of mature giant or sub-Neptune exoplanets in the visible will require space- based instruments optimized for high-contrast imaging with contrasts of 10^-9. In this context, the coronagraph instrument (CGI) on the Wide-Field Infrared Survey Telescope (WFIRST) will reach raw contrasts of about 10^-8 or better using state-of-the-art starlight suppression and wavefront control techniques. A ten-fold contrast improvement is therefore required using post-processing techniques in order to detect 10^-9 planets from speckles. Post-processing techniques that are successful on both ground-based and space-based instruments need to be validated at such high contrast levels. In this communication, we investigate speckle subtraction techniques for different observation strategies and hardware parameters on WFIRST-like simulated images in the presence of deformable mirrors and an hybrid lyot coronagraph (HLC). We compare the contrast gain after post-processing in both speckle-noise and photon-noise dominated regimes for two different observing scenarios: the reference star differential imaging (RDI) and the angular differential imaging (ADI). We find that the ADI observing strategy is more robust to speckle and photon noises than the RDI observing strategy, enabling up to a threefold gain with respect to the latter. Thus, we recommend that the telescope be able to roll by at least 13° off nominal. We investigated the impact of spatial sampling on post-processed sensitivity, in the context of design trade studies for the Integral Field Spectrograph (IFS) component of the instrument. Our preliminary results suggest that the spatial sampling can be halved from the baseline sampling rate (~4 lenslets per λ/D) without any degradation in final contrast, thereby reducing the integration time required for spectroscopic characterization. In the speckle-noise dominated regime, we also find that at Nyquist sampling or higher, sub-pixel reference- to-target offsets have a negligible impact on the level of residual speckles after post-processing.

Proceedings Article | 29 July 2016 Paper

The latest results from DICE (Detector Interferometric Calibration Experiment)

A. Crouzier, F. Malbet, F. Hénault, A. Léger, C. Cara, J. M. Le Duigou, O. Preis, P. Kern, A. Delboulbe, G. Martin, P. Feautrier, E. Stadler, S. Lafrasse, S. Rochat, C. Ketchazo, M. Donati, Eric Doumayrou, P. O. Lagage, M. Shao, R. Goullioud, B. Nemati, C. Zhai, E. Behar, S. Potin, M. Saint-Pe, J. Dupont

Proceedings Volume 9904, 99045G (2016) https://doi.org/10.1117/12.2234304

KEYWORDS: Interferometry, Calibration, Sensors, Metrology, Stars, Charge-coupled devices, Electroluminescent displays, Stray light, Point spread functions, Planets

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Proceedings Article | 22 July 2016 Paper

WFIRST/AFTA coronagraph contrast performance sensitivity studies: simulation versus experiment

Erkin Sidick, Byoung-Joon Seo, David Marx, Ilya Poberezhskiy, Bijan Nemati

Proceedings Volume 9912, 99126M (2016) https://doi.org/10.1117/12.2231763

KEYWORDS: Device simulation, Deformable mirrors, Coronagraphy, Actuators, Wavefronts, Telescopes, Optical components, Calibration, Modulation, Monte Carlo methods

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Proceedings Article | 18 May 2016 Paper

Low-CNR inverse synthetic aperture LADAR imaging demonstration with atmospheric turbulence

R. Trahan, B. Nemati, H. Zhou, M. Shao, I. Hahn, W. Schulze

Proceedings Volume 9846, 98460E (2016) https://doi.org/10.1117/12.2224322

KEYWORDS: LIDAR, Atmospheric turbulence, Sensors, Imaging systems, Photodetectors, Transmitters, Fourier transforms, Heterodyning, Signal detection, Image quality

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Proceedings Article | 18 May 2016 Paper

Low-cost chirp linearization for long-range ISAL imaging application

Hanying Zhou, Bijan Nemati, Mike Shao, Chengxing Zhai, Inseob Hahn, William Schulze, Russell Trahan

Proceedings Volume 9846, 98460D (2016) https://doi.org/10.1117/12.2224122

KEYWORDS: Ferroelectric materials, Turbulence, Receivers, Interferometers, Laser applications, LIDAR, Transmitters, Phase measurement, Tunable lasers, Bragg cells

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SPIE Journal Paper | 14 December 2015

Technology advancement of the CCD201-20 EMCCD for the WFIRST coronagraph instrument: sensor characterization and radiation damage

Leon Harding, Richard Demers, Michael Hoenk, Pavani Peddada, Bijan Nemati, Michael Cherng, Darren Michaels, Leo Neat, Anthony Loc, Nathan Bush, David Hall, Neil Murray, Jason P. Gow, Ross Burgon, Andrew Holland, Alice Reinheimer, Paul Jorden, Douglas Jordan

JATIS, Vol. 2, Issue 01, 011007, (December 2015) https://doi.org/10.1117/12.10.1117/1.JATIS.2.1.011007

KEYWORDS: Electron multiplying charge coupled devices, Sensors, Charge-coupled devices, Silicon, Clocks, Particles, Cameras, Coronagraphy, Planets, CMOS sensors

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SPIE Journal Paper | 7 December 2015

WFIRST-AFTA coronagraph shaped pupil masks: design, fabrication, and characterization

Kunjithapatham Balasubramanian, Victor White, Karl Yee, Pierre Echternach, Richard Muller, Matthew Dickie, Eric Cady, Camilo Prada, Daniel Ryan, Ilya Poberezhskiy, Brian Kern, Hanying Zhou, John Krist, Bijan Nemati, A. J. Eldorado Riggs, Neil Zimmerman, N. Jeremy Kasdin

JATIS, Vol. 2, Issue 01, 011005, (December 2015) https://doi.org/10.1117/12.10.1117/1.JATIS.2.1.011005

KEYWORDS: Photomasks, Silicon, Coronagraphy, Reflectivity, Semiconducting wafers, Aluminum, Point spread functions, Wavefronts, Optical instrument design, Etching

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SPIE Journal Paper | 28 October 2015

Numerical modeling of the proposed WFIRST-AFTA coronagraphs and their predicted performances

John Krist, Bijan Nemati, Bertrand Mennesson

JATIS, Vol. 2, Issue 01, 011003, (October 2015) https://doi.org/10.1117/12.10.1117/1.JATIS.2.1.011003

KEYWORDS: Coronagraphy, Wavefronts, Stars, Polarization, Point spread functions, Planets, Numerical modeling, Telescopes, Speckle, Monochromatic aberrations

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SPIE Journal Paper | 28 October 2015

Demonstration of high contrast with an obscured aperture with the WFIRST-AFTA shaped pupil coronagraph

Eric Cady, Camilo Mejia Prada, Xin An, Kunjithapatham Balasubramanian, Rosemary Diaz, N. Jeremy Kasdin, Brian Kern, Andreas Kuhnert, Bijan Nemati, Ilya Poberezhskiy, A. J. Eldorado Riggs, Robert Zimmer, Neil Zimmerman

JATIS, Vol. 2, Issue 01, 011004, (October 2015) https://doi.org/10.1117/12.10.1117/1.JATIS.2.1.011004

KEYWORDS: Coronagraphy, Photomasks, Planets, Point spread functions, Telescopes, Infrared telescopes, Semiconducting wafers, Reflectivity, Wavefronts, Data modeling

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The coronagraph instrument on the Wide-Field Infrared Survey Telescope-Astrophysics-Focused Telescope Asset (WFIRST-AFTA) mission study has two coronagraphic architectures, shaped pupil and hybrid Lyot, which may be interchanged for use in different observing scenarios. Each architecture relies on newly developed mask components to function in the presence of the AFTA aperture, and so both must be matured to a high technology readiness level in advance of the mission. A series of milestones were set to track the development of the technologies required for the instrument; we report on completion of WFIRST-AFTA coronagraph milestone 2—a narrowband 10−8 contrast test with static aberrations for the shaped pupil—and the plans for the upcoming broadband coronagraph milestone 5.

Proceedings Article | 16 September 2015

WFIRST-AFTA coronagraph performance: feedback from post-processing studies to overall design

Bertrand Mennesson, John Krist, Bijan Nemati, Marie Ygouf, Laurent Pueyo, Remi Soummer, Marshall Perrin

Proceedings Volume 9605, 96050D (2015) https://doi.org/10.1117/12.2189403

KEYWORDS: Coronagraphy, Stars, Planets, Point spread functions, Calibration, Wavefronts, Exoplanets, Speckle, Polarization, Image processing

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The WFIRST-AFTA Coronagraph aims at forming direct images and measuring the first spectra of exoplanets in orbit around main sequence stars. An important aspect of the instrument is the ability to remove residual stellar speckles to improve the detectability of such planets. Based on detailed simulations and early laboratory tests, we present here some first estimates of the contrast gain expected from advanced post-processing treatments of AFTA-like coronagraphic images. We further discuss their impact on the overall design of the instrument, including its anticipated observing approach.

Proceedings Article | 16 September 2015

Requirements and design reference mission for the WFIRST/AFTA coronagraph instrument

Richard Demers, Frank Dekens, Rob Calvet, Zensheu Chang, Robert Effinger, Eric Ek, Larry Hovland, Laura Jones, Anthony Loc, Bijan Nemati, Charley Noecker, Timothy Neville, Hung Pham, Mike Rud, Hong Tang, Juan Villalvazo

Proceedings Volume 9605, 960502 (2015) https://doi.org/10.1117/12.2191792

KEYWORDS: Coronagraphy, Collimators, Space telescopes, Telescopes, Iterated function systems, Planets, Mirrors, Exoplanets, Electronics, Thermography

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The WFIRST-AFTA coronagraph instrument takes advantage of AFTAs 2.4-meter aperture to provide novel exoplanet imaging science at approximately the same instrument cost as an Explorer mission. The AFTA coronagraph also matures direct imaging technologies to high TRL for an Exo-Earth Imager in the next decade. The coronagraph Design Reference Mission (DRM) optical design is based on the highly successful High Contrast Imaging Testbed (HCIT), with modifications to accommodate the AFTA telescope design, service-ability, volume constraints, and the addition of an Integral Field Spectrograph (IFS). In order to optimally satisfy the three science objectives of planet imaging, planet spectral characterization and dust debris imaging, the coronagraph is designed to operate in two different modes: Hybrid Lyot Coronagraph or Shaped Pupil Coronagraph. Active mechanisms change pupil masks, focal plane masks, Lyot masks, and bandpass filters to shift between modes. A single optical beam train can thus operate alternatively as two different coronagraph architectures. Structural Thermal Optical Performance (STOP) analysis predicts the instrument contrast with the Low Order Wave Front Control loop closed. The STOP analysis was also used to verify that the optical/structural/thermal design provides the extreme stability required for planet characterization in the presence of thermal disturbances expected in a typical observing scenario. This paper describes the instrument design and the flow down from science requirements to high level engineering requirements.

Proceedings Article | 16 September 2015

Electron multiplication CCD detector technology advancement for the WFIRST-AFTA coronagraph

Leon Harding, Richard Demers, Michael Hoenk, Pavani Peddada, Bijan Nemati, Michael Cherng, Darren Michaels, Anthony Loc, Nathan Bush, David Hall, Neil Murray, Jason Gow, Ross Burgon, Andrew Holland, Alice Reinheimer, Paul Jorden, Douglas Jordan

Proceedings Volume 9605, 96050F (2015) https://doi.org/10.1117/12.2189927

KEYWORDS: Sensors, Electron multiplying charge coupled devices, Charge-coupled devices, Coronagraphy, Imaging systems, Silicon, Tantalum, CCD image sensors, Iterated function systems, Clocks

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The WFIRST-AFTA (Wide Field InfraRed Survey Telescope-Astrophysics Focused Telescope Asset) is a NASA space observatory. It will host two major astronomical instruments: a wide-field imager (WFI) to search for dark energy and carry out wide field near infrared (NIR) surveys, and a coronagraph instrument (CGI) to image and spectrally characterize extrasolar planets. In this paper, we discuss the work that has been carried out at JPL in advancing Electron Multiplying CCD (EMCCD) technology to higher flight maturity, with the goal of reaching a NASA technology readiness level of 6 (TRL-6) by early-to-mid 2016. The EMCCD has been baselined for both the coronagraph's imager and integral field spectrograph (IFS) based on its sub-electron noise performance at extremely low flux levels - the regime where the AFTA CGI will operate. We present results from a study that fully characterizes the beginning of life performance of the EMCCD. We also discuss, and present initial results from, a recent radiation test campaign that was designed and carried out to mimic the conditions of the WFIRST-AFTA space environment in an L2 orbit, where we sought to assess the sensor's end of life performance, particularly degradation of its charge transfer efficiency, in addition to other parameters such as dark current, electron multiplication gain, clock induced charge and read noise.

Proceedings Article | 16 September 2015

Laboratory performance of the shaped pupil coronagraphic architecture for the WFIRST/AFTA coronagraph

Eric Cady, Camilo Mejia Prada, Xin An, Kunjithapatham Balasubramanian, Rosemary Diaz, N. Jeremy Kasdin, Brian Kern, Andreas Kuhnert, Bijan Nemati, Keith Patterson, Ilya Poberezhskiy, A. J. Eldorado Riggs, Daniel Ryan, Hanying Zhou, Robert Zimmer, Neil Zimmerman

Proceedings Volume 9605, 96050B (2015) https://doi.org/10.1117/12.2189113

KEYWORDS: Coronagraphy, Photomasks, Telescopes, Point spread functions, Microscopes, Infrared telescopes, Silicon, Binary data, Infrared radiation, Stars

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One of the two primary architectures being tested for the WFIRST-AFTA coronagraph instrument is the shaped pupil coronagraph, which uses a binary aperture in a pupil plane to create localized regions of high contrast in a subsequent focal plane. The aperture shapes are determined by optimization, and can be designed to work in the presence of secondary obscurations and spiders - an important consideration for coronagraphy with WFIRST-AFTA. We present the current performance of the shaped pupil testbed, including the results of AFTA Milestone 2, in which ≈ 6 × 10^-9 contrast was achieved in three independent runs starting from a neutral setting.

Proceedings Article | 11 September 2015

The impact of radiation damage on photon counting with an EMCCD for the WFIRST-AFTA coronagraph

Nathan Bush, David Hall, Andrew Holland, Ross Burgon, Neil Murray, Jason Gow, Matthew Soman, Douglas Jordan, Richard Demers, Leon Harding, Michael Hoenk, Darren Michaels, Bijan Nemati, Pavani Peddada

Proceedings Volume 9605, 96050E (2015) https://doi.org/10.1117/12.2189818

KEYWORDS: Electron multiplying charge coupled devices, Interference (communication), Coronagraphy, Sensors, Signal processing, X-rays, Photon counting, Clocks, Exoplanets, Space operations

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WFIRST-AFTA is a 2.4m class NASA observatory designed to address a wide range of science objectives using two complementary scientific payloads. The Wide Field Instrument (WFI) offers Hubble quality imaging over a 0.28 square degree field of view, and will gather NIR statistical data on exoplanets through gravitational microlensing. The second instrument is a high contrast coronagraph that will carry out the direct imaging and spectroscopic analysis of exoplanets, providing a means to probe the structure and composition of planetary systems. The coronagraph instrument is expected to operate in low photon flux for long integration times, meaning all noise sources must be kept to a minimum. In order to satisfy the low noise requirements, the Electron Multiplication (EM)-CCD has been baselined for both the imaging and spectrograph cameras. The EMCCD was selected in comparison with other candidates because of its low effective electronic read noise at sub-electron values with appropriate multiplication gain setting. The presence of other noise sources, however, such as thermal dark signal and Clock Induced Charge (CIC), need to be characterised and mitigated. In addition, operation within a space environment will subject the device to radiation damage that will degrade the Charge Transfer Efficiency (CTE) of the device throughout the mission lifetime. Here we present our latest results from pre- and post-irradiation testing of the e2v CCD201-20 BI EMCCD sensor, baselined for the WFIRST-AFTA coronagraph instrument. A description of the detector technology is presented, alongside considerations for operation within a space environment. The results from a room temperature irradiation are discussed in context with the nominal operating requirements of AFTA-C and future work which entails a cryogenic irradiation of the CCD201-20 is presented.

Proceedings Article | 4 September 2015

An overview of WFIRST/AFTA coronagraph optical modeling

John Krist, Bijan Nemati, Hanying Zhou, Erkin Sidick

Proceedings Volume 9605, 960505 (2015) https://doi.org/10.1117/12.2188361

KEYWORDS: Coronagraphy, Wavefronts, Polarization, Point spread functions, Stars, Telescopes, Space telescopes, Monochromatic aberrations, Planets, Mirrors

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The WFIRST/AFTA 2.4 m space telescope currently under study includes a stellar coronagraph for the imaging and spectral characterization of extrasolar planets. Based largely on performance predictions from end-to-end optical propagation modeling, promising coronagraphic methods were selected in late 2013 for further consideration for use on AFTA. Since those downselect analyses further modeling work has been done on evaluating refined coronagraph designs, wavefront sensing and control, detector representation, and time-dependent effects. Thermal, structural, ray trace, and diffraction propagation models are used in these studies. Presented here is the progress to date and plans for future analyses.

Proceedings Article | 2 August 2014

Technology development towards WFIRST-AFTA coronagraph

Ilya Poberezhskiy, Feng Zhao, Xin An, Kunjithapatham Balasubramanian, Ruslan Belikov, Eric Cady, Richard Demers, Rosemary Diaz, Qian Gong, Brian Gordon, Renaud Goullioud, Frank Greer, Olivier Guyon, Michael Hoenk, N. Jeremy Kasdin, Brian Kern, John Krist, Andreas Kuhnert, Michael McElwain, Bertrand Mennesson, Dwight Moody, Richard Muller, Bijan Nemati, Keith Patterson, A. J. Riggs, Daniel Ryan, Byoung-Joon Seo, Stuart Shaklan, Erkin Sidick, Fang Shi, Nicholas Siegler, Rémi Soummer, Hong Tang, John Trauger, J. Kent Wallace, Xu Wang, Victor White, Daniel Wilson, Karl Yee, Hanying Zhou, Neil Zimmerman

Proceedings Volume 9143, 91430P (2014) https://doi.org/10.1117/12.2060320

KEYWORDS: Coronagraphy, Sensors, Wavefronts, Wavefront sensors, Iterated function systems, Photomasks, Space telescopes, Exoplanets, Deformable mirrors, Planets

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NASA’s WFIRST-AFTA mission concept includes the first high-contrast stellar coronagraph in space. This coronagraph will be capable of directly imaging and spectrally characterizing giant exoplanets similar to Neptune and Jupiter, and possibly even super-Earths, around nearby stars. In this paper we present the plan for maturing coronagraph technology to TRL5 in 2014-2016, and the results achieved in the first 6 months of the technology development work. The specific areas that are discussed include coronagraph testbed demonstrations in static and simulated dynamic environment, design and fabrication of occulting masks and apodizers used for starlight suppression, low-order wavefront sensing and control subsystem, deformable mirrors, ultra-low-noise spectrograph detector, and data post-processing.

Proceedings Article | 2 August 2014

Detector selection for the WFIRST-AFTA coronagraph integral field spectrograph

Bijan Nemati

Proceedings Volume 9143, 91430Q (2014) https://doi.org/10.1117/12.2060321

KEYWORDS: Sensors, Electron multiplying charge coupled devices, Signal to noise ratio, Iterated function systems, Planets, Coronagraphy, Charge-coupled devices, Electrons, Exoplanets, Stars

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The coronagraph instrument in the WFIRST-AFTA mission will allow high contrast imaging of exoplanetary systems with the benefit of a 2.4 meter space telescope. The instrument will feature an integral field spectrograph (IFS) capable of measuring spectra from exoplanets. Since the typical exoplanet target will be dimmer than the host star by a factor of ~1e9, and the dispersion of this light into many spectral channels further suppresses the photon rate, the noise requirements on the detector for this instrument will be very tight. From a performance perspective, many parameters are important, including the read noise, the dark current, and the clock induced charge. At the same time, from a functionality perspective, the unique challenges of the space environment, in particular damage from high energy cosmic rays, need to be assessed and mitigated. In this paper we present our recent work in selecting the detector for the WFIRST-AFTA IFS. We also discuss flight operation considerations and risks associated with these detectors as well as their technology readiness level.

Proceedings Article | 15 September 2011

Micropixel-level image position sensing testbed

Bijan Nemati, Michael Shao, Chengxing Zhai, Hernan Erlig, Renaud Goullioud, Xu Wang

Proceedings Volume 8151, 81510W (2011) https://doi.org/10.1117/12.894477

KEYWORDS: Metrology, Stars, Charge-coupled devices, Telescopes, Point spread functions, Quantum efficiency, Optical fibers, Calibration, Space telescopes, Mirrors

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The search for Earth-mass planets in the habitable zones of nearby Sun-like stars is an important goal of astrophysics. This search is not feasible with the current slate of astronomical instruments. We propose a new concept for microarcsecond astrometry which uses a simplified instrument and hence promises to be low cost. The concept employs a telescope with only a primary, laser metrology applied to the focal plane array, and new algorithms for measuring image position and displacement on the focal plane. The required level of accuracy in both the metrology and image position sensing is at a few micro-pixels. We have begun a detailed investigation of the feasibility of our approach using simulations and a micro-pixel image position sensing testbed called MCT. So far we have been able to demonstrate that the pixel-to-pixel distances in a focal plane can be measured with a precision of 20 micro-pixels and image-to-image distances with a precision of 30 micro-pixels. We have also shown using simulations that our image position algorithm can achieve accuracy of 4 micro-pixels in the presence of λ/20 wavefront errors.

Proceedings Article | 15 September 2011

NEAT: a microarcsec astrometric telescope

M. Shao, B. Nemati, C. Zhai, R. Goullioud, F. Malbet, A. Leger

Proceedings Volume 8151, 81510V (2011) https://doi.org/10.1117/12.894481

KEYWORDS: Stars, Space telescopes, Telescopes, Charge-coupled devices, Point spread functions, Planets, Diffraction, Metrology, Sensors, Mirrors

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NEAT, Nearby Exo-Earth Astrometric Telescope is a medium-small telescope ~ 1m in diameter that is designed to make ultra precise < 1 uas (microarcsec) astrometric measurements of nearby stars in a ~ 1hr observation. Four major error sources prevent normal space telescopes from obtaining accuracies close to 1 uas. Even with a small 1m telescope, photon noise is usually not a problem for the bright nearby target stars. But in general, the reference stars are much fainter. Typically a field of view of ~0.5 deg dia is needed to obtain enough bright reference stars. The NEAT concept uses a very simple but unusual design to avoid optically induced astrometric errors. The third source of error is the accuracy and stability of the focal plane. A 1uas error over a ~2000 arcsec field of view implies the focal plane is accurate or at least stable to 5 parts in 10¹⁰ over the lifetime of the mission (~5yrs). The 4th class of error has to do with our knowledge of the PSF and how that PSF is sampled by an imperfect detector. A Nyquist sampled focal plane would have > 2 pixels per λ/D, and centroiding to 1uas means centroiding to 10^-5 pixels. This paper describes the mission concept, and an overview of the technology needed to perform 1uas astrometry with a small telescope, and how we overcome problems 1 and 2. A companion paper will describe the technical progress we've made in solving problems 3 and 4.

Proceedings Article | 6 August 2010

Single aperture imaging astrometry with a diffracting pupil: application to exoplanet mass measurement with a small coronagraphic space telescope

Olivier Guyon, Michael Shao, Stuart Shaklan, Marie Levine, S. Mark Ammons, Eduardo Bendek, Robert Woodruff, Bijan Nemati, Joe Pitman

Proceedings Volume 7731, 77312C (2010) https://doi.org/10.1117/12.857902

KEYWORDS: Space telescopes, Coronagraphy, Telescopes, Stars, Diffraction, Exoplanets, Infrared telescopes, Cameras, Planets, Infrared radiation

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High precision astrometry of nearby bright stars is theoretically (in the photon noise limit) possible with a space coronagraph using a wide field diffraction limited camera imaging an annulus of background stars around the central coronagraphic field. With the sub-micro arcsecond accuracy theoretically achievable on a 1.4-m telescope, the mass of all planets that can be imaged by the coronagraph would be estimated. Simultaneous imaging and astrometric measurements would reduce the number of astrometric measurements necessary for mass determination, and reduce confusion between multiple planets and possible exozodiacal clouds in the coronagraphic image. While scientifically attractive, this measurement is technically very challenging, and must overcome astrometric distortions, which, in conventional telescopes, are several orders of magnitude above the photon noise limit. In this paper, we propose a new approach to calibrating astrometric distortions in the wide field imaging camera. The astrometric measurement is performed by simultaneously imaging background stars and diffraction spikes from the much brighter coronagraphic target on the same focal plane array. The diffraction spikes are generated by a series of small dark spots on the primary mirror to reduce sensitivity to optical and mechanical distortions. Small scale distortions and detector errors are averaged down to sub-micro arcsecond by rolling the telescope around the line of sight. A preliminary error budget is shown and discussed to identify major sources of error for a 1.4-m telescope imaging a 0.25 squaredeg field of view at the galactic pole.

Proceedings Article | 22 July 2010

SIM interferometer testbed (SCDU) status and recent results

Bijan Nemati, Xin An, Renaud Goullioud, Michael Shao, Tsae-Pyng Shen, Udo Wehmeier, Mark Weilert, Xu Wang, Thomas Werne, Janet Wu, Chengxing Zhai

Proceedings Volume 7734, 77341N (2010) https://doi.org/10.1117/12.856300

KEYWORDS: Stars, Calibration, Interferometers, Error analysis, Metrology, Wavefronts, Spectral calibration, CCD cameras, Cameras, Light sources

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SIM Lite is a space-borne stellar interferometer capable of searching for Earth-size planets in the habitable zones of nearby stars. This search will require measurement of astrometric angles with sub micro-arcsecond accuracy and optical pathlength differences to 1 picometer by the end of the five-year mission. One of the most significant technical risks in achieving this level of accuracy is from systematic errors that arise from spectral differences between candidate stars and nearby reference stars. The Spectral Calibration Development Unit (SCDU), in operation since 2007, has been used to explore this effect and demonstrate performance meeting SIM goals. In this paper we present the status of this testbed and recent results.

Proceedings Article | 22 July 2010

The SIM Lite Astrometric Observatory: engineering risk reduction activity

Renaud Goullioud, Frank Dekens, Bijan Nemati, Xin An, Larry Hovland

Proceedings Volume 7734, 77341M (2010) https://doi.org/10.1117/12.857721

KEYWORDS: Interferometers, Stars, Telescopes, Metrology, Mirrors, Cameras, Space telescopes, Sensors, Actuators, Calibration

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The SIM Lite Astrometric Observatory is a mission concept for a space-borne instrument to perform micro-arcsecond narrow-angle astrometry to search 60 to 100 nearby stars for Earth-like planets, and to perform global astrometry for a broad astrophysics program. The main enabling technology development for the mission was completed during phases A & B. While the project is waiting for the results of the ASTRO2010 Decadal Survey to proceed into flight implementation, the instrument team is currently converting the developed technology onto flight-ready engineering models. These key engineering tasks will significantly reduce the implementation risks during the flight phases C & D of the mission. The main optical interferometer components, including the astrometric beam combiner (ABC), the fine steering mechanism (FSM), the path-length control and modulation optical mechanisms (POM & MOM), focal plane camera electronics (ATC & FTC), camera cooling cryo-heat pipe, and the siderostat mechanism are currently under development. Main assemblies are built to meet flight requirements and have been or will be subjected to flight qualification level environmental testing (random vibration and thermal cycling) and performance testing. The Spectral Calibration Development Unit (SCDU), a white light interferometer testbed has recently demonstrated how to perform the spectral calibration of the instrument. The Guide 2 Telescope testbed (G2T) has demonstrated the 50 micro-arcsecond angle monitoring capability required by SIM Lite to perform astrometry. This paper summarizes recent progress in engineering risk reduction activities.

Proceedings Article | 22 July 2010

SCDU (Spectral Calibration Development Unit) testbed narrow angle astrometric performance

Xu Wang, Renaud Goullioud, Bijan Nemati, Michael Shao, Udo Wehmeier, Mark Weilert, Thomas Werne, Janet Wu, Chengxing Zhai

Proceedings Volume 7734, 77344J (2010) https://doi.org/10.1117/12.857278

KEYWORDS: Calibration, Stars, Spectral calibration, Interferometers, Optical filters, Picosecond phenomena, Error analysis, Data processing, Exoplanets, Metrology

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The most stringent astrometric performance requirements on NASA's SIM(Space Interferometer Mission)-Lite mission will come from the so-called Narrow-Angle (NA) observing scenario, aimed at finding Earth-like exoplanets, where the interferometer chops between the target star and several nearby reference stars multiple times over the course of a single visit. Previously, about 20 pm NA error with various shifts was reported1. Since then, investigation has been under way to understand the mechanisms that give rise to these shifts. In this paper we report our findings, the adopted mitigation strategies, and the resulting testbed performance.

Proceedings Article | 22 July 2010

SCDU testbed automated in-situ alignment, data acquisition, and analysis

Thomas Werne, Udo Wehmeier, Janet Wu, Xin An, Renaud Goullioud, Bijan Nemati, Michael Shao, Tsae-Pyng Shen, Xu Wang, Mark Weilert, Chengxing Zhai

Proceedings Volume 7734, 77344F (2010) https://doi.org/10.1117/12.857525

KEYWORDS: MATLAB, Computing systems, Cameras, Data storage, Data processing, Data acquisition, Distributed computing, Human-machine interfaces, Control systems, Real-time computing

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In the course of fulfilling its mandate, the Spectral Calibration Development Unit (SCDU) testbed for SIM-Lite produces copious amounts of raw data. To effectively spend time attempting to understand the science driving the data, the team devised computerized automations to limit the time spent bringing the testbed to a healthy state and commanding it, and instead focus on analyzing the processed results. We developed a multi-layered scripting language that emphasized the scientific experiments we conducted, which drastically shortened our experiment scripts, improved their readability, and all-but-eliminated testbed operator errors. In addition to scientific experiment functions, we also developed a set of automated alignments that bring the testbed up to a well-aligned state with little more than the push of a button. These scripts were written in the scripting language, and in Matlab via an interface library, allowing all members of the team to augment the existing scripting language with complex analysis scripts. To keep track of these results, we created an easilyparseable state log in which we logged both the state of the testbed and relevant metadata. Finally, we designed a distributed processing system that allowed us to farm lengthy analyses to a collection of client computers which reported their results in a central log. Since these logs were parseable, we wrote query scripts that gave us an effortless way to compare results collected under different conditions. This paper serves as a case-study, detailing the motivating requirements for the decisions we made and explaining the implementation process.

Proceedings Article | 22 July 2010

Mitigation of angle tracking errors due to color dependent centroid shifts in SIM Lite

Bijan Nemati, Xin An, Renaud Goullioud, Michael Shao, Tsae-Pyng Shen, Udo Wehmeier, Mark Weilert, Xu Wang, Thomas Werne, Janet Wu, Chengxing Zhai

Proceedings Volume 7734, 77344I (2010) https://doi.org/10.1117/12.857778

KEYWORDS: Stars, Interferometers, Metrology, Cameras, Wavefronts, Point spread functions, Charge-coupled devices, Optical alignment, CCD cameras, Beam splitters

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The SIM-Lite astrometric interferometer will search for Earth-size planets in the habitable zones of nearby stars. In this search the interferometer will monitor the astrometric position of candidate stars relative to nearby reference stars over the course of a 5 year mission. The elemental measurement is the angle between a target star and a reference star. This is a two-step process, in which the interferometer will each time need to use its controllable optics to align the starlight in the two arms with each other and with the metrology beams. The sensor for this alignment is an angle tracking CCD camera. Various constraints in the design of the camera subject it to systematic alignment errors when observing a star of one spectrum compared with a start of a different spectrum. This effect is called a Color Dependent Centroid Shift (CDCS) and has been studied extensively with SIM-Lite's SCDU testbed. Here we describe results from the simulation and testing of this error in the SCDU testbed, as well as effective ways that it can be reduced to acceptable levels.

Proceedings Article | 22 July 2010

SIM Lite mission spectral calibration sensitivities and refinements

C. Zhai, X. An, R. Goullioud, B. Nemati, M. Shao, J. Shen, X. Wang, U. Wehmeier, M. Weilert, T. Werne, J. Wu

Proceedings Volume 7734, 77341J (2010) https://doi.org/10.1117/12.856336

KEYWORDS: Calibration, Spectral calibration, Error analysis, Stars, Modulation, Ferroelectric materials, Data modeling, Phase shift keying, Fourier transforms, Optical filters

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SIM-Lite missions will perform astrometry at microarcsecond accuracy using star light interferometry. For typical baselines that are shorter than 10 meters, this requires to measure optical path difference (OPD) accurate to tens of picometers calling for highly accurate calibration. A major challenge is to calibrate the star spectral dependency in fringe measurements - the spectral calibration. Previously, we have developed a spectral calibration and estimation scheme achieving picometer level accuracy. In this paper, we present the improvements regarding the application of this scheme from sensitivity studies. Data from the SIM Spectral Calibration Development Unit (SCDU) test facility shows that the fringe OPD is very sensitive to pointings of both beams from the two arms of the interferometer. This sensitivity coupled with a systematic pointing error provides a mechanism to explain the bias changes in 2007. Improving system alignment can effectively reduce this sensitivity and thus errors due to pointing errors. Modeling this sensitivity can lead to further improvement in data processing. We then investigate the sensitivity to a model parameter, the bandwidth used in the fringe model, which presents an interesting trade between systematic and random errors. Finally we show the mitigation of calibration errors due to system drifts by interpolating instrument calibrations. These improvements enable us to use SCDU data to demonstrate that SIM-Lite missions can meet the 1pm noise floor requirement for detecting earth-like exoplanets.

Proceedings Article | 20 August 2009

The Gemini Planet Imager calibration testbed

J. Kent Wallace, Rick Burruss, Laurent Pueyo, Remi Soummer, Chris Shelton, Randall Bartos, Felipe Fregoso, Bijan Nemati, Paul Best, John Angione

Proceedings Volume 7440, 74400S (2009) https://doi.org/10.1117/12.826525

KEYWORDS: Calibration, Wavefronts, Gemini Planet Imager, Sensors, Wavefront sensors, Coronagraphy, Beam splitters, Adaptive optics, Mirrors, Interferometers

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The calibration wavefront system for GPI will measure the complex wavefront at the apodized pupil and provide slow phase corrections to the AO system to mitigate against errors that would cause a loss in contrast. This talk describes both the low-order and high-order sensors in the calibration wavefront sensor and how the information is combined to form the wavefront estimate before the coronagraph. Expected performance for this wavefront sensor will also be described for typical observing scenarios. Finally, we will show labratory results from our calibration testbed that demonstrate the instrument performance at levels commensurate with those required on the GPI instrument.

Proceedings Article | 15 July 2008

Post-coronagraph wavefront sensor for Gemini Planet Imager

J. Kent Wallace, John Angione, Randall Bartos, Paul Best, Rick Burruss, Felipe Fregoso, B. Martin Levine, Bijan Nemati, Michael Shao, Chris Shelton

Proceedings Volume 7015, 70156N (2008) https://doi.org/10.1117/12.787258

KEYWORDS: Wavefront sensors, Calibration, Sensors, Gemini Planet Imager, Wavefronts, Coronagraphy, Stars, Beam splitters, Adaptive optics, Image sensors

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The Gemini Planet Imager (GPI)¹ will employ an apodized-pupil coronagraph to make direct detections of faint companions of nearby stars to a contrast level of the 10^-7 within a few λ/D of the parent star. Such high contrasts from the ground require exquisite wavefront sensing and control both for the AO system as well as for the coronagraph. Un-sensed non-common path phase and amplitude errors after the wavefront sensor dichroic but before the coronagraph lead to speckles which limit the contrast². The calibration wavefront system for GPI will measure the complex wavefront at the system pupil before the apodizer and provide slow phase corrections to the AO system to mitigate errors that would cause a loss in contrast. Here we describe the low-order and high-order wavefront sensors that compose the calibration wavefront sensor, how they operate, and how their information is combined to form the wavefront estimate before the coronagraph. Detailed simulations that show the expected performance for this wavefront sensor will be described for typical observing scenarios. Finally, we will show preliminary lab results from our calibration testbed that demonstrate the operation of the key hardware.

Proceedings Article | 14 September 2007

Star confusion effect on SIM PlanetQuest astrometric performance

C. Zhai, J. Yu, M. Milman, N. Fathpour, M. Morales, B. Nemati, M. Regehr, M. Heflin, L. Sievers

Proceedings Volume 6675, 667506 (2007) https://doi.org/10.1117/12.735770

KEYWORDS: Stars, Interferometers, Charge-coupled devices, Visualization, Superposition, Target detection, Photons, Signal detection, Error analysis, Signal to noise ratio

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SIM PlanetQuest will measure star positions to an accuracy of a few microarcseconds using precise white light fringe measurements. One challenge for the SIM observation scenario is "star confusion," where multiple stars are present in the instrument field of view. This is especially relevant for observing dim science targets because the density of number of stars increases rapidly with star magnitude. We study the effect of star confusion on the SIM astrometric performance due to systematic fringe errors caused by the extra photons from the confusion star(s). Since star confusion from multiple stars may be analyzed as a linear superposition of the effect from single star confusion, we quantify the astrometric errors due to single star confusion surveying over many spectral types, including A0V, F0V, K5III, and M0V, and for various visual magnitude differences. To the leading order, the star confusion effect is characterized by the magnitude difference, spectral difference, and the angular separation between the target and confusion stars. Strategies for dealing with star confusion are presented. For example, since the presence of additional sources in the field of view leads to inconsistent delay estimates from different channels, with sufficient signal to noise ratio, the star confusion can be detected using chi-square statistics of fringe measurements from multiple spectral channels. An interesting result is that the star confusion can be detected even though the interferometer cannot resolve the separation between the target and confusion stars when their spectra are sufficiently different. Other strategies for mitigating the star confusion effect are also discussed.

Proceedings Article | 14 August 2006

Measurement of the non-common vertex error of a double corner cube

Alireza Azizi, Martin Marcin, Douglas Moore, Steve Moser, John Negron, Eung-Gi Paek, Daniel Ryan, Alex Abramovici, Paul Best, Ian Crossfield, Bijan Nemati, Tim Neville, B. Platt, Leonard Wayne

Proceedings Volume 6292, 629203 (2006) https://doi.org/10.1117/12.696088

KEYWORDS: Metrology, Prisms, Motion measurement, Interferometers, Interferometry, Beam splitters, Autocollimators, Data modeling, Heterodyning, Laser metrology

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The Space Interferometry Mission (SIM) requires the control of the optical path of each interferometer with picometer accuracy. Laser metrology gauges are used to measure the path lengths to the fiducial corner cubes at the siderostats. Due to the geometry of SIM a single corner cube does not have sufficient acceptance angle to work with all the gauges. Therefore SIM employs a double corner cube. Current fabrication methods are in fact not capable of producing such a double corner cube with vertices having sufficient commonality. The plan for SIM is to measure the non-commonalty of the vertices and correct for the error in orbit. SIM requires that the non-common vertex error (NCVE) of the double corner cube to be less than 6 μm. The required accuracy for the knowledge of the NCVE is less than 1 μm. This paper explains a method of measuring non-common vertices of a brassboard double corner cube with sub-micron accuracy. The results of such a measurement will be presented.

Proceedings Article | 27 June 2006

SIM PlanetQuest: status and recent progress

Bijan Nemati

Proceedings Volume 6268, 62680Q (2006) https://doi.org/10.1117/12.665678

KEYWORDS: Interferometers, Metrology, Stars, Optical testing, Sensors, Stellar interferometry, Cameras, Astronomy, Planets, Control systems

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SIM PlanetQuest will investigate, using stellar interferometry from space, a broad range of topics in astronomy and astrophysics. Chief among its scientific goals is a search of nearby stars for terrestrial planets in the circumstellar habitable zone. Composed of three astrometric interferometers each capable of resolving approximately one billionth of a degree, SIM is poised to revolutionize our understanding of the Universe in a number of areas. With the completion of its technology development phase, SIM is now on a sure footing for the development of requirements for the flight instrument. The preliminary design of SIM is in place and many key brassboards have been built. Here we review the project status and recent progress.

Proceedings Article | 20 August 2005

Gold coatings for cube-corner retro-reflectors

Svetlana Dligatch, Mark Gross, Roger Netterfield, Nathan Pereira, Benjamin Platt, Bijan Nemati

Proceedings Volume 5870, 587007 (2005) https://doi.org/10.1117/12.613286

KEYWORDS: Gold, Scattering, Optical properties, Ultrasonics, Optical coatings, Retroreflectors, Ions, Scatter measurement, Particles, Reflectivity

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The Space Interferometry Mission (SIM) PlanetQuest is managed by the Jet Propulsion Laboratory for the National Aeronautics and Space Administration. SIM requires, among other things, high precision double cube-corner retroreflectors. A test device has recently been fabricated for this project with demanding specifications on the optical surfaces and gold reflective coatings. Several gold deposition techniques were examined to meet the stringent specifications on uniformity, optical properties, micro-roughness and surface quality. We report on a comparative study of optical performance of gold films deposited by resistive and e-beam pvaporation, including measurements of the scattering from the coated surfaces. The effects of oxygen bombardment and titanium under-layer on optical properties and adhesion were evaluated. The influence of surface preparation on the optical properties was examined also.

Proceedings Article | 19 August 2005

Precision metrology of dihedral angle error in prisms and corner cubes for the Space Interferometry Mission

Jan Burke, Bozenko Oreb, Benjamin Platt, Bijan Nemati

Proceedings Volume 5869, 58690W (2005) https://doi.org/10.1117/12.613591

KEYWORDS: Prisms, Wavefronts, Fringe analysis, Interferometers, Mirrors, Interferometry, Error analysis, Phase shifts, Retroreflectors, Collimation

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Recent work done at CSIRO's Australian Centre for Precision Optics has pushed the fabrication limits on optical retroreflectors. To achieve dihedral angle errors well below an arcsecond, the measurement accuracy was required to be 0.1 arcsec or better. On this level, the error introduced by the interferometer's instrument function is not negligible. So-called "collimation errors", or more generally, wavefront aberrations, can significantly falsify the angle measurements. This paper describes and demonstrates the basic concepts for interferometric measurement of dihedral angle errors in retroreflectors from a practical point of view. We discuss obvious and subtle stumbling blocks, summarize practical experiences, and show some results of the recent joint work between JPL and CSIRO.

Proceedings Article | 20 October 2004

Model validation of SIM external metrology at the sub-nanometer level

Bijan Nemati, Gary Kuan

Proceedings Volume 5491, (2004) https://doi.org/10.1117/12.549700

KEYWORDS: Metrology, Data modeling, Interferometers, Reflection, Phase shifts, Sensors, Performance modeling, Interferometry, Coating, Polarization

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In order to achieve micro-arcsecond astrometry, SIM must make measurements of various optical pathlengths at the picometer level. In this regime of precision, nearly every simplifying assumption in optics must be reexamined as a potential source of systematic error. SIM makes extensive use of physics-based models to predict the form and level of systematic errors affecting instrument performance. Since many of the modeling areas represent new frontiers in optical modeling, the validation of these physical models is a significant challenge that SIM must meet. In the case of the external metrology truss, the model must account for the imperfections in the corner cubes as well as the distance measuring interferometers ("beam launchers"). This model is being validated using the Kite testbed, a 2-D metrology truss with picometer-level accuracy in displacement measurements. We present the model, and the results of the model validation tests on the Kite testbed.

Proceedings Article | 20 October 2004

Kite: status of the external metrology testbed for SIM

Frank Dekens, Oscar Alvarez-Salazar, Alireza Azizi, Steven Moser, Bijan Nemati, John Negron, Timothy Neville, Daniel Ryan

Proceedings Volume 5491, (2004) https://doi.org/10.1117/12.549797

KEYWORDS: Metrology, Stars, Data modeling, Interferometers, Heterodyning, Space operations, Motion measurement, Switches, Bragg cells, Sensors

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Kite is a system level testbed for the External Metrology System of the Space Interferometry Mission (SIM). The External Metrology System is used to track the fiducials that are located at the centers of the interferometer's siderostats. The relative changes in their positions needs to be tracked to an accuracy of tens of picometers in order to correct for thermal deformations and attitude changes of the spacecraft. Because of the need for such high precision measurements, the Kite testbed was build to test both the metrology gauges and our ability to optically model the system at these levels. The Kite testbed is a redundant metrology truss, in which 6 lengths are measured, but only 5 are needed to define the system. The RMS error between the redundant measurements needs to be less than 140pm for the SIM Wide-Angle observing scenario and less than 8 pm for the Narrow-Angle observing scenario. With our current testbed layout, we have achieved an RMS of 85 pm in the Wide-Angle case, meeting the goal. For the Narrow-Angle case, we have reached 5.8 pm, but only for on-axis observations. We describe the testbed improvements that have been made since our initial results, and outline the future Kite changes that will add further effects that SIM faces in order to make the testbed more representative of SIM.

Proceedings Article | 26 February 2003

External metrology truss technology demonstration (KITE)

Bijan Nemati

Proceedings Volume 4852, (2003) https://doi.org/10.1117/12.460729

KEYWORDS: Metrology, Interferometers, Laser metrology, Stars, Time metrology, Heterodyning, Beam splitters, Data acquisition, Device simulation, Interferometry

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To achieve micro-arcsecond astrometry, SIM's external metrology system must track the relative changes of three baseline vectors with a precision of tens of picometers over a one-hour time scale. The Kite testbed is designed to be the technology demonstration for a picometer-class external metrology truss. Four fiducials, two simple corner cubes and two triple corner cubes, ar arranged in a planar parallelogram configuration to allow a redundant measurement of truss deformations by six metrology gauges placed between the fiducials. Each metrology gauge is capable of 20-pm relative metrology accuracy and 10-μm absolute metrology accuracy, using a beam launcher capable of self-alignment at the arcsecond level. The Kite demonstration involves the articulation of one of the corner cubes to simulate SIM instrument geometrical changes while various performance metrics are evaluated based on the readings of the individual metrology gauges. The test performance metric compares the direct measurement of length changes by one metrology gauge against the computed estimate for the same based on the other five gauges.

Proceedings Article | 26 February 2003

Dim star fringe stabilization demonstration using pathlength feed-forward on the SIM testbed 3 (STB3)

Renaud Goullioud, Oscar Alvarez-Salazar, Bijan Nemati

Proceedings Volume 4852, (2003) https://doi.org/10.1117/12.460714

KEYWORDS: Interferometers, Stars, Metrology, Beam splitters, Interference (communication), Control systems, Space operations, Mirrors, Sensors, Motion measurement

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Future space-based optical interferometers such as the Space Interferometer Mission require fringe stabilization to the level of nanometers in order to produce astrometric data at the micro-arc-second level. Even the best attitude control system available to date will not be able to stabilize the attitude of a several thousand pound spacecraft to a few milli-arc-seconds. Active pathlength control is usually implemented to compensate for attitude drift of the spacecraft. This issue has been addressed in previous experiments while tracking bright stars. In the case of dim stars, as the sensor bandwidth falls below one hertz, feedback control will not provide sufficient rejection. However, stabilization of the fringes from a dim-star down to the nanometer level can be done open loop using information from additional interferometers looking at bright guide stars. The STB3 testbed developed at the Jet Propulsion Laboratory features three optical interferometers sharing a common baseline, dynamically representative to the SIM interferometer. An artificial star feeding the interferometers is installed on a separate optics bench. Voice coils are used to simulate the attitude motion of the spacecraft by moving the entire bench. Data measured on STB3 show that fringe motion of a dim star due to spacecraft attitude changes can be attenuated by 80 dB at 0.1Hz without feedback control, using only information from two guide stars. This paper describes the STB3 setup, the pathlength feed-forward architecture, implementation issues and data collected with the system.

Proceedings Article | 26 February 2003

Mitigation of atmospheric effects in SIM's astrometric interferometer testbed 3

Oscar Alvarez-Salazar, Renaud Goullioud, Bijan Nemati, Alireza Azizi

Proceedings Volume 4852, (2003) https://doi.org/10.1117/12.460724

KEYWORDS: Interferometers, Stars, Metrology, Atmospheric sciences, Atmospheric optics, Signal to noise ratio, Atmospheric propagation, Filtering (signal processing), Optical tracking, Electronic filtering

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The Space Interferometry Mission's (SIM) shared-baseline astrometric interferometer System Test Bed 3 (STB3) has been constructed at JPL. STB3's objective is to use two of its interferometers (guides) for low frequency (0 to 1 Hz) fringe stabilization in the third one (science). This approach - being proposed for the first time in the context of space based observatories - is needed given the dim nature of science stars to be observed by SIM. Fringe stability is mostly affected by the low frequency attitude motion of the test bed's instrument table, with the inevitable exception of instrument vibration, thermal drift, and atmospheric fluctuations. Relative changes in table attitude cause optical path changes in the guide interferometers, which are tracked, linearly combined and fed forward to the science interferometer's active delay line to stabilize its optical path. This technique for tracking fringes in the science interferometer is possible because the position of the guide stars relative to the science star is well known. This open loop fringe tracking technique is dubbed Path-length Feed Forward, or PFF. In STB3, current fringe stability in the science interferometer using the PFF technique is at 50 to 60 nanometers RMS (from 0 to 500 Hz). Compare this to 15 to 20 nm RMS fringe stability in the guide interferometers, which operate in closed loop mode. Vibration, thermal drift and atmospherics in the science and guide interferometers are largely eliminated with the use of an internal metrology system. By design, mechanical vibrations are above the bandwidth of the interferometer system, and are passively rejected. Nevertheless, the internal metrology system can easily reject current low-level vibrations in STB3 down to the 6-nanometer RMS level. Fringe tracking error in the science interferometer due to atmospherics is currently about 40 nanometers RMS at frequencies below 1.0 Hz. In SIM, the error in this low frequency band must be no more than 6 nm RMS. This error arises because the optical path stabilized by the internal metrology system is not equal to taht of the starlight, so not all atmospheric fluctuations in the starlight path can be stabilized. Therefore, there is a need to reduce the strength of atmospheric fluctuations or to filter them from the PFF command. In STB3 the strength of atmospheric fluctuations is already reduced with the use of optical path enclosures, which brought these fluctuations down from ~170nm RMS to their current levels of ~66nm RMS with a spread of 20nm. Simulations show that signal to noise ratios are generally not sufficient to filter atmospheric errors on-line.

Proceedings Article | 5 July 2000

Demonstration of pathlength feed-forward for precision dim-star astrometry

Bijan Nemati

Proceedings Volume 4006, (2000) https://doi.org/10.1117/12.390171

KEYWORDS: Interferometers, Stars, Metrology, Control systems, Interferometry, Optical testing, Sensors, Antimony, Optical benches, Wavefronts

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The Space Interferometry Mission (SIM) is a high precision, space-based interferometer designed to achieve micro- arcsecond astrometric resolution. Many of the interesting science targets for SIM astrometry are dim enough that neither the pointing nor the pathlength control necessary for observing fringes can be performed using the usual closed-loop control techniques. The strategy in these cases is to feed forward the required control signals for the dim- star interferometer using other information, including two other interferometers operating simultaneously and locked on bright `guide' stars. The STB-3 testbed at the Jet Propulsion Laboratory, composed of three optical interferometers with a common baseline, is designed to develop these technologies for SIM. In its first phase, to be completed by spring 2000, STB-3 is expected to demonstrate pathlength feed-forward on an optical bench. Here we describe the technique used and the status of this experiment.

Proceedings Article | 28 August 1998

Starlight beam misalignment in optical synthesis imaging

Bijan Nemati, Alan Duncan

Proceedings Volume 3356, (1998) https://doi.org/10.1117/12.324435

KEYWORDS: Synthetic apertures, Visibility, Interferometers, Image resolution, Stars, Interferometry, Optical interferometry, Wavefronts, Light, Astronomical imaging

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Optical interferometry and interferometric synthesis imaging are being recognized as very important to the future of high resolution space-based astronomy. In this paper, an overview of optical interferometric imaging is presented and the effect of starlight beam misalignment in optical synthesis imaging is studied using a computer model. These studies will be augmented by laboratory synthesis imaging experiments designed to investigate these issues further.

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