Your search keyword '"Miko, Laddawan"' showing total 8 results

1. Design and testing of a low-resolution NIR spectrograph for the EXoplanet Climate Infrared TElescope

Author

Bernard, Lee, Jensen, Logan, Gamaunt, Johnathan, Butler, Nat, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel P., Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen F., McClelland, Ryan, Miko, Laddawan R., Mugnai, Lorenzo V., Nagler, Peter, Netterfield, C. Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory S., Waczynski, Augustyn, Waldmann, Ingo, Bernard, Lee, Jensen, Logan, Gamaunt, Johnathan, Butler, Nat, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel P., Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen F., McClelland, Ryan, Miko, Laddawan R., Mugnai, Lorenzo V., Nagler, Peter, Netterfield, C. Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory S., Waczynski, Augustyn, and Waldmann, Ingo

Abstract

The EXoplanet Climate Infrared TElescope (EXCITE) experiment is a balloon-borne, purpose-designed mission to measure spectroscopic phase curves of short-period extrasolar giant planets (EGPs, or "hot Jupiters"). Here, we present EXCITE's principal science instrument: a high-throughput, single-object spectrograph operating in the 0.8-2.5 mu m and 2.5-4.0 mu m bands with R >= 50. Our compact design achieves diffraction-limited, on-axis performance with just three powered optics: two off-axis parabolic mirrors and a CaF2 prism. We discuss the optical and mechanical design, the expected optical performance of the spectrograph, and summarize the tolerances needed to achieve that performance. We also discuss plans for establishing alignment of the optics and verifying the optical performance.

Published

2022

2. Design and testing of a low-resolution NIR spectrograph for the EXoplanet Climate Infrared TElescope

Author

Bernard, Lee, Jensen, Logan, Gamaunt, Johnathan, Butler, Nat, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel P., Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen F., McClelland, Ryan, Miko, Laddawan R., Mugnai, Lorenzo V., Nagler, Peter, Netterfield, C. Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory S., Waczynski, Augustyn, Waldmann, Ingo, Bernard, Lee, Jensen, Logan, Gamaunt, Johnathan, Butler, Nat, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel P., Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen F., McClelland, Ryan, Miko, Laddawan R., Mugnai, Lorenzo V., Nagler, Peter, Netterfield, C. Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory S., Waczynski, Augustyn, and Waldmann, Ingo

Abstract

The EXoplanet Climate Infrared TElescope (EXCITE) experiment is a balloon-borne, purpose-designed mission to measure spectroscopic phase curves of short-period extrasolar giant planets (EGPs, or "hot Jupiters"). Here, we present EXCITE's principal science instrument: a high-throughput, single-object spectrograph operating in the 0.8-2.5 mu m and 2.5-4.0 mu m bands with R >= 50. Our compact design achieves diffraction-limited, on-axis performance with just three powered optics: two off-axis parabolic mirrors and a CaF2 prism. We discuss the optical and mechanical design, the expected optical performance of the spectrograph, and summarize the tolerances needed to achieve that performance. We also discuss plans for establishing alignment of the optics and verifying the optical performance.

Published

2022

3. Properties and characteristics of the WFIRST H4RG-10 detectors

Author

Mosby, Jr., Gregory, Rauscher, Bernard J., Bennett, Chris, Cheng, Edward . S., Cheung, Stephanie, Cillis, Analia, Content, David, Cottingham, Dave, Foltz, Roger, Gygax, John, Hill, Robert J., Kruk, Jeffrey W., Mah, Jon, Meier, Lane, Merchant, Chris, Miko, Laddawan, Piquette, Eric C., Waczynski, Augustyn, Wen, Yiting, Mosby, Jr., Gregory, Rauscher, Bernard J., Bennett, Chris, Cheng, Edward . S., Cheung, Stephanie, Cillis, Analia, Content, David, Cottingham, Dave, Foltz, Roger, Gygax, John, Hill, Robert J., Kruk, Jeffrey W., Mah, Jon, Meier, Lane, Merchant, Chris, Miko, Laddawan, Piquette, Eric C., Waczynski, Augustyn, and Wen, Yiting

Abstract

The Wide-Field Infrared Survey Telescope (WFIRST) will answer fundamental questions about the evolution of dark energy over time and expand the catalog of known exoplanets into new regions of parameter space. Using a Hubble-sized mirror and 18 newly developed HgCdTe 4K x 4K photodiode arrays (H4RG-10), WFIRST will measure the positions and shapes of hundreds of millions of galaxies, the light curves of thousands of supernovae, and the microlensing signals of over a thousand exoplanets toward the bulge of the Galaxy. These measurements require unprecedented sensitivity and characterization of the Wide Field Instrument (WFI), particularly its detectors. The WFIRST project undertook an extensive detector development program to create focal plane arrays that meet these science requirements. These prototype detectors have been characterized and their performance demonstrated in a relevant space-like environment (thermal vacuum, vibration, acoustic, and radiation testing), advancing the H4RG-10's technology readiness level (TRL) to TRL-6. We present the performance characteristics of these TRL-6 demonstration devices., Comment: 47 pages, 19 figures manuscript submitted to JATIS

Published

2020

4. Properties and characteristics of the WFIRST H4RG-10 detectors

Author

Mosby, Jr., Gregory, Rauscher, Bernard J., Bennett, Chris, Cheng, Edward . S., Cheung, Stephanie, Cillis, Analia, Content, David, Cottingham, Dave, Foltz, Roger, Gygax, John, Hill, Robert J., Kruk, Jeffrey W., Mah, Jon, Meier, Lane, Merchant, Chris, Miko, Laddawan, Piquette, Eric C., Waczynski, Augustyn, Wen, Yiting, Mosby, Jr., Gregory, Rauscher, Bernard J., Bennett, Chris, Cheng, Edward . S., Cheung, Stephanie, Cillis, Analia, Content, David, Cottingham, Dave, Foltz, Roger, Gygax, John, Hill, Robert J., Kruk, Jeffrey W., Mah, Jon, Meier, Lane, Merchant, Chris, Miko, Laddawan, Piquette, Eric C., Waczynski, Augustyn, and Wen, Yiting

Abstract

The Wide-Field Infrared Survey Telescope (WFIRST) will answer fundamental questions about the evolution of dark energy over time and expand the catalog of known exoplanets into new regions of parameter space. Using a Hubble-sized mirror and 18 newly developed HgCdTe 4K x 4K photodiode arrays (H4RG-10), WFIRST will measure the positions and shapes of hundreds of millions of galaxies, the light curves of thousands of supernovae, and the microlensing signals of over a thousand exoplanets toward the bulge of the Galaxy. These measurements require unprecedented sensitivity and characterization of the Wide Field Instrument (WFI), particularly its detectors. The WFIRST project undertook an extensive detector development program to create focal plane arrays that meet these science requirements. These prototype detectors have been characterized and their performance demonstrated in a relevant space-like environment (thermal vacuum, vibration, acoustic, and radiation testing), advancing the H4RG-10's technology readiness level (TRL) to TRL-6. We present the performance characteristics of these TRL-6 demonstration devices., Comment: 47 pages, 19 figures manuscript submitted to JATIS

Published

2020

5. Laboratory and Sky Testing Results for the TIS H4RG-10 4k x 4k, 10 micron Visible CMOS-Hybrid Detector

Author

NAVAL OBSERVATORY WASHINGTON DC, Dorland, Bryan N, Hennessy, Gregory S, Zacharias, Norbert, Monet, David G, Harris, Hugh, Rollins, Chris, Shu, Peter, Miko, Laddawan, Mott, Brent, Waczynski, Augustyn, NAVAL OBSERVATORY WASHINGTON DC, Dorland, Bryan N, Hennessy, Gregory S, Zacharias, Norbert, Monet, David G, Harris, Hugh, Rollins, Chris, Shu, Peter, Miko, Laddawan, Mott, Brent, and Waczynski, Augustyn

Abstract

We present both laboratory and telescope testing results describing the performance of the H4RG-10 CMOS-Hybrid detector. The H4RG-10 is the largest visible hybrid array currently in existence and shows great potential for use in future space missions. We report read noise, dark current, pixel connectivity, persistence, and inter-pixel capacitance measurements for the temperature range 110-240 K. We report on quantitative astrometric and qualitative photometric performance of the instrument based on observations made at USNO's Flagstaff Station observatory and establish an upper limit to the astrometric performance of the detector. We discuss additional testing and future work associated with improving detector performance., Published in Proceedings of SPIE, v6690 article ID 66900D, 2007. The original document contains color images. Prepared in collaboration with NOBS Flagstaff Station, Flagstaff, AZ, the Detector Systems Branch, NASA Goddard Space Flight Center, Greenbelt, MD, Research Support Instruments, Lanham, MD, and Global Science and Technology, Inc., Greenbelt, MD.

Published

2007

6. The EXoplanet Climate Infrared TElescope (EXCITE)

Author

Nagler, Peter C., Bernard, Lee, Bocchieri, Andrea, Butler, Nathaniel, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gamaunt, John, Gong, Qian, Hartley, John, Helson, Kyle, Jensen, Logan, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldmann, Ingo, Evans, Christopher J., Bryant, Julia J., Motohara, Kentaro, Nagler, Peter C., Bernard, Lee, Bocchieri, Andrea, Butler, Nathaniel, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gamaunt, John, Gong, Qian, Hartley, John, Helson, Kyle, Jensen, Logan, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldmann, Ingo, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Abstract

The EXoplanet Climate Infrared TElescope (EXCITE) is a 0.5 meter near-infrared spectrograph that will fly from a high altitude balloon platform. EXCITE is designed to perform phase-resolved spectroscopy – continuous spectroscopic observations of a planet’s entire orbit about its host star – of transiting hot Jupiter-type exoplanets. With spectral coverage from 0.8 – 4 um, EXCITE will measure the peak of a target’s spectral energy distribution and the spectral signatures of many hydrogen and carbon-containing molecules. Phase curve observations are highly resource intensive, especially for shared-use facilities, and they require exceptional photometric stability that is difficult to achieve, even from space. In this work, we introduce the EXCITE experiment and explain how it will solve both these problems. We discuss its sensitivity and stability, then provide an update on its current status as we work toward a 2024 long duration science flight.

7. The EXoplanet Climate Infrared TElescope (EXCITE)

Author

Nagler, Peter C., Bernard, Lee, Bocchieri, Andrea, Butler, Nathaniel, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gamaunt, John, Gong, Qian, Hartley, John, Helson, Kyle, Jensen, Logan, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldmann, Ingo, Evans, Christopher J., Bryant, Julia J., Motohara, Kentaro, Nagler, Peter C., Bernard, Lee, Bocchieri, Andrea, Butler, Nathaniel, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gamaunt, John, Gong, Qian, Hartley, John, Helson, Kyle, Jensen, Logan, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldmann, Ingo, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Abstract

The EXoplanet Climate Infrared TElescope (EXCITE) is a 0.5 meter near-infrared spectrograph that will fly from a high altitude balloon platform. EXCITE is designed to perform phase-resolved spectroscopy – continuous spectroscopic observations of a planet’s entire orbit about its host star – of transiting hot Jupiter-type exoplanets. With spectral coverage from 0.8 – 4 um, EXCITE will measure the peak of a target’s spectral energy distribution and the spectral signatures of many hydrogen and carbon-containing molecules. Phase curve observations are highly resource intensive, especially for shared-use facilities, and they require exceptional photometric stability that is difficult to achieve, even from space. In this work, we introduce the EXCITE experiment and explain how it will solve both these problems. We discuss its sensitivity and stability, then provide an update on its current status as we work toward a 2024 long duration science flight.

8. Design and testing of a low-resolution NIR spectrograph for the EXoplanet Climate Infrared TElescope

Author

Bernard, Lee, Jensen, Logan, Gamaunt, John, Butler, Nathaniel, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Nagler, Peter, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldman, Ingo, Evans, Christopher J., Bryant, Julia J., Motohara, Kentaro, Bernard, Lee, Jensen, Logan, Gamaunt, John, Butler, Nathaniel, Bocchieri, Andrea, Changeat, Quentin, D'Alessandro, Azzurra, Edwards, Billy, Gong, Qian, Hartley, John, Helson, Kyle, Kelly, Daniel, Klangboonkrong, Kanchita, Kleyheeg, Annalies, Lewis, Nikole, Li, Steven, Line, Michael, Maher, Stephen, McClelland, Ryan, Miko, Laddawan, Mugnai, Lorenzo, Nagler, Peter, Netterfield, Barth, Parmentier, Vivien, Pascale, Enzo, Patience, Jennifer, Rehm, Tim, Romualdez, Javier, Sarkar, Subhajit, Scowen, Paul, Tucker, Gregory, Waczynski, Augustyn, Waldman, Ingo, Evans, Christopher J., Bryant, Julia J., and Motohara, Kentaro

Abstract

The EXoplanet Climate Infrared TElescope (EXCITE) experiment is a balloon-borne, purpose-designed mission to measure spectroscopic phase curves of short-period extrasolar giant planets (EGPs, or “hot Jupiters”). Here, we present EXCITE’s principal science instrument: a high-throughput, single-object spectrograph operating in the 0.8-2.5 µm and 2.5-4.0 µm bands with R≥50. Our compact design achieves diffraction-limited, on-axis performance with just three powered optics: two off-axis parabolic mirrors and a CaF2 prism. We discuss the optical and mechanical design, the expected optical performance of the spectrograph, and summarize the tolerances needed to achieve that performance. We also discuss plans for establishing alignment of the optics and verifying the optical performance.