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1. The terrestrial organism and biogeochemistry spatial sampling design for the National Ecological Observatory Network

Author

Barnett, David T, Duffy, Paul A, Schimel, David S, Krauss, Rachel E, Irvine, Kathryn M, Davis, Frank W, Gross, John E, Azuaje, Elena I, Thorpe, Andrea S, Gudex-Cross, David, Patterson, Michael, McKay, Jalynda M, McCorkel, Joel T, and Meier, Courtney L

Subjects
National Ecological Observatory Network, sampling terrestrial organisms and biogeochemistry, spatial sample design, Special Feature: NEON Design, Ecological Applications, Ecology, Zoology
Published
2019

5. Landsat 9 thermal infrared sensor 2 (TIRS-2) radiometric calibration and potential future Landsat thermal band efforts.

Author

Montanaro, Matthew, McCorkel, Joel, Pearlman, Aaron, Efremova, Boryana, Wenny, Brian, Lunsford, Allen, Reuter, Dennis, Hair, Jason, and Jhabvala, Murzy

Subjects
*LANDSAT satellites, *SPACE flight, *QUANTUM wells, *PRODUCT image, *FLIGHT testing
Abstract

The Thermal Infrared Sensor 2 (TIRS-2) instrument on Landsat 9 provides the latest generation of thermal infrared Earth observations for the Landsat program. Routine thermal band measurements began in 1982 with Landsat 4 and its single-channel design and evolved in 2013 to a dual-band design with the TIRS instrument on Landsat 8, thereby improving derived surface temperature accuracy. The TIRS-2 instrument is a near-copy of the TIRS design but with expanded electronic redundancies to prevent single point failures and modifications to address a stray light problem found with the original TIRS design. As with all Landsat image data, careful efforts were made both pre-flight and on-orbit to fully characterize and calibrate the TIRS-2 instrument so that the final image products were as accurate as possible. SI-traceable calibration functions were derived from pre-flight spectral and radiometric test data to convert raw detector output into at-aperture radiance units for use in the U.S. Geological Survey Landsat Level 1 product generation system. Additionally, performance metrics for noise, stability, uniformity, and accuracy were calculated from test datasets and compared to requirements. Equivalent datasets were acquired during on-orbit commissioning using the onboard calibration sources to adjust the calibration functions for actual in-flight operating conditions. With updated calibration coefficients, users can expect data products that have met or exceeded requirements: Image noise (NEdT) is less than 100 mK; Radiometric instability is less than 0.1% over an orbit; Stray light effects are less than 1% maximum (more than a 10x improvement over the Landsat 8 TIRS instrument); and absolute radiometric accuracy is approximately 1.4% (over source temperatures of 260 to 330 K). As TIRS-2 is expected to continue the Landsat thermal band legacy for the next decade or more, efforts are already underway to develop the next generation thermal sensor design. Engineers at NASA Goddard Space Flight Center have recently flight tested the Compact Thermal Imager (CTI) which demonstrates an improved detector design utilizing strained-layer superlattice (SLS) technology providing higher quantum efficiencies than the quantum well infrared photometer (QWIP) technology utilized by the TIRS instruments. Additionally, plans are being formulated for the next generation Landsat series, known as Landsat-Next. The instrument design for this system will increase the number of thermal infrared bands to five with increased spatial resolution, thereby providing expanded science capability. These potential future improvements in thermal band measurements will ensure the continuing legacy of the Landsat thermal infrared collection well into the future. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Statistical validation of ionospheric electron density profiles retrievals from GOES geosynchronous satellites

Author

Zakharenkova Irina, Cherniak Iurii, Gleason Scott, Hunt Douglas, Freesland Douglas, Krimchansky Alexander, McCorkel Joel, Ramsey Graeme, and Chapel Jim

Subjects
ionospheric density, electron density profiles, radio occultation, gps, geostationary satellite, Meteorology. Climatology, QC851-999
Abstract

In this paper, we discuss a novel retrieval of ionospheric electron density profiles using the Radio Occultation (RO) technique applied to measurements captured by the Global Positioning System (GPS) receivers onboard two Geostationary Operational Environmental Satellites (GOES). The GOES satellites operate at ~35,800 km altitude and are primarily weather satellites that operationally contribute continuous remote-sensing data for real-time weather forecasting, as well as near-Earth environment monitoring and Sun observations. The GPS receivers onboard GOES-16 and GOES-17 satellites can track GPS signals propagated through the Earth’s atmosphere, and although the receivers are primarily designed for navigation and station-keeping maneuvers, these GPS measurements that traverse the Earth’s atmosphere can be used to retrieve the ionospheric electron density profiles. This process poses a range of technical challenges. GOES RO links are different from the traditional low Earth orbit (LEO) RO geometry since the receiver is located in an orbit that is higher in altitude than the GPS constellation of transmitters. Additionally, the GPS receivers onboard GOES satellites provide only single-frequency GPS L1 observations and have clocks much less stable than those typically used for RO measurements. The geographical distribution of the retrieved GEO-based RO profiles was found to be uniquely constrained and repeatable based on the relative geostationary fixed positions in the Earth-Centered Earth Fixed reference frame with respect to the GPS constellation orbiting at lower altitude, and significantly different from the coverage patterns of LEO-based RO missions. We demonstrate the successful application of the proposed RO profiling technique with a statistically significant set of GPS observations from GOES-16 and GOES-17 satellites over several years of data collection. This enabled us to retrieve more than 10,000 ionospheric electron density profiles with a maximum altitude of up to 1000–2000 km, much higher than any existing LEO-based RO mission. We demonstrate good performance of GEO-based RO measurements for properly specifying the vertical distribution of ionospheric plasma density by comparing the profiles dataset from the GOES RO experiment with independent reference observations – ground-based ionosondes and LEO-based RO missions, as well as model simulation results provided by the empirical International Reference Ionosphere model. Over multiple years of observations, statistical analysis of discrepancies between the ionospheric F2 layer peak parameters (peak density and height) derived from geosynchronous GOES observations and reference measurements was conducted. This analysis reveals a very good agreement between GOES RO electron density profiles and independent types of measurements in both the F2 peak and the profile shape.

Published
2023
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9. Current status of Landsat program, science, and applications

Author

Wulder, Michael A., Loveland, Thomas R., Roy, David P., Crawford, Christopher J., Masek, Jeffrey G., Woodcock, Curtis E., Allen, Richard G., Anderson, Martha C., Belward, Alan S., Cohen, Warren B., Dwyer, John, Erb, Angela, Gao, Feng, Griffiths, Patrick, Helder, Dennis, Hermosilla, Txomin, Hipple, James D., Hostert, Patrick, Hughes, M. Joseph, Huntington, Justin, Johnson, David M., Kennedy, Robert, Kilic, Ayse, Li, Zhan, Lymburner, Leo, McCorkel, Joel, Pahlevan, Nima, Scambos, Theodore A., Schaaf, Crystal, Schott, John R., Sheng, Yongwei, Storey, James, Vermote, Eric, Vogelmann, James, White, Joanne C., Wynne, Randolph H., and Zhu, Zhe

Published
2019
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12. Prelaunch Spectral Characterization of the Operational Land Imager-2.

Author

Barsi, Julia A., Donley, Eric, Goldman, Michelle, Kampe, Thomas, Markham, Brian L., McAndrew, Brendan, McCorkel, Joel, Morland, Eric, Pedelty, Jeffrey A., Pharr, James, Rodriguez, Michael R., Shuman, Timothy M., Stutheit, Cameron, and Sushkov, Andrei B.

Subjects
FOCAL planes, SPECTRAL sensitivity, LASER measurement, LANDSAT satellites, MONOCHROMATORS, RADIANCE
Abstract

The Landsat-9 satellite, launched in September 2021, carries the Operational Land Imager-2 (OLI-2) as one of its payloads. This instrument is a clone of the Landsat-8 OLI and its mission is to continue the operational land imaging of the Landsat program. The OLI-2 instrument is not significantly different from OLI though the instrument-level pre-launch spectral characterization process was much improved. The focal plane modules used on OLI-2 were manufactured as spares for OLI and much of the spectral characterization of the components was performed for OLI. However, while the spectral response of the fully assembled OLI was characterized by a double monochromator system, the OLI-2 spectral characterization made use of the Goddard Laser for Absolute Measurement of Radiance (GLAMR). GLAMR is a system of tunable lasers that cover 350–2500 nm which are fiber-coupled to a 30 in integrating sphere permanently monitored by NIST-traceable radiometers. GLAMR allowed the spectral characterization of every detector of the OLI-2 focal plane in nominal imaging conditions. The spectral performance of the OLI-2 was, in general, much better than requirements. The final relative spectral responses (RSRs) represent the best characterization any Landsat instrument spectral response. This paper will cover the results of the spectral characterization from the component-level to the instrument-level of the Landsat-9 OLI-2. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Time Resolved Irradiance of an Integrating Sphere Illuminated by a Mode-Locked Optical Parametric Oscillator

Author

McAndrew, Brendan and McCorkel, Joel

Subjects
Engineering (General)
Abstract

Tunable laser based illumination sources have been adopted by a number of recent hyperspectral instruments for pre-launch spectral radiometric calibration. Some of these sources use mode-locked cavity configurations, which produce a pulse train and create an undesirable fluctuation in the radiometric source at the mode locking frequency. Although typically this frequency is several orders of magnitude higher than the instrument response, care must be taken to ensure the resultant calibration is not biased due to detector or electronic saturation effects. The temporal averaging properties of an integrating sphere can be used to reduce high frequency fluctuations to an acceptable level. In this work, the time resolved output of an integrating sphere coupled with a mode-locked source was measured. A 76 cm diameter sphere with 30 cm output aperture was illuminated using a mode-locked pulse train at 76 MHz, with single pulse durations of 12 ps. The time constant of the sphere was found to be 36 ns, and the resultant temporal averaging of pulses produced a maximum time varying irradiance at the output of 20% of the mean. The form of this time variance is a sawtooth pattern, with a sharp rise during the introduction of each pulse into the sphere followed by a slower decay between pulses. A comparison of instrument calibration data generated with this integrating sphere using both a mode locked source and a continuous wave source is also given. .

Published
2019

14. Landsat 9: Mission Status and Prelaunch Instrument Performance Characterization and Calibration

Author

Markham, Brian, Barsi, Julia, Donley, Eric, Efremova, Boryana, Hair, Jason, Jenstrom, Del, Kaita, Edward, Knight, Ed, Kvaran, Geir, McCorkel, Joel, Montanaro, Matthew, Morland, Eric, Pearlman, Aaron, Pedelty, Jeffrey, and Wenny, Brian

Subjects
Instrumentation And Photography
Abstract

Landsat 9 is currently under development as a joint effort between NASA and the United States Geological Survey (USGS). Landsat 9 is essentially a rebuild of Landsat 8 and has the same two sensors, the Operational Land Imager (OLI) and the Thermal Imaging Sensor (TIRS). The OLI-2 on Landsat 9, is being built by Ball Aerospace and has completed its pre-launch characterization and calibration and is scheduled to be delivered in the summer of 2019. The TIRS-2, being built by Goddard Space Flight Center, is currently undergoing testing through Spring 2019 and also scheduled for summer 2019 delivery. Several improvements to the characterization of both instruments have been incorporated into the testing plan, including improved spectral and radiometric characterization. The instruments will then be integrated onto the spacecraft being built by Northrop Grumman Innovation Systems (NGIS). The mission is targeted to launch as early as December 2020 on an Atlas-5.

Published
2019

15. Landsat 9 TIRS-2 Spectral Response Test: Updates & Perspective

Author

Pearlman, Aaron, Efremova, Boryana, Lunsford, Allen, McCorkel, Joel, Simon, Amy, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor 2 (TIRS-2) pre-launch spectral characterization at telescope and detector subsystem level provided a strong indication that the spectral response requirements will be met. Confidence in the validity of these results was strengthened through comparison to component-level measurements. This work reviews the modifications to the test setup to reduce spectral response uncertainties further in preparation for instrument-level testing. We developed a methodology to improve alignment repeatability of the upgraded system. Preliminary indications show that the spectral response will contribute a relatively small amount to the overall TIRS-2 radiometric uncertainty budget, which is expected to meet its radiometric requirements. Through spectral response testing, as part of a comprehensive pre-launch test program, TIRS-2 is expected to achieve the performance necessary for a variety of environmental applications.

Published
2019

16. First Results from Laser-Based Spectral Characterization of Landsat 9 Operational Land Imager-2

Author

McCorkel, Joel, McAndrew, Brendan, Barsi, Julia, Markham, Brian, Pharr, James, Rodriguez, Michael, Shuman, Tim, Sushkov, Andrei, and Zukowski, Barbara

Subjects
Earth Resources And Remote Sensing, Instrumentation And Photography
Abstract

Landsat 9 will continue the Landsat data record into its fifth decade with launch scheduled for December 2020. The two instruments on Landsat 9 are Thermal Infrared Sensor-2 (TIRS-2) and Operational Land Imager-2 (OLI-2). OLI-2 is a nine-channel pushbroom imager with a 15-degree field of view that will have a 16-day measurement cadence from its nominal 705-km orbit altitude. A key aspect of the data that will be produced by OLI-2 is its spectral fidelity which enables countless science applications. The prelaunch test campaign for spectral characterization of OLI-2 was substantially improved relative to the methodology used for OLI: the full spectral response of every detector was characterized with greater accuracy, sampling, and precision. This paper will describe how this was accomplished with a tunable laser-based light source called Goddard Laser for Absolute Measurement of Radiance (GLAMR).

Published
2019

17. GOES-17 Advanced Baseline Imager Performance Recovery Summary

Author

McCorkel, Joel, Van Naarden, John, Lindsey, Daniel, Efremova, Boryana, Coakley, Monica M, Black, Mason, and Krimchansky, Alexander

Subjects
Earth Resources And Remote Sensing
Abstract

The 17th Geostationary Operational Environmental Satellite (GOES-17) was launched on 1 March 2018. The Advanced Baseline Imager (ABI) is the primary instrument on the GOES-R series for weather and environmental monitoring. The GOES-17 ABI (flight model 2) experienced a degradation in its thermal system that limits ABI's ability to shed solar heat load. This limitation resulted in significant reduction in performance after initial turn on with only 3 of 16 spectral channels expected to be available for much of the year. A combined government/vendor team was tasked with optimizing the operation of ABI to recapture as much performance as possible. By modifying the operational configuration and sensor parameters, the team was able to regain over 97% imaging capability.This was accomplished by taking advantage of the considerably flexible nature of ABI's design to adapt its configuration to the new reality and improve capabilities for many of ABI's subsystems. The significant differences in operational configuration, sensor parameter optimization, and algorithm optimization will be discussed as well as their impact on performance and data availability.

Published
2019

18. LANDSAT 9 Thermal Infrared Sensor 2 Spectral Response Test: Updates and Perspective

Author

Pearlman, Aaron J, Efremova, Boryana, Lundsford, Allen, McCorkel, Joel, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor 2 (TIRS-2) pre-launch spectral characterization at telescope and detector subsystem level provided a strong indication that the spectral response requirements will be met. Confidence in the validity of these results was strengthened through comparison to component-level measurements. This work reviews the modifications to the test setup to reduce spectral response uncertainties further in preparation for instrument-level testing. We developed a methodology to improve alignment repeatability of the upgraded system. Preliminary indications show that the spectral response will contribute a relatively small amount to the overall TIRS-2 radiometric uncertainty budget, which is expected to meet its radiometric requirements. Through spectral response testing, as part of a comprehensive pre-launch test program, TIRS-2 is expected to achieve the performance necessary for a variety of environmental applications.

Published
2019

20. Landsat 9 TIRS-2 Performance Results Based on Subsystem-Level Testing

Author

Pearlman, Aaron J, McCorkel, Joel T, Montanaro, Matthew, Efremova, Boryana, Wenny, Brian N, Lunsford, Allen, Simon, Amy, Hair, Jason, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

Landsat 9 is the next in the series of Landsat satellites and has a complement of two pushbroom imagers: Operational Land Imager-2 (OLI-2) that samples the solar reflective spectrum with nine channels and Thermal Infrared Sensor-2 (TIRS-2) samples the thermal infrared spectrum with two channels. The first builds of these sensors, OLI and TIRS, were launched on Landsat 8 in 2013 and Landsat 9 is expected to launch in December 2020. TIRS-2 is designed and built to continue the Landsat data record and satisfy the needs of the remote sensing community. There are two sets of requirements considered for planning the component, subsystem and instrument level tests for TIRS-2: performance requirements and Special Calibration Test Requirements (SCTR). The performance requirements specify key spectral, spatial, radiometric, and operational parameters of TIRS-2 while the SCTRs specify parameters of how the instrument is tested. Several requirements can only be verified at the instrument level, but many performance metrics can be assessed earlier in prelaunch testing at the subsystem level. A test program called TIRS Imaging Performance and Cryoshell Evaluation (TIPCE) was developed to characterize TIRS-2 spectral, spatial, and scattered-light rejection performance at the telescope and detector subsystem level. There were three thermal vacuum campaigns in TIPCE that occurred from November 2017 to March 2018. This work shows results of TIPCE data analysis which provide confidence that key requirements will be met at instrument level with a few minor waivers. A full complement of performance testing will be done at the TIRS-2 instrument level for final verification in late 2018 through Spring 2019.

Published
2018

21. Landsat 9 TIRS-2 Architecture and Design

Author

Hair, Jason H, Reuter, Dennis C, Tonn, Synthia L, McCorkel, Joel, Simon, Amy A, Djam, Melody, Alexander, David, Ballou, Kevin, Barclay, Richard, Coulter, Phillip, Edick, Michael, Efremova, Boryana, Finneran, Paul, Florez, Jose, Graham, Steven, Harbert, Kenneth, Hewitt, Dennis, Hickey, Michael, Hicks, Samantha, Hoge, William, Jhabvala, Murzy, Lilly, Carol, Lunsford, Allen, Mann, Laurie, Masters, Candace, Montanaro, Matthew, Muench, Theodore, Otero, Veronica, Parong, Fil, Pearlman, Aaron, Penn, Jonathan, Vigneau, Danielle, and Wenny, Brian

Subjects
Earth Resources And Remote Sensing
Published
2018

22. Landsat 9 Thermal Infrared Sensor 2 Pre-Launch Characterization: Initial Imaging and Spectral Performance Results

Author

Pearlman, Aaron, McCorkel, Joel, Montanaro, Matthew, Efremova, Boryana, Wenny, Brian, Lunsford, Allen, Simon, Amy, Hair, Jason, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor-2 (TIRS-2) scheduled to launch in December 2020 aboard Landsat 9 will continue Landsat's four decade-long legacy of providing moderate resolution thermal imagery from low earth orbit (at 705 km) for environmental applications. Like the Thermal Infrared Sensor aboard Landsat 8, it is a pushbroom sensor with a cross-track field of view of 15 and provides two spectral channels at 10.8 and 12 micrometers. To ensure radiometric, spatial, and spectral performance, a comprehensive pre-launch testing program is being conducted at NASA Goddard Space Flight Center at the component, subsystem, and instrument level. This effort will focus on the results from the subsystem level testing to assess TIRS-2 imaging performance including focus, spatial performance, and stray light rejection. It is also used to provide a preliminary assessment of spectral performance. The TIRS-2 subsystem is placed in a thermal vacuum chamber with the calibration ground support equipment, which provides a flexible blackbody illumination source and optics to assess imaging performance. Spectral performance is tested using a spectral response test setup with its own illumination source outside the chamber that propagates through the calibration ground support equipment in an optical configuration designed for this purpose. The results show that TIRS-2 performance is expected to meet all of its performance requirements with few waivers and deviations.

Published
2018

24. Landsat 9 Thermal Infrared Sensor 2 Subsystem-Level Spectral Test Results

Author

Efremova, Boryana, Pearlman, Aaron J, McCorkel, Joel, Montanaro, Matthew, Hickey, Michael, Lunsford, Allen, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

Results from the Thermal Infrared Sensor 2 (TIRS-2) prelaunch spectral characterization at telescope and detector subsystem level are presented. The derived relative spectral response (RSR) shape is expected to be very similar to the instrument-level spectral response and provides an initial estimate of the RSR and its differences to the component-level RSR measurements. Such differences were observed at TIRS- 1 and are likely a result of angular dependence of the spectral response of the detector. The subsystem RSR measurements also provide an opportunity for a preliminary assessment of the spectral requirements. Final requirements verification will be performed at future thermal vacuum environmental testing with the fully assembled TIRS-2 instrument.

Published
2018

25. Landsat 9 Thermal Infrared Sensor 2 Preliminary Stray Light Assessment

Author

Montanar, Matthew, McCorkel, Joel, Tveekrem, June, Stauder, John, Lunsford, Allen, Mentzell, Eric, Hair, Jason, and Reuter, Dennis

Subjects
Spacecraft Design, Testing And Performance, Lunar And Planetary Science And Exploration
Abstract

Although the Thermal Infrared Sensor 2 (TIRS-2) is a nearidentical copy of the Landsat 8/TIRS-1 instrument, an important design change to the optical system was designed to mitigate the stray light issue that plagued the TIRS-1 instrument [1, 2, 3]. This change involved the addition of several baffles strategically placed within the optical telescope to block the stray light paths that were present in the TIRS- 1 design. The specific optical changes were determined by first characterizing the TIRS-1 stray light paths on-orbit and then deriving a detailed optical model that was used to determine the locations and shapes of the mitigating baffles. The stray light design changes to the TIRS-2 instrument were confirmed through the initial thermal-vacuum characterization tests. Preliminary assessments of TIRS-2 indicate that the total stray light magnitude has been drastically reduced to a total magnitude of approximately 1% or less.

Published
2018

26. Landsat 9 Thermal Infrared Sensor 2 Architecture and Design

Author

Hair, Jason H, Reuter, Dennis C, Tonn, Synthia L, McCorkel, Joel T, Simon, Amy A, Djam, Melody, Alexander, David, Ballou, Kevin, Barclay, Richard, Coulter, Phillip, Edick, Michael, Efremova, Boryana, Finneran, Paul, Florez, Jose, Graham, Steven, Harbert, Kenneth, Hewitt, Dennis, Hickey, Michael, Hicks, Samantha, Hoge, William, Jhabvala, Murzban, Lilly, Carol, Lunsford, Allen, Mann, Laurie, Masters, Candace, Montanaro, Matthew, Muench, Theodore, Otero, Veronica, Parong, Fil, Pearlman, Aaron, Penn, Jonathan, Vigneau, Danielle, and Wenny, Brian

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor 2 (TIRS-2) will fly aboard the Landsat 9 spacecraft and leverages the Thermal Infrared Sensor (TIRS) design currently flying on Landsat 8. TIRS-2 will provide similar science data as TIRS, but is not a buildto-print rebuild due to changes in requirements and improvements in absolute accuracy. The heritage TIRS design has been modified to reduce the influence of stray light and to add redundancy for higher reliability over a longer mission life. The TIRS-2 development context differs from the TIRS scenario, adding to the changes. The TIRS-2 team has also learned some lessons along the way.

Published
2018

27. Characterization of Firefly, an Imaging Spectrometer Designed for Airborne Measurements of Solar-Induced Fluorescence

Author

Cook, Bruce, Corp, Lawrence, Clemens, Peter, Paynter, Ian, Nagol, Jyoteshwar, and McCorkel, Joel

Subjects
Instrumentation And Photography
Abstract

FIREFLY (Fluorescence Imaging of REd and Far-red Light Yield) is a compact, fine-resolution imaging spectrometer that was designed and assembled by Headwall Photonics (Fitchburg, MA, USA) in collaboration with NASA scientists for airborne measurements of Solar-Induced Fluorescence (SIF). FIREFLY is integrated into the next generation of NASA Goddard’s Lidar, Hyperspectral and Thermal airborne imager (G-LiHT; www.gliht.nasa.gov), providing a complete system for measuring, interpreting and scaling SIF emissions. Characterization of FIREFLY was performed here to evaluate its performance and suitability for retrieving SIF.

Published
2018
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28. LANDSAT 9 Thermal Infrared Sensor 2 Characterization Plan Overview

Author

McCorkel, Joel, Montanaro, Matthew, Efremova, Boryana, Pearlman, Aaron, Wenny, Brian, Lunsford, Allen, Simon, Amy, Hair, Jason, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

Landsat 9 will continue the Landsat data record into its fifth decade with a near-copy build of Landsat 8 with launch scheduled for December 2020. The two instruments on Landsat 9 are Thermal Infrared Sensor-2 (TIRS-2) and Operational Land Imager-2 (OLI-2). TIRS-2 is a two-channel pushbroom imager with a 15-degree field of view that will have a 16-day measurement cadence from its nominal 705-km orbit altitude. Its carefully developed instrument performance requirements and associated characterization plan will result in stable and well-understood science-quality imagery that will be used for environmental, economic and legal applications. This paper will present a summary of the plan for TIRS-2 prelaunch characterization at the component, subsystem, and instrument level.

Published
2018

29. Initial Pre-Launch Imaging and Spectral Characterization of Landsat 9 Thermal Infrared Sensor-2

Author

Pearlman, Aaron, McCorkel, Joel, Montanaro, Matthew, Efremova, Boryana, Wenny, Brian, Lunsford, Allen, Simon, Amy, Hair, Jason, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor-2 (TIRS-2) scheduled to launch in December 2020 aboard Landsat 9 will continue Landsat's four decade-long legacy of providing moderate resolution thermal imagery from low earth orbit (at 705 km) for environmental applications. Like the Thermal Infrared Sensor aboard Landsat 8, it is a pushbroom sensor with a cross-track field of view of 15 and provides two spectral channels at 10.8 and 12 micrometers To ensure radiometric, spatial, and spectral performance, a comprehensive pre-launch testing program is being conducted at NASA Goddard Space Flight Center at the component, subsystem, and instrument level. This effort will focus on the results from the subsystem level testing to assess TIRS-2 imaging performance including focus, spatial performance, and stray light rejection. It is also used to provide a preliminary assessment of spectral performance. The TIRS-2 subsystem is placed in a thermal vacuum chamber with the calibration ground support equipment, which provides a flexible blackbody illumination source and optics to assess imaging performance. Spectral performance is tested using a spectral response test setup with its own illumination source outside the chamber that propagates through the calibration ground support equipment in an optical configuration designed for this purpose. The results show that TIRS-2 performance is expected to meet all of its performance requirements with few waivers and deviations.

Published
2018

30. Landsat 9 Thermal Infrared Sensor 2 Pre-Launch Characterization: Initial Imaging & Spectral Performance Results

Author

Pearlman, Aaron, McCorkel, Joel, Montanaro, Matthew, Efremova, Boryana, Wenny, Brian, Lunsford, Allen, Simon, Amy, Hair, Jason, and Reuter, Dennis

Subjects
Earth Resources And Remote Sensing
Abstract

The Thermal Infrared Sensor-2 (TIRS-2) scheduled to launch in December 2020 aboard Landsat 9 will continue Landsat's four decade-long legacy of providing moderate resolution thermal imagery from low earth orbit (at 705 km) for environmental applications. Like the Thermal Infrared Sensor aboard Landsat 8, it is a pushbroom sensor with a cross-track field of view of 15 and provides two spectral channels at 10.8 and 12 um. To ensure radiometric, spatial, and spectral performance, a comprehensive pre-launch testing program is being conducted at NASA Goddard Space Flight Center at the component, subsystem, and instrument level. This effort will focus on the results from the subsystem level testing to assess TIRS-2 imaging performance including focus, spatial performance, and stray light rejection. It is also used to provide a preliminary assessment of spectral performance. The TIRS-2 subsystem is placed in a thermal vacuum chamber with the calibration ground support equipment, which provides a flexible blackbody illumination source and optics to assess imaging performance. Spectral performance is tested using a spectral response test setup with its own illumination source outside the chamber that propagates through the calibration ground support equipment in an optical configuration designed for this purpose. The results show that TIRS-2 performance is expected to meet all of its performance requirements with few waivers and deviations.

Published
2018

31. Goddard Laser for Absolute Measurement of Radiance for Instrument Calibration in the Ultraviolet to Short Wave Infrared

Author

McAndrew, Brendan, McCorkel, Joel, Shuman, Timothy, Zukowski, Barbara, Traore, Aboubakar, Rodriguez, Michael, Brown, Steven, and Woodward, John

Subjects
Optics, Lasers And Masers
Abstract

A description of the Goddard Laser for Absolute Calibration of Radiance, a tunable, narrow linewidth spectroradiometric calibration tool, and results from calibration of an earth science satellite instrument from ultraviolet to short wave infrared wavelengths.

Published
2018

33. Overview of the 2015 Algodones Sand Dunes Field Campaign to Support Sensor Intercalibration

Author

McCorkel, Joel, Bachmann, Charles M, Coburn, Craig, Gerace, Aaron, Leigh, Larry, Czapla-Myers, Jeff, Helder, Dennis, and Cook, Bruce

Subjects
Earth Resources And Remote Sensing
Abstract

Several sites from around the world are being used operationally and are suitable for vicarious calibration of space-borne imaging platforms. However, due to the proximity of these sites (e.g., Libya 4), a rigorous characterization of the landscape is not feasible, limiting their utility for sensor intercalibration efforts. Due to its accessibility and similarities to Libya 4, the Algodones Sand Dunes System in California, USA, was identified as a potentially attractive intercalibration site for space-borne, reflective instruments such as Landsat. In March 2015, a 4-day field campaign was conducted to develop an initial characterization of Algodones with a primary goal of assessing its intercalibration potential. Five organizations from the US and Canada collaborated to collect both active and passive airborne image data, spatial and temporal measurements of spectral bidirectional reflectance distribution function, and in-situ sand samples from several locations across the Algodones system. The collection activities conducted to support the campaign goal is summarized, including a summary of all instrumentation used, the data collected, and the experiments performed in an effort to characterize the Algodones site.

Published
2017
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34. Earth-observing Satellite Intercomparison Using the Radiometric Calibration Test Site at Railroad Valley

Author

Czapla-Myers, Jeffrey, McCorkel, Joel, Anderson, Nikolaus, and Biggar, Stuart

Subjects
Earth Resources And Remote Sensing
Abstract

This paper describes the current ground-based calibration results of Landsat 7 Enhanced Thematic Mapper Plus (ETM+), Landsat 8 Operational Land Imager (OLI), Terra and Aqua Moderate Resolution Imaging Spectroradiometer (MODIS), Suomi National Polar orbiting Partnership Visible Infrared Imaging Radiometer Suite (VIIRS), and Sentinel-2A Multispectral Instrument (MSI), using an automated suite of instruments located at Railroad Valley, Nevada, USA. The period of this study is 2012 to 2016 for MODIS, VIIRS, and ETM+, 2013 to 2016 for OLI, and 2015 to 2016 for MSI. The current results show that all sensors agree with the Radiometric Calibration Test Site (RadCaTS) to within +/-5% in the solar-reflective regime, except for one band on VIIRS that is within +/-6%. In the case of ETM+ and OLI, the agreement is within +/-3%, and, in the case of MODIS, the agreement is within +/-3.5%. MSI agrees with RadCaTS to within +/-4.5% in all applicable bands.

Published
2017
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37. Spectral and Radiometric Calibration Using Tunable Lasers

Author

McCorkel, Joel

Subjects
Lasers And Masers
Abstract

A tunable laser system includes a tunable laser, an adjustable laser cavity for producing one or more modes of laser light emitted from the tunable laser, a first optical parametric oscillator positioned in a light path of the adjustable laser cavity, and a controller operable to simultaneously control parameters of at least the tunable laser, the first optical parametric oscillator, and the adjustable laser cavity to produce a range of wavelengths emitted from the tunable laser system. A method of operating a tunable laser system includes using a controller to simultaneously control parameters of a tunable laser, an adjustable laser cavity for producing one or more modes of laser light emitted from the tunable laser, and a first optical parametric oscillator positioned in a light path of the adjustable laser cavity, to produce a range of wavelengths emitted from the tunable laser system.

Published
2017

40. Monitoring Orbital Precession of EO-1 Hyperion With Three Atmospheric Correction Models in the Libya-4 PICS

Author

Neigh, Christopher S. R, McCorkel, Joel, Campbell, Petya K. E, Ong, Lawrence, Ly, Vuong, Landis, David, and Middleton, Elizabeth M

Subjects
Instrumentation And Photography, Earth Resources And Remote Sensing
Abstract

Spaceborne spectrometers require spectral-temporal stability characterization to aid in validation of derived data products. Earth Observation 1 (EO-1) began orbital precession in 2011 after exhausting onboard fuel resources. In the Libya-4 pseudo-invariant calibration site (PICS), this resulted in a progressive shift from a mean local equatorial crossing time of approximately10:00 A.M. in 2011 to approximately 8:30 A.M. in late 2015. Here, we studied precession impacts to Hyperion surface reflectance products using three atmospheric correction approaches from 2004 to 2015. Combined difference estimates of surface reflectance were less than 5 percent in the visible near infrared (VNIR) and less than 10 percent for most of the shortwave infrared (SWIR). Combined coefficient of variation estimates in the VNIR ranged from 0.025 to 0.095, and in the SWIR it ranged from 0.025 to 0.06, excluding bands near atmospheric absorption features. Reflectances produced with different atmospheric models were correlated (R squared) in VNIR from 0.25 to 0.94 and in SWIR from 0.12 to 0.88 (p value (calculated probability) less than 0.01). The uncertainties in all the models increased with a terrain slope up to 15 degrees and selecting dune flats could reduce errors. We conclude that these data remain a valuable resource over this period for sensor intercalibration despite orbital decay.

Published
2016
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41. Results from Source-Based and Detector-Based Calibrations of a CLARREO Calibration Demonstration System

Author

Angal, Amit, Mccorkel, Joel, and Thome, Kurt

Subjects
Earth Resources And Remote Sensing
Abstract

The Climate Absolute Radiance and Refractivity Observatory (CLARREO) mission is formulated to determine long-term climate trends using SI-traceable measurements. The CLARREO mission will include instruments operating in the reflected solar (RS) wavelength region from 320 nm to 2300 nm. The Solar, Lunar for Absolute Reflectance Imaging Spectroradiometer (SOLARIS) is the calibration demonstration system (CDS) for the reflected solar portion of CLARREO and facilitates testing and evaluation of calibration approaches. The basis of CLARREO and SOLARIS calibration is the Goddard Laser for Absolute Measurement of Response (GLAMR) that provides a radiance-based calibration at reflective solar wavelengths using continuously tunable lasers. SI-traceability is achieved via detector-based standards that, in GLAMRs case, are a set of NIST-calibrated transfer radiometers. A portable version of the SOLARIS, Suitcase SOLARIS is used to evaluate GLAMRs calibration accuracies. The calibration of Suitcase SOLARIS using GLAMR agrees with that obtained from source-based results of the Remote Sensing Group (RSG) at the University of Arizona to better than 5 (k2) in the 720-860 nm spectral range. The differences are within the uncertainties of the NIST-calibrated FEL lamp-based approach of RSG and give confidence that GLAMR is operating at 5 (k2) absolute uncertainties. Limitations of the Suitcase SOLARIS instrument also discussed and the next edition of the SOLARIS instrument (Suitcase SOLARIS- 2) is expected to provide an improved mechanism to further assess GLAMR and CLARREO calibration approaches. (2016) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE).

Published
2016
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42. Evaluation of GLAMR-Based Calibration for SI-Traceable Field Reflectance Retrievals

Author

Angal, Amit, McCorkel, Joel, and Thome, Kurtis

Subjects
Earth Resources And Remote Sensing
Abstract

The reflected solar instrument that is part of the Climate Absolute Radiance and Refractivity Observatory (CLARREO) mission is being formulated with a goal of providing SI-traceable measurement of radiance that is an order of magnitude more accurate than the current imaging sensors. The Goddard Laser for Absolute Measurement of Radiance (GLAMR) is a key element to reaching such accuracy along with transferring the laboratory calibration to on-orbit measurements. Results from field reflectance retrievals using three separate instruments all of which have been calibrated using GLAMR are shown. The instruments include a commercial field spectrometer and a portable version of CLARREO's calibration demonstration system. The third instrument is NASA Goddard's Lidar, Hyperspectral and Thermal Imager (G-LiHT) which is an airborne system. All three were operated during a March 2013 measurement campaign at Red Lake Playa, Arizona as part of the on-orbit commissioning phase of Landsat 8. Reflectance is derived from near-coincident measurements by the three sensors for a small area of the playa. The retrieved results are SI-traceable and demonstrate the ability to transfer the GLAMR calibration to the field. Use of the G-LiHT data in the calibration of Landsat-7 and -8 sensors permits them both to be placed on the GLAMR-scale as well.

Published
2016
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43. The Characterization of a DIRSIG Simulation Environment to Support the Inter-Calibration of Spaceborne Sensors

Author

Ambeau, Brittany L, Gerace, Aaron D, Montanaro, Matthew, and McCorkel, Joel

Subjects
Optics
Abstract

Climate change studies require long-term, continuous records that extend beyond the lifetime, and the temporal resolution, of a single remote sensing satellite sensor. The inter-calibration of spaceborne sensors is therefore desired to provide spatially, spectrally, and temporally homogeneous datasets. The Digital Imaging and Remote Sensing Image Generation (DIRSIG) tool is a first principle-based synthetic image generation model that has the potential to characterize the parameters that impact the accuracy of the inter-calibration of spaceborne sensors. To demonstrate the potential utility of the model, we compare the radiance observed in real image data to the radiance observed in simulated image from DIRSIG. In the present work, a synthetic landscape of the Algodones Sand Dunes System is created. The terrain is facetized using a 2-meter digital elevation model generated from NASA Goddard's LiDAR, Hyperspectral, and Thermal (G-LiHT) imager. The material spectra are assigned using hyperspectral measurements of sand collected from the Algodones Sand Dunes System. Lastly, the bidirectional reflectance distribution function (BRDF) properties are assigned to the modeled terrain using the Moderate Resolution Imaging Spectroradiometer (MODIS) BRDF product in conjunction with DIRSIG's Ross-Li capability. The results of this work indicate that DIRSIG is in good agreement with real image data. The potential sources of residual error are identified and the possibilities for future work are discussed..

Published
2016
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44. Interactions Between Temperature and Intercellular CO2 Concentration in Controlling Leaf Isoprene Emission Rates

Author

Monson, Russell K, Neice, Amberly A, Trahan, Nicole A, Shiach, Ian, McCorkel, Joel T, and Moore, David J. P

Subjects
Exobiology, Meteorology And Climatology
Abstract

Plant isoprene emissions have been linked to several reaction pathways involved in atmospheric photochemistry. Evidence exists from a limited set of past observations that isoprene emission rate (I(sub s)) decreases as a function of increasing atmospheric CO2 concentration, and that increased temperature suppresses the CO2 effect. We studied interactions between intercellular CO2 concentration (C(sub I)) and temperature as they affect I(sub s) in field-grown hybrid poplar trees in one of the warmest climates on earth - the Sonoran Desert of the southwestern United States. We observed an unexpected midsummer down regulation of I(sub s) despite the persistence of relatively high temperatures. High temperature suppression of the I(sub s):C(sub I) relation occurred at all times during the growing season, but sensitivity of I(sub s) to increased C(sub I) was greatest during the midsummer period when I(subs) was lowest. We interpret the seasonal down regulation of I(sub s) and increased sensitivity of I(sub s) to C(sub I) as being caused by weather changes associated with the onset of a regional monsoon system. Our observations on the temperature suppression of the I(sub s):C(sub I) relation are best explained by the existence of a small pool of chloroplastic inorganic phosphate, balanced by several large, connected metabolic fluxes, which together, determine the C(sub I) and temperature dependencies of phosphoenolpyruvate import into the chloroplast.

Published
2016
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45. Imager-to-Radiometer In-flight Cross Calibration: RSP Radiometric Comparison with Airborne and Satellite Sensors

Author

McCorkel, Joel, Cairns, Brian, and Wasilewski, Andrzej

Subjects
Earth Resources And Remote Sensing
Abstract

This work develops a method to compare the radiometric calibration between a radiometer and imagers hosted on aircraft and satellites. The radiometer is the airborne Research Scanning Polarimeter (RSP), which takes multi-angle, photo-polarimetric measurements in several spectral channels. The RSP measurements used in this work were coincident with measurements made by the Airborne Visible/Infrared Imaging Spectrometer (AVIRIS), which was on the same aircraft. These airborne measurements were also coincident with an overpass of the Landsat 8 Operational Land Imager (OLI). First we compare the RSP and OLI radiance measurements to AVIRIS since the spectral response of the multispectral instruments can be used to synthesize a spectrally equivalent signal from the imaging spectrometer data. We then explore a method that uses AVIRIS as a transfer between RSP and OLI to show that radiometric traceability of a satellite-based imager can be used to calibrate a radiometer despite differences in spectral channel sensitivities. This calibration transfer shows agreement within the uncertainty of both the various instruments for most spectral channels.

Published
2016
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49. Demonstrating the Error Budget for the Climate Absolute Radiance and Refractivity Observatory Through Solar Irradiance Measurements

Author

Thome, Kurtis, McCorkel, Joel, and McAndrew, Brendan

Subjects
Instrumentation And Photography, Meteorology And Climatology
Abstract

The Climate Absolute Radiance and Refractivity Observatory (CLARREO) mission addresses the need to observe highaccuracy, long-term climate change trends and to use decadal change observations as a method to determine the accuracy of climate change. A CLARREO objective is to improve the accuracy of SI-traceable, absolute calibration at infrared and reflected solar wavelengths to reach on-orbit accuracies required to allow climate change observations to survive data gaps and observe climate change at the limit of natural variability. Such an effort will also demonstrate National Institute of Standards and Technology (NIST) approaches for use in future spaceborne instruments. The current work describes the results of laboratory and field measurements with the Solar, Lunar for Absolute Reflectance Imaging Spectroradiometer (SOLARIS) which is the calibration demonstration system (CDS) for the reflected solar portion of CLARREO. SOLARIS allows testing and evaluation of calibration approaches, alternate design and/or implementation approaches and components for the CLARREO mission. SOLARIS also provides a test-bed for detector technologies, non-linearity determination and uncertainties, and application of future technology developments and suggested spacecraft instrument design modifications. Results of laboratory calibration measurements are provided to demonstrate key assumptions about instrument behavior that are needed to achieve CLARREO's climate measurement requirements. Absolute radiometric response is determined using laser-based calibration sources and applied to direct solar views for comparison with accepted solar irradiance models to demonstrate accuracy values giving confidence in the error budget for the CLARREO reflectance retrieval.

Published
2016
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50. Validation of EO-1 Hyperion and Advanced Land Imager Using the Radiometric Calibration Test Site at Railroad Valley, Nevada

Author

Czapla-Myers, Jeffrey, Ong, Lawrence, Thome, Kurtis, and McCorkel, Joel

Subjects
Earth Resources And Remote Sensing
Abstract

The Earth-Observing One (EO-1) satellite was launched in 2000. Radiometric calibration of Hyperion and the Advanced Land Imager (ALI) has been performed throughout the mission lifetime using various techniques that include ground-based vicarious calibration, pseudo-invariant calibration sites, and also the moon. The EO-1 mission is nearing its useful lifetime, and this work seeks to validate the radiometric calibration of Hyperion and ALI from 2013 until the satellite is decommissioned. Hyperion and ALI have been routinely collecting data at the automated Radiometric Calibration Test Site [RadCaTS/Railroad Valley (RRV)] since launch. In support of this study, the frequency of the acquisitions at RadCaTS has been significantly increased since 2013, which provides an opportunity to analyze the radiometric stability and accuracy during the final stages of the EO-1 mission. The analysis of Hyperion and ALI is performed using a suite of ground instrumentation that measures the atmosphere and surface throughout the day. The final product is an estimate of the top-of-atmosphere (TOA) spectral radiance, which is compared to Hyperion and ALI radiances. The results show that Hyperion agrees with the RadCaTS predictions to within 5% in the visible and near-infrared (VNIR) and to within 10% in the shortwave infrared (SWIR). The 2013-2014 ALI results show agreement to within 6% in the VNIR and 7.5% in the SWIR bands. A cross comparison between ALI and the Operational Land Imager (OLI) using RadCaTS as a transfer source shows agreement of 3%-6% during the period of 2013-2014.

Published
2015
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