Your search keyword '"Optics"' showing total 4,764 results

1. Spacecraft Lighting Systems Perspectives for Lunar Missions

Author

Toni A Clark

Subjects

Optics, Spacecraft Design, Testing and Performance

Published

2024

2. Lensless Imaging For Particle-Image Velocity Measurements (PIV)

Author

Jenna Eppink and Chung-Sheng Yao

Subjects

Instrumentation and Photography, Optics, Aerodynamics

Published

2024

3. SCIFLI HORIS Windowpane Optical Analysis

Author

Hyun Jung Kim, William Humphreys, Arianna Haven, Carey Scott, Ian Rook, Thomas Gutierrez, Alexandra Philip, and Tait Pottebaum

Subjects

Optics

Abstract

This NASA Technical Memorandum summarizes windowpane optical analyses for the OSIRIS-REx (Origins, Spectral Interpretation, Resource Identification and Security Regolith Explorer) mission [1] supported by the SCIFLI (Scientifically Calibrated In-Flight Imagery) team [2] at NASA Langley Research Center (NASA LaRC). The SCIFLI team led a NASA multi-center team in characterization of fused silica (FS) and anti-reflective coated (AR-coated) sapphire materials for use as aircraft windowpanes. These materials were needed for the Hypervelocity OSIRIS-REx Reentry Imaging & Spectroscopy (HORIS) mission and were tested to generate performance parameters relevant to the flight environment. Some of the assessed parameters included optical quality, transmittance, reflectance, color balance, birefringence, transmitted wavefront error, wedge, and haziness of the windows. In order to evaluate the material characteristics in a uniform manner, several criteria were held constant. For example, the physical dimensions of the test articles were held constant (i.e., 17-inch diameter aircraft windowpane and 2-inch diameter witness samples). In this way, the comparison of test results from one material specimen to another was invariant with regard to the manner in which the tests were conducted. This also reduced the variability in how the data were reported. As a result, the results shown in this report, including test data generated by NASA can be used for windowpane material evaluation and future material design trades. Window designers can use the data and the testing method along with the testing matrices to efficiently match material performance to their design and mission objectives and requirements. Standardized testing methodologies and data reduction procedures are described in this report. Unless otherwise noted in the data itself, all the windowpane materials were tested in order to characterize their performance for the HORIS mission. One appendix has been included in this report. These include detailed wavefront interferograms of transmitted wavefront error and optical wedge used in the generation of aggregated material performance.

Published

2024

4. Clock Synchronization Characterization of the Washington DC Metropolitan Area Quantum Network (DC-QNet)

Author

Wayne McKenzie, Anne Marie Richards, Shirali Patel, Thomas Gerrits, T. G. Akin, Steven Peil, Adam Black, David Tulchinsky, Ya-Shian Li-Baboud, Anouar Rahmouni, Yicheng Shi, Ivan A. Burenkov, Alan Mink, Nijil Lal, Paulina Kuo, Pranish Shrestha, Mheni Merzouki, Alejandro Rodriguez Perez, Eleanya Onuma, Richard Slonaker, Daniel E. Jones, Atiyya A. Davis, Thomas A. Searles, J. D. Whalen, Matthew Diaz, Kate Collins, Qudsia Quraishi, Bruce Crabill, Oliver Slattery, and Abdella Battou

Subjects

Optics

Abstract

Distributed protocols relying on quantum interference, event synchronization, network telemetry, timestamping, and precise time-of-flight measurements require high-precision clock and time synchronization. This study describes the design, development, and characterization of two optical time transfer methods between a network of reference clocks at each laboratory node in the Washington Metropolitan Quantum Network Research Consortium (DC-QNet). With optical time transfer using active electronic stabilization, sub-picosecond time deviation (TDEV) was achieved at integration times between 1 s and 105 s over 35 km of deployed fiber. Using the White Rabbit-Precision Time Protocol (WR-PTP), we achieved sub-10 picosecond TDEV at integration times ranging from sub-second to over one day. There is potential to improve WR-PTP time transfer using in-situ compensation methods. Measurement methods were developed to understand the impact of environmental and time-of-flight fluctuations on clock synchronization. Path delay gradients, chromatic dispersion, polarization drift, and optical power variations all contributed to clock synchronization instabilities. For protocols requiring the coexistence of quantum and classical communications, we deployed WR-PTP in a bi-directional configuration using 1270 nm and 1290 nm wavelengths over 64 km. The results from this study will inform future advancements in the development of metropolitan-scale, telecommunications-compatible clock synchronization networks for enabling near-term experimental research in quantum networking protocols.

Published

2024

5. Uncertainty Budget for Detector-Based Absolute Radiometric Calibration With GLAMR

Author

Zhipeng Wang, Julia Barsi, Kurtis Thome, Brian N. Wenny, Brendan McAndrew, Boryana Efremova, and Joel McCorkel

Subjects

Earth Resources and Remote Sensing, Optics

Abstract

The accuracy of the absolute radiometric calibration (RadCal) for remote sensing instruments is essential to their wide range of applications. The uncertainty associated to the traditional source-based RadCal method is assessed at a 2% (k=1) or higher level for radiance measurement. To further improve the accuracy to meet the demands of climate studies, a detector-based approach using tunable lasers as a light source has been devised. The Goddard Laser for Absolute Measurement of Radiance, known as the GLAMR system, is a notable example of the incorporation of such technology. Using transfer radiometers calibrated at NIST as calibration standards, the absolute spectral response (ASR) function of a remote sensing instrument is measured with its uncertainty traceable to the International System of Units. This paper presents a comprehensive uncertainty analysis of the detector-based absolute RadCal using the GLAMR system. It identifies and examines uncertainty sources during the GLAMR RadCal test, including those from the GLAMR system, the testing configuration, and data processing methodologies. Analysis is carried out to quantify the contribution of each source and emphasize the most influential factors. It is shown that the calibration uncertainty of GLAMR RadCal can be better than 0.3% (k=1) in the wavelength range of 350-950 nm and 0.6% (k=1) between 950-2300 nm, with the exception of regions with strong water absorption. In addition, recommendations are made to refine the calibration process to further reduce the uncertainty.

Published

2024

6. Spectral Correlation in MODIS Water-Leaving Reflectance Retrieval Uncertainty

Author

Minwei Zhang, Amir Ibrahim, Bryan A. Franz, Andrew M. Sayer, P. Jeremy Werdell, and Lachlan I. McKinna

Subjects

Optics, Earth Resources And Remote Sensing

Abstract

Spectral remote sensing reflectance, Rrs(λ) (sr−1), is the fundamental quantity used to derive a host of bio-optical and biogeochemical properties of the water column from satellite ocean color measurements. Estimation of uncertainty in those derived geophysical products is therefore dependent on knowledge of the uncertainty in satellite-retrieved Rrs. Furthermore, since the associated algorithms require Rrs at multiple spectral bands, the spectral (i.e., band-to-band)error covariance in Rrs is needed to accurately estimate the uncertainty in those derived properties. This study establishes a derivative-based approach for propagating instrument random noise, instrument systematic uncertainty, and forward model uncertainty into R rs as retrieved using NASA’s multiple-scattering epsilon (MSEPS) atmospheric correction algorithm, to generate pixel-level error covariance in R rs. The approach is applied to measurements from Moderate Resolution Imaging Spectroradiometer (MODIS) on the Aqua satellite and verified using Monte Carlo (MC) analysis. We also make use of this full spectral error covariance in R rs to calculate uncertainty in phytoplankton pigment chlorophyll-a concentration (chla, mg/m3) and diffuse attenuation coefficient of downwelling irradiance at 490 nm (K d(490), m-1). Accounting for the error covariance in Rrs generally reduces the estimated relative uncertainty in chla by ∼1-2% (absolute value) in waters with chla< 0.25 mg/m3 where the color index (CI) algorithm is used. The reduction is ∼5-10% in waters with chla> 0.35 mg/m3 where the blue-green ratio (OCX) algorithm is used. Such reduction can be higher than 30% in some regions. For K d(490), the reduction by error covariance is generally ∼2%, but can be higher than 20% in some regions. The error covariance in R rs is further verified through forward-calculating chla from MODIS-retrieved and in situ R rs and comparing estimated uncertainty with observed differences. An 8-day global composite of propagated uncertainty shows that the goal of 35% uncertainty in chla can be achieved over deep ocean waters (chla ≤ 0.1 mg/m3). While the derivative-based approach generates reasonable error covariance in R rs some assumptions should be updated as our knowledge improves. These include the inter-band error correlation in top-of-atmosphere reflectance, and uncertainties in the calibration of MODIS 869 nm band, in ancillary data, and in the in situ data used for system vicarious calibration.

Published

2024

7. The Atacama Cosmology Telescope: Galactic Dust Structure and the Cosmic PAH Background in Cross-correlation with WISE

Author

Rodrigo Córdova Rosado, Brandon S. Hensley, Susan E. Clark, Adriann J. Duivenvoorden, Zachary Atkins, Elia Stefano Battistelli, Steve K. Choi, Jo Dunkley, Carlos Hervías-Caimapo, Zack Li, Thibaut Louis, Sigurd Naess, Lyman A. Page, Bruce Partridge, Cristóbal Sifón, Suzanne T. Staggs, Cristian Vargas, and Edward J. Wollack

Subjects

Optics, Astronomy

Abstract

We present a cross-correlation analysis between 1ʹ resolution total intensity and polarization observations from the Atacama Cosmology Telescope (ACT) at 150 and 220 GHz and 15ʺ mid-infrared photometry from the Wide-field Infrared Survey Explorer (WISE) over 107 12°.5 × 12°.5 patches of sky. We detect a spatially isotropic signal in the WISE×ACT TT cross-power spectrum at 30σ significance that we interpret as the correlation between the cosmic infrared background at ACT frequencies and polycyclic aromatic hydrocarbon (PAH) emission from galaxies in WISE, i.e., the cosmic PAH background. Within the Milky Way, the Galactic dust TT spectra are generally well described by power laws in ℓ over the range 103 < ℓ < 104, but there is evidence both for variability in the power-law index and for non-power-law behavior in some regions. We measure a positive correlation between WISE total intensity and ACT E-mode polarization at 1000 < ℓ ≲ 6000 at >3σ in each of 35 distinct ∼100 deg2 regions of the sky, suggesting that alignment between Galactic density structures and the local magnetic field persists to subparsec physical scales in these regions. The distribution of TE amplitudes in this ℓ range across all 107 regions is biased to positive values, while there is no evidence for such a bias in the TB spectra. This work constitutes the highest-ℓ measurements of the Galactic dust TE spectrum to date and indicates that cross-correlation with high-resolution mid-infrared measurements of dust emission is a promising tool for constraining the spatial statistics of dust emission at millimeter wavelengths.

Published

2024

8. High-Order Coronagraphic Wavefront Control With Algorithmic Differentiation: First Experimental Demonstration

Author

Scott D. Will, Marshall D. Perrin, Emiel H. Por, James Noss, Ananya Sahoo, Peter Petrone, Iva Laginja, Raphael Pourcelot, Susan F. Redmond, Laurent Pueyo, Tyler D. Groff, James R. Fienup, and Remi Soummer

Subjects

Optics

Abstract

Future space-based coronagraphs will rely critically on focal-plane wavefront sensing and control with deformable mirrors to reach deep contrast by mitigating optical aberrations in the primary beam path. Until now, most focal-plane wavefront control algorithms have been formulated in terms of Jacobian matrices, which encode the predicted effect of each deformable mirror actuator on the focal-plane electric field. A disadvantage of these methods is that Jacobian matrices can be cumbersome to compute and manipulate, particularly when the number of deformable mirror actuators is large. Recently, we proposed a new class of focal-plane wavefront control algorithms that utilize gradient-based optimization with algorithmic differentiation to compute wavefront control solutions while avoiding the explicit computation and manipulation of Jacobian matrices entirely. In simulations using a coronagraph design for the proposed Large UV/Optical/Infrared Surveyor (LUVOIR), we showed that our approach reduces overall CPU time and memory consumption compared to a Jacobian-based algorithm. Here, we expand on these results by implementing the proposed algorithm on the High Contrast Imager for Complex Aperture Telescopes (HiCAT) testbed at the Space Telescope Science Institute (STScI) and present initial experimental results, demonstrating contrast suppression capabilities equivalent to Jacobian-based methods.

Published

2023

9. Extending Aquatic Spectral Information with the First Radiometric IR-B Field Observations

Author

Henry F Houskeeper and Stanford B Hooker

Subjects

Earth Resources and Remote Sensing, Optics

Abstract

Planetary radiometric observations enable remote sensing of biogeochemical parameters to describe spatiotemporal variability in aquatic ecosystems. For approximately the last half century, the science of aquatic radiometry has established a knowledge base using primarily, but not exclusively, visible wavelengths. Scientific subdisciplines supporting aquatic radiometry have evolved hardware, software, and procedures to maximize competency for exploiting visible wavelength information. This perspective culminates with the science requirement that visible spectral resolution must be continually increased to extract more information. Other sources of information, meanwhile, remain underexploited, particularly information from nonvisible wavelengths. Herein, absolute radiometry is used to evaluate spectral limits for deriving and exploiting aquatic data products, specifically the normalized water-leaving radiance, Γ(λ)⁠, and its derivative products. Radiometric observations presented herein are quality assured for individual wavebands, and spectral verification is conducted by analyzing celestial radiometric results, comparing agreement of above- and in-water observations at applicable wavelengths, and evaluating consistency with bio-optical models and optical theory. The results presented include the first absolute radiometric field observations of Γ(λ) within the IR-B spectral domain (i.e. spanning 1400–3000 nm), which indicate that IR-B signals confer greater and more variable flux than formerly ascribed. Black-pixel processing, a routine correction in satellite and in situ aquatic radiometry wherein a spectrum is offset corrected relative to a nonvisible waveband (often IR-B or a shorter legacy waveband) set to a null value, is shown to degrade aquatic spectra and derived biogeochemical parameters.

Published

2023

10. Cryolite Overcoated Aluminum Reflectors for Far-Ultraviolet Spectroscopy

Author

Javier Del Hoyo, Luis Rodriguez De Marcos, J Hennessy, M Batkis, C Bos, and Manuel Quijada

Subjects

Optics

Abstract

Aluminum (Al) mirrors are conventionally protected with metal-fluoride coatings (e.g., MgF2, LiF, or AlF3) immediately after deposition to prevent oxidation and preserve its far-ultraviolet (FUV) spectral efficiency. However, the resulting FUV reflectance of the aluminum reflector is limited by the metal-fluoride overcoat film index of refraction, morphology, stoichiometry, and its absorption cut-off in the lower end of the FUV spectra. Cryolite (sodium hexafluoroaluminate, Na3AlF6) emerges as a potential candidate to preserve the aluminum FUV reflectance due to its relatively lower index of refraction in the visible to ultraviolet; therefore, allowing for the thin-film design of highly spectral efficient reflectors over a wide spectral range. We investigate the use of cryolite in aluminum reflector FUV coating design. The deposited aluminum reflector overcoated with cryolite will be examined in terms of spectral efficiency and environmental durability. The deposited cryolite overcoat will be evaluated in terms of optical constants and structural properties. Preliminary results have shown that the use of cryolite as an overcoat to protect aluminum would yield unprecedented results as an optimal Hydrogen Lyman-alpha (HLyα) spectral line reflector, with experimental reflectance values >96%.

Published

2023

11. Optical Concentration Sensor for Liquid Solution

Author

Jeffrey A Kohler

Subjects

Optics, Electronics and Electrical Engineering

Published

2023

12. Assembly of the FOXSI-4 Mirror Modules

Author

Stephen D. Bongiorno, Wayne H. Baumgartner, Jeffery Kolodziejczak, Charles G. Davis, Jagan Ranganathan, Nicholas Thomas, Jeff E Mccracken, and Danielle Gurgew

Subjects

Optics

Abstract

The Focusing Optics X-ray Solar Imager 4 (FOXSI 4) is a heliophysics sounding rocket experiment that is currently in its fourth launch campaign. The payload is comprised of seven 2 m focal length X-ray telescopes, which each consist of a grazing incidence mirror module that focuses x-rays onto an imaging detector. For this fourth flight, Marshall Space Flight Center (MSFC) designed, built, and tested three new high-angular-resolution optics. This paper describes the design and assembly of the FOXSI 4 mirror modules.

Published

2023

13. Optimizing the Electroforming Process to Enhance the Thickness Uniformity of Full Shell X-Ray Optics

Author

Panini Singam, Chet Speegle, Amy Meekham, Jeffery Kolodziejczak, Wayne Baumgartner, Grant Davis, David Banks, Jessica Gaskin, Stephen Bongiorno, and Brian Ramsey

Subjects

Optics

Published

2023

14. Using Dome Concordia to Characterize the Long-Term Stability of VIIRS Thermal Emissive Bands

Author

Amit Angal, Xiaoxiong Xiong, Ashish Shrestha, and Aisheng Wu

Subjects

Earth Resources and Remote Sensing, Space Sciences (General), Optics

Abstract

The Visible Infrared Imaging Radiometer Suite (VIIRS) instruments aboard the Suomi NPP and NOAA-20 spacecraft have successfully provided Earth image products since 2011 and 2017, respectively. Maintaining accurate radiometric calibration and calibration consistency between the two sensors is a necessity for the continued quality of long-term data records. In this work, the use of frequent VIIRS measurements of brightness temperature over the area surrounding Dome Concordia (Dome C), Antarctica (75.1 °S, 123.4°E) to track the long-term stability of its thermal emissive bands (TEB) is presented. The extremely dry, cold, and rarefied atmosphere of the site makes it ideal to track and detect long-term changes in the TEB responses via analysis of near-nadir and off-nadir VIIRS overpasses in reference to the surface temperature measurements provided by an automated weather station (AWS). Multi-year Dome C measurements have been used to assess the stability of the VIIRS response-versus-scan-angle (RVS) of the half-angle-mirror (HAM), derived from prelaunch characterization, and detector differences at multiple scan angles. Also, included in this work is the RVS stability assessments using the Dome C overpasses. The methodology developed via this work will also be applied to the recently launched VIIRS instrument onboard the NOAA-21 satellite (previously JPSS-2) in the future.

Published

2023

15. Users' Guide to Vinci: Personal Computer Software for Planning Image-based Measurements in Wind Tunnels

Author

Edward T Schairer

Subjects

Optics, Research and Support Facilities (Air)

Abstract

Vinci is software that can be used to plan image-based measurements in wind tunnels. It allows the user to plan the placement of cameras and the choice of lenses well in advance of a test, thereby reducing the set-up time and cost when tunnel occupancy begins. It can also be used post-test to display data (pressure-sensitive paint, particle image velocimetry, model deformation) in context with the test article. Vinci is self-contained and runs on personal computers under Windows operating systems. No other software is required. Test articles are represented by CFD-like surface grids that may be read from an external file or created within the program as a combination of simple geometric shapes. The user controls the position and orientation of the test article through a Graphical User Interface (GUI) and may add many additional objects, including tunnel walls and windows, a wide variety of simple geometric shapes, mirrors, lamps, and laser sheets. The application computes simulated images from up to 40 cameras. Images are based on pinhole projection. Each camera is defined by the sensor size and the focal length of the lens. All camera parameters, including position and point angles, are controlled through the GUI. Simulated images are displayed in a window of the GUI and may be saved as bitmaps.

Published

2023

16. Broadband and Wide Angle Nonreciprocal Thermal Emission from Weyl Semimetal Structures

Author

Andrew Butler and Christos Argyropoulos

Subjects

Optics

Abstract

Nonreciprocal thermal emission is a cutting-edge technology that enables fundamental control over thermal radiation and has exciting applications in thermal energy harvesting. However, so far one of the foremost challenges is making nonreciprocal emission to operate over a broad wavelength range and for multiple angles. In this work, we solve this outstanding problem by proposing three different types of structures always utilizing only one Weyl semimetal (WSM) thin film combined with one or two additional dielectric or metallic layers and terminated by a metallic substrate. First a tradeoff relationship between the magnitude and bandwidth of the thermal nonreciprocity contrast is established based on the thickness of the WSM film. Then, the bandwidth broadening effect is demonstrated via the insertion of a dielectric spacer layer that can also be fine-tuned by varying its thickness. Finally, further control on the resulting strong nonreciprocal thermal radiation is demonstrated by the addition of a thin metallic layer in the proposed few layer designs. The presented composite structures work for a broad frequency range and multiple emission angles, consisting highly advantageous properties to various nonreciprocal thermal radiation applications. Moreover, the proposed designs do not require any patterning and can be experimentally realized by simple deposition fabrication methods. They are expected to aid in the creation of broadband nonreciprocal thermal emitters that can find applications in new energy harvesting devices.

Published

2023

17. Silicon Photonic Transceiver for Spacecraft Navigational Lidar

Author

Nathan Dostart, Aram Gragossian, Farzin Amzajerdian, Christin E Lundgren, F Guy Wilson, Glenn D Hines, and Bruce W Barnes

Subjects

Optics

Abstract

We describe development of a silicon photonic optical transceiver for integration into NASA's Navigation Doppler Lidar. We demonstrate lidar operation using the on-chip optical balanced receiver.

Published

2023

18. Guidelines for Schlieren Systems at Langley Research Center

Author

E Conrad Compton and Robert C Spencer

Subjects

Optics

Abstract

The original Langley Working Paper (LWP 448) published on July 27th, 1967, provided guidance to NASA Langley Research Center personnel on how to set up conventional path-integrated schlieren flow visualization systems and what pitfalls could be expected with such setups. The guidance and information contained in the document continues to be used for schlieren setups at NASA Langley Research Center to this day.

Published

2023

19. Spectral Characterization of the RST Grism and Prism Spectrometers

Author

Evan Bray and Qian Gong

Subjects

Optics

Published

2023

20. Spectroscopy of Nancy Grace Roman Space Telescope (RST): Grism and Prism Assemblies

Author

Qian Gong, Evan Bray, Victor J Chambers, Bente Eegholm, Margaret Dominguez, Guangjun Gao, John Lehan, Catherine Marx, Joshua Schlieder, and Laurie Seide

Subjects

Optics, Astronomy

Published

2023

21. Optical Design of the Survey and Time-domain Astrophysical Research eXplorer’s X-Ray Telescope

Author

James A Corsetti, Scott O Rohrbach, Timo T Saha, and William W Zhang

Subjects

Optics

Abstract

The proposed Survey and Time-domain Astrophysical Research eXplorer mission contains multiple subassemblies including the X-Ray Telescope. This paper discusses the optical design of that telescope, detailing the requirements, telescope architecture and performance analysis.

Published

2023

22. Basic Theory and Operating Principles of Optical Frequency Domain Reflectometry Measurement Systems as Applied to Fiber Bragg Grating Sensors

Author

Jason P Moore

Subjects

Optics, Instrumentation and Photography

Abstract

Optical frequency domain reflectometer (OFDR) systems provide for the interrogation of hundreds of fiber Bragg gratings (FBGs) within a single optical fiber. The coupling of FBG sensors to an OFDR interrogator results in a highly distributed measurement system utilizing sensors that are lightweight, immune to electromagnetic interference, and low-profile. This paper presents and explores a basic derivation of OFDR-FBG signals, the processing of those signals, the assembly of a basic OFDR system, an example measurement scenario, and the effects of specific component and configuration changes on interrogator speed, resolution, and accuracy.

Published

2023

23. Optimizing Retrieval Spaces of Bio-Optical Models for Remote Sensing of Ocean Color

Author

Neranga K. Hannadige, Peng-Wang Zhai, P. Jeremy Werdell, Meng Gao, Bryan A. Franz, Kirk Knobelspiesse, and Amir Ibrahim

Subjects

Optics, Earth Resources and Remote Sensing

Abstract

We investigated the optimal number of independent parameters required to accurately represent spectral remote sensing reflectances (𝑅rs) by performing principal component analysis on quality controlled in situ and synthetic 𝑅rs data. We found that retrieval algorithms should be able to retrieve no more than four free parameters from 𝑅rs spectra for most ocean waters. In addition, we evaluated the performance of five different bio-optical models with different numbers of free parameters for the direct inversion of in-water inherent optical properties (IOPs) from in situ and synthetic 𝑅rs data. The multi-parameter models showed similar performances regardless of the number of parameters. Considering the computational cost associated with larger parameter spaces, we recommend bio-optical models with three free parameters for the use of IOP or joint retrieval algorithms.

Published

2023

24. Optical Characteristics of Radiated Multifunctional Optical Materials

Author

Narasimha Prasad, Eric Bowman, Meghan Brandt, Amalthea Trobare, Ching-hua Su, Bradley Arnold, Fow-Sen Choa, and N B Singh

Subjects

Optics

Abstract

The performance of optical and electronic materials, and devices are affected significantly in space due to exposure from high energy radiations. We have been investigating the effect of -ray radiations on multifunctional binary and ternary selenide and halide crystals. These materials have shown excellent performance for the wavelength conversion in MWIR and LWIR regions, acousto-optics, and great potential for radiation detection. Crystals with high Z materials such as thallium, mercury and lead based compounds have great potential for the development of a variety of devices and components suitable for space applications. We will report on the characteristics of several halides including mercurous halides (Hg2X2, X= Cl, Br, I), Thallium mercury iodide (Tl4HgI4) and thallium arsenic selenide and thallium gallium selenide, and ternary selenides. These crystals, synthesized with high purity source materials, will be evaluated by studying optical characteristics and measuring resistivity after exposure to a 137Cs -ray source.

Published

2023

25. JWST From Below: An Overview of the Construction of the James Webb Space Telescope (JWST) and Discussion of Current Status

Author

Raymond Ohl

Subjects

Optics

Published

2023

26. Backup Optical Navigation Attitude for Artemis-1 Backup Attitude Ground Tool

Author

Malak Samaan, Lylia Benhacine, Sean Downs, Michael Buttacoli, and Greg Holt

Subjects

Optics, Space Communications, Spacecraft Communications, Command and Tracking, Spacecraft Instrumentation and Astrionics

Abstract

The Backup Optical Navigation Attitude (BONA) software was developed as a response to the Artemis1 Power Distribution Unit (PDU) hardware problems found early in 2021. The hardware problem, a capacitor installed incorrectly, removes the intended redundant path for which the PDU can relay its power and data to attached devices. Specific to the BONA context, the concern is that a failure of the single remaining path in this PDU would lead to an inability to communicate with one of the two-star trackers (STs) on Orion. By flight rule, being reduced to a single star tracker means an immediate turn around end-of-mission. The BONA software is not intended to extend the mission, but instead act as a single star tracker attitude confirmation tool. Insurance, if you will, for the Orion project that a ground tool is available to compare the single remaining ST results with optical navigation images retrieved during the mission. Engineers operating BONA in the Mission Control Center (MCC) Mission Evaluation Room (MER) will analyze the downlinked star field images and based on the stars identified and known time of image, derive vehicle attitude estimates, which can be compared with the ST results. Potentially, in extreme situations, and with expert recommendation, the derivations could lead to navigation state updates being commanded to Orion.

Published

2023

27. P-ACTIVE Project Report

Author

Hyun Jung Kim, Stephen Borg, Scott Bartram, Kiumars Aryana, William Humphreys, Juejun Hu, Tian Gu, Sensong An, Yifei Zhang, Cosmin-Constantin Popescu, Calum Williams, Matthew Julian, and David Bombara

Subjects

Optics

Abstract

The Phase change material-based actively-tunable filter (P-ACTIVE, Dr. Hyun Jung Kim, the Principal Investigator / PI) project is a NASA Langley Research Center (LaRC)-led research endeavor that began as a NASA CIF (Center Innovation Fund) project in 2019. The goal of P-ACTIVE is to develop all-solid-state tunable optical filters that can serve as low-Size, Weight, and Power (SWaP) replacements to the ubiquitous filter wheel technology current in use, and serve as a starting point for completely new optical component technologies. By using materials commonly used in electronic memory devices, namely chalcogenide phase-change materials (PCMs), in conjunction with nanostructured surfaces with exotic, tailored optical responses (“metasurfaces”), the P-ACTIVE filters are able to tune their optical transmission/reflection behavior in real-time. Because of this new functionality, P-ACTIVE filters are highlighted for NASA science and space programs such as next generation Lidar, landing system (SLS) thermal monitoring, thermal imaging, imaging spectroscopy, and disaster monitoring (e.g., volcanic eruption observations from SmallSats). This document intends to serve as a compendium of the P-ACTIVE project. We begin by describing the project from background science and assume no prior knowledge of the subject. We then address experimental and theoretical results of P-ACTIVE device performance, as well as recent results obtained from the MISSE-14 mission related to space qualification of P-ACTIVE devices and constituent materials. We conclude with a prospective view of the P-ACTIVE technology, and discuss the potential for these filters and other similar metasurface devices to serve NASA’s mission.

Published

2023

28. Vibration-Induced Linewidth Broadening in Long Range FMCW Lidar

Author

Nathan Dostart, Aram Gragossian, Farzin Amzajerdian, Glenn D Hines, Lance Lowell Proctor, Bruce W Barnes, Randa Hatem Elhertani, and Diego F Pierrottet

Subjects

Optics

Abstract

We analyze performance changes on a NASA-developed lidar system resulting from vibration loads expected during spacecraft landing. Vibration-induced laser linewidth broadening and reduced measurement precision are demonstrated and related to vibration level and target range.

Published

2022

29. Evaluation of Optical Distortion Measurement Techniques for Curved Optical Surfaces

Author

Mark Nurge, Robert Youngquist, and Annelisa Esparza

Subjects

Optics

Published

2022

30. Silicon Photonic Transceiver for Spacecraft Navigational Lidar

Author

Nathan Dostart, Aram Gragossian, Farzin Amzajerdian, Guy Wilson, Glenn D Hines, and Bruce W Barnes

Subjects

Optics

Abstract

NASA is developing an entry, descent, and landing (EDL) lidar system, the Navigation Doppler Lidar (NDL), for high-precision landing on the Moon, Mars, and beyond. The current flight NDL systems use 1550 nm fiber-optic components for frequency-modulated continuous wave (FMCW) ranging beyond 5 km, but have reduced performance under vibrational and thermal stresses during EDL. Here we describe recent efforts to develop a breadboard silicon photonic optical transceiver for integration into NDL to reduce instrument size and improve robustness to environment and demonstrate the optical balanced receiver performance during testing with the breadboard NDL unit. Initial testing shows improved suppression of common mode noise by 25 dB over the current receiver, but a 10 dB reduction in signal to noise ratio (SNR) resulting from coupling losses from fiber to the on-chip waveguides. Future work will target reduced coupling loss, hermetic packaging, and co-integration of a single sideband suppressed carrier modulator into the same chip.

Published

2022

31. Simons Observatory: Characterizing the Large Aperture Telescope Receiver with Radio Holography

Author

Grace. E. Chesmore, Kathleen Harrington, Carlos E. Sierra, Patricio A. Gallardo, Shreya Sutariya, Tommy Alford, Alexandre E. Adler, Tanay Bhandarkar, Gabriele Coppi, Nadia Dachlythra, Joseph Golec, Jon Gudmundsson, Saianeesh K. Haridas, Bradley R. Johnson, Anna M. Kofman, Jeffrey Iuliano, Jeff McMahon, Michael D. Niemack, John Orlowski-Scherer, Karen Perez Sarmiento, Roberto Puddu, Max Silva-Feaver, Sara M. Simon, Julia Robe, Edward J. Wollack, and Zhilei Xu

Subjects

Optics, Instrumentation and Photography

Abstract

We present near-field radio holography measurements of the Simons Observatory Large Aperture Telescope Receiver optics. These measurements demonstrate that radio holography of complex millimeter-wave optical systems comprising cryogenic lenses, filters, and feed horns can provide detailed characterization of wave propagation before deployment. We used the measured amplitude and phase, at 4 K, of the receiver near-field beam pattern to predict two key performance parameters: 1) the amount of scattered light that will spill past the telescope to 300 K and 2) the beam pattern expected from the receiver when fielded on the telescope. These cryogenic measurements informed the removal of a filter, which led to improved optical efficiency and reduced sidelobes at the exit of the receiver. Holography measurements of this system suggest that the spilled power past the telescope mirrors will be less than 1%, and the main beam with its near sidelobes are consistent with the nominal telescope design. This is the first time such parameters have been confirmed in the lab prior to deployment of a new receiver. This approach is broadly applicable to millimeter and submillimeter instruments.

Published

2022

32. Defining Pupil Knowledge Requirements for Roman Space Telescope Integrated Payload Assembly Testing

Author

Kaitlyn Chandler Summey

Subjects

Optics, Aerodynamics, Numerical Analysis

Abstract

This thesis examines the use of phase retrieval to characterize an optical system under testing conditions with pupil knowledge error. The purpose of this research is to define pupil knowledge requirements for the integrated payload testing of the Roman Space Telescope (RST). I have conducted a Monte Carlo study to determine how uncertainty in the location of the ground support equipment relative to the payload will affect the ability to use image-based wavefront sensing during the test to characterize system alignment. This test will be conducted in the Space Environment Simulator (SES) with the presence of Wavefront Error (WFE) due to gravity sag on the primary mirror. In this study, I incrementally decentered a piece of ground support equipment, the SubAperture Metrology System (SAMS), and evaluated how the phase retrieval algorithm attempted to fit the wavefront with the pupil mismatch. The results of this study are a factor in the overall Integrated Payload Assembly (IPA) testing WFE budget.

Published

2022

33. LISA EDUT Program Status

Author

Sean Brenan, Sam Bonelli, Andrew Sacco, and Brian Vanrensselaer

Subjects

Instrumentation and Photography, Optics

Abstract

The status of the Engineering Development Unit (EDU) Telescope Project for the LISA Mission is presented

Published

2022

34. An Overview of Contamination Control for the James Webb Space Telescope Launch Campaign

Author

Alan Chichester Abeel, Eve M Wooldridge, Joseph O Ward, Marco Calabrini, and Olivier Schmeitsky

Subjects

Optics, Astronomy

Abstract

The James Webb Space Telescope (JWST) is a large, infrared space telescope operating at Lagrange point 2. JWST is a joint effort between NASA, ESA, and CSA and was launched from the Centre Spatial Guyanais (CSG) on an Ariane 5 rocket in December 2021. The three-month launch campaign utilized enhanced contamination controls to meet JWST’s strict cleanliness requirements. Prior to launch, JWST was permitted to only be exposed to ISO Class 7 cleanrooms, whereas the processing facilities at CSG are ISO Class 8. NASA, ESA, Arianespace, and CNES implemented temporary upgrades to the nominal contamination control operations for the launch campaign unique to JWST, including the use of vetted, portable High Efficiency Particulate Air (HEPA) filter walls, pre-entrance cleanliness acceptance surveys of each facility and the intra-plant transporter, tightened cleanroom protocols, upgraded garmenting and laundering techniques, cleaning of Self-Contained Atmospheric Protection Ensemble (SCAPE) suits, increased maintenance, staffed pre-cleaning stations, adaptation of the house purge network, and a contamination control enclosure atop the Ariane 5 launcher prior to fairing encapsulation. The Ariane 5 fairing interior and Vehicle Equipment Bay membrane also received multiple cleanings, detailed inspections, and verification sampling to achieve necessary cleanliness levels. The fairing itself was specially sealed to protect the inner environment with just a small, door porthole accessible via diving board for final closeout of the purge interface. All of these enhancements together allowed JWST to meet its contamination requirements for launch, ensuring successful post-separation deployments and mission science.

Published

2022

35. Phasing the Webb Telescope

Author

D. Scott Acton, Scott Knight, Maria Carrasquilla, Nick Weiser, Michaela Masciarelli, Sarah Jurczyk, Greg Rapp, Julio Mueckay, Erin Wolf, Jess Murphy, Larkin Carey, Eric Coppock, Chanda Walker, Joel Runnels, Garrett West, Greg Wirth, Brian Hicks, Katie Melbourne, Michael Gordon, Bob Brown, Stefano Grimaldi, Derek Sabatke, Ray Wright, Laura Coyle, Taylor Chonis, Kevin Whiteaker, Marshall Perrin, Tom Comeau, Charles-Philippe Lajoie, George Hartig, Tracy Beck, Matt Lallo, Mike Regan, Randal Telfer, Marcio Meléndez, Greg Brady, Laurent Pueyo, Nicolas Flagey, Bernard Kulp, Ed Nelan, Tom Zielinski, Alden Jurling, Matt Bergkoetter, Chuck Bowers, Bruce Dean, Lee Feinberg, Ritva Keski-Kuha, Jeff Kirk, Michael W. McElwain, and Joe Howard

Subjects

Spacecraft Instrumentation and Astrionics, Optics

Abstract

The James Webb Space Telescope (JWST) is a segmented deployable telescope, currently operating at L2. The telescope utilizes 6 degrees of freedom for adjustment of the Secondary Mirror (SM) and 7 degrees of freedom for adjustment of each of its 18 segments in the Primary Mirror (PM). After deployment, the PM segments and the SM arrived in their correct optical positions to within a ~1 mm, with accordingly large wavefront errors. A Wavefront Sensing and Controls (WFSC) process was executed to adjust each of these optical elements in order to correct the deployment errors and produce diffraction-limited images across the entire science field. This paper summarizes the application of the WFSC process.

Published

2022

36. Estimating pixel-level uncertainty in ocean color retrievals from MODIS

Author

Minwei Zhang, Amir Ibrahim, Bryan A. Franz, Ziauddin Ahmad, and Andrew M. Sayer

Subjects

Optics, Earth Resources And Remote Sensing

Abstract

The spectral distribution of marine remote sensing reflectance, R(rs), is the fundamental measurement of ocean color science, from which a host of bio-optical and biogeochemical properties of the water column can be derived. Estimation of uncertainty in these derived properties is thus dependent on knowledge of the uncertainty in satellite-retrieved R(rs) (u(c)(R(rs))) at each pixel. Uncertainty in R(rs), in turn, is dependent on the propagation of various uncertainty sources through the R(rs) retrieval process, namely the atmospheric correction (AC). A derivative-based method for uncertainty propagation is established here to calculate the pixel-level uncertainty in R(rs), as retrieved using NASA’s multiple-scattering epsilon (MSEPS) AC algorithm and verified using Monte Carlo (MC) analysis. The approach is then applied to measurements from the Moderate Resolution Imaging Spectroradiometer (MODIS) on the Aqua satellite, with uncertainty sources including instrument random noise, instrument systematic uncertainty, and forward model uncertainty. The uc(Rrs) is verified by comparison with statistical analysis of coincident retrievals from MODIS and in situ Rrs measurements, and our approach performs well in most cases. Based on analysis of an example 8-day global products, we also show that relative uncertainty in R(rs) at blue bands has a similar spatial pattern to the derived concentration of the phytoplankton pigment chlorophyll-a (chl-a), and around 7.3%, 17.0%, and 35.2% of all clear water pixels (chl-a ≤ 0.1 mg/cu.m) with valid u(c)(R(rs)) have a relative uncertainty ≤ 5% at bands 412 nm, 443 nm, and 488 nm respectively, which is a common goal of ocean color retrievals for clear waters. While the analysis shows that u(c)(R(rs)) calculated from our derivative-based method is reasonable, some issues need further investigation, including improved knowledge of forward model uncertainty and systematic uncertainty in instrument calibration.

Published

2022

37. Characterization of Aerogel Scattering Filters for Astronomical Telescopes

Author

Alyssa Barlis, Stefan Arseneau, Charles L Bennett, Thomas Essinger-Hileman, Haiquan Guo, Kyle R Helson, Tobias Marriage, Manuel A Quijada, Ariel E Tokarz, Stephanie L Vivod, and Edward J Wollack

Subjects

Astrophysics, Optics

Abstract

We have developed a suite of novel infrared-blocking filters made by embedding scattering particles in a polymer aerogel substrate. Our developments allow us to tune the spectral performance of the filters based on both the composition of the base aerogel material and the properties of the scattering particles. Our filters are targeted for use in a variety of applications, from ground-based CMB experiments to planetary science probes. We summarize the formulations we have fabricated and tested to date, including several polyimide base aerogel formulations incorporating a range of size distributions of diamond scattering particles. We also describe the spectral characterization techniques used to measure the filters’ optical properties, including the development o fa mm-wave Fourier transform spectrometer testbed.

Published

2022

38. A Method for Measuring Optical Distortion in Curved Optical Surfaces using Moiré Interferometry

Author

Mark A. Nurge, Robert C. Youngquist, and Annelisa B. Esparza

Subjects

Optics

Abstract

In FY2020, KSC’s Applied Physics Lab created a computer based image processing system to allow inspection of the new visors being developed for the Artemis Program. This system was based on an ASTM standard where the distortion of an image is used to determine the optical aberrations in a visor, but this approach is restricted to small fields-of-view (small areas of the visor) and is limited in its ability to reliably detect and measure distortion. From our experience with flat surface inspection, we know that other optical techniques can offer higher sensitivity and accuracy. [1] This memorandum describes a method to model and measure the distortion in curved optical surfaces using moir´e interferometry. We were able to apply this process to examine samples of the xEMU Artemis astronaut helmets. Design details are provided along with examples to illustrate performance.

Published

2022

39. Numerical phase space optics methods and applications to the analysis of fiber coupling efficiency in atmospheric turbulence

Author

Yousef K. Chahine, Ferrill Rushton, Brian E. Vyhnalek, and Sarah A. Tedder

Subjects

Optics, Space Communications, Spacecraft Communications, Command And Tracking

Abstract

A fundamental requirement of free-space optical communication is the ability to efficiently couple atmospherically distorted light from a telescope to a detector. A numerical method is presented for modeling fiber-based receiver performance in atmospheric conditions based on phase space optics which does not rely on Monte Carlo methods. This method is employed to analyze the waveguide insertion loss and optimal coupling geometry in atmospheric conditions for step-index fibers, graded-index fibers, and photonic lanterns with and without tilt compensation and central obscurations in the telescope.

Published

2022

40. Characterization of Rochon Prisms for Bi-Directional Imaging Applications

Author

Joshua M Weisberger and Brett F Bathel

Subjects

Instrumentation And Photography, Optics

Abstract

Polarizing prisms are often used in applications where light is split into two separate beams of orthogonal polarization, or to isolate a beam with a preferred polarization state. These prisms are typically used with lasers, but there are applications of their use with imaging systems. One such example is that of a recently developed focusing schlieren system, where light must be transmitted through a Rochon prism in both the forward and backward directions. Three Rochon prisms were characterized in this study in terms of their transmitted intensity and polarization state: a quartz/quartz prism, a glass/quartz prism, and a MgF2/MgF2 prism. Laser testing at four wavelengths was performed, along with full clear aperture collimated LED light testing at a single wavelength. The glass/quartz and MgF2/MgF2 prisms operated in the same manner when light was transmitted in either the forward or backward direction. The quartz/quartz prism, however, exhibited differences between operation in the forward and backward direction. In the forward orientation for input plane polarized light, the transmitted intensity varied sinusoidally as a function of height of incidence through the prism, while the polarization of the unrefracted and refracted beams were uniform and orthogonally polarized. In the backward orientation, the intensity for both unrefracted and refracted beams was uniform, but the azimuthal orientation of the output plane polarized light varied sinusoidally as a function of height of incidence through the prism, while remaining orthogonally polarized between the two beams at each position.

Published

2022

41. Characterization of Bidirectional Transmissive and Reflective Properties of Black Silicon

Author

Georgi T Georgiev, James J Butler, Ron Shiri, and Christine A Jhabvala

Subjects

Optics

Abstract

This paper describes the initial work of characterizing the transmissive and reflective properties of black silicon diffusers. The diffusers were fabricated from a 100 mm diameter black silicon sample at NASA’s Goddard Space Flight Center (GSFC). The directional hemispherical reflectance from 250 nm to 2500 nm and BRDF/BTDF measurements at 632.8 nm, 1064 nm, and 1550 nm were measured using the GSFC Diffuser Calibration Laboratory’s (DCL) spectrophotometer and optical scatterometer. The diffusers exhibit a low level of specular reflection up to ~1100 nm with no evidence of retroscatter. The measurements are traceable to those made at the National Institute of Standards and Technology (NIST).

Published

2021

42. Joint Augmented Reality Visual Informatics System Project: HID Prototype System Goals for FY22

Author

Briana L Krygier

Subjects

Optics

Published

2021

43. ORCAS – Orbiting Configurable Artificial Star Mission Architecture

Author

Eliad Peretz, Christine Hamilton, John C Mather, Lucas Pabarcius, Kevin Hall, Adam Michaels, Robert Pritchett, Wayne Yu, Peter Wizinowich, and Eric Golliher

Subjects

Optics

Abstract

In this paper, we establish the mission operation concept for the Orbiting Configurable Artificial Star mission, a hybrid space-ground observatory, which aims to enable ground observations of near-diffraction limited resolution and exquisite sensitivity. We present the mission requirements, introduce a potential orbit solution that can meet them, detail the concrete operational steps to be taken to enable such observations, and develop a mission planning tool which generates a mission schedule that meets all mission requirements and can be altered in real time in the case of disruptions to the mission. Finally, we show the the mission could enable 300 adaptive optics and 1500 flux calibration observations throughout its lifetime.

Published

2021

44. Transmission Telescope Optical Dynamic Alignment

Author

Viviana Vladutescu, Aaron J. Swank, Dzu K. Le, Calvin R. Robinson, and O. Scott Sands

Subjects

Optics, Lasers And Masers

Abstract

The Integrated Radio Optical Communication System (iROC) is designed to transmit data between Mars and Earth by means of radio waves at 32.67 GHz (Ka Band) and laser beam at 1550 nm, both transmitted via a combined teletenna. The iROC terminal will provide ‘beaconless’ operations to allow full function from the outer planets. In order to point without the aid of an uplink beacon, the proof of concept presented here is addressing the need for an accurate determination and control of the relative position of the laser beam with respect to a reference star. The experiment presented simulates a surrogate transmission telescope system in laboratory setting and presents the model used in the correction of the outgoing beam. The results of the model show a nonlinear dependence between the outgoing and the reference beam, indicating the necessity of a minimum of two metrology instruments placed along the optical system for increased pointing precision.

Published

2021

45. Novel Fiber Optic Sensing Arrays with Enhanced Sensitivity in Cryogenic Temperatures

Author

Hon Man Chan

Subjects

Instrumentation And Photography, Optics

Abstract

State-of-the-art instrumentation techniques have provided an opportunity to obtain greater insight into the characteristics of cryogenic liquid storage. Optical fiber sensors that utilize fiber Bragg gratings are a viable option for temperature sensing in volatile liquid such as liquid oxygen because there is no risk of electrical sparking and no electromagnetic interference. The National Aeronautics and Space Administration (NASA) Armstrong Flight Research Center (Edwards, California) has developed a novel, simple-to-fabricate fiber array sensor that has been tested and found to be three times more sensitive than typical fiber sensors under cryogenic condition (traditional fiber sensors can suffer from reduced sensitivity below 100 K). Cryogenic temperature monitoring using the NASA fiber optic sensing system is demonstrated in a simulated cryostatic condition, as well as in an elevated pressure environment under liquid nitrogen. Measurement accuracy is compared with traditional silicon diodes. Instrument installation, sensor characteristics, and experimental results are discussed in detail.

Published

2021

46. Angle Dependence of Focused X-Ray-Induced Single Event Transients in an Epitaxial Silicon Diode

Author

Kaitlyn L Ryder, Landen D Ryder, Andrew L. Sternberg, En Xia Zhang, Stephen D. LaLumondiere, Daniele M. Monahan, Jeremy P. Bonsall, Yuanfu Zhao, Liang Wang, Chuanmin Wang, Robert A. Weller, Ronald D. Schrimpf, and Robert A. Reed

Subjects

Nuclear Physics, Optics

Abstract

Focused X-Ray single event transient (SET) experiments are performed at small angles on an epitaxial silicon diode at two reverse bias conditions. For both biases, the collected charge and peak current results follow the cosine law, while the transient fall time remains independent of incident angle. This demonstrates that only the amount of charge being generated is affected by angle and not the fundamental device response.

Published

2021

47. Near future MeV telescopes can discover asteroid-mass primordial black hole dark matter

Author

Anupam Ray, Ranjan Lah, Julian B. Muño, and Regina Caputo

Subjects

Astronomy, Optics

Abstract

Primordial black holes (PBHs), formed out of large over densities in the early Universe, are a viable dark matter (DM) candidate over a broad range of masses. Ultralight, asteroid-mass PBHs with masses around1017g are particularly interesting as current observations allow them to constitute the entire DM density. PBHs in this mass range emit∼MeV photons via Hawking radiation which can directly be detected by the gamma ray telescopes, such as the upcoming AMEGO. In this work we forecast how well an instrument with the sensitivity of AMEGO will be able to detect, or rule out, PBHs as a DM candidate, by searching for their evaporating signature when marginalizing over the Galactic and extra-Galactic gamma-ray back-grounds. We find that an instrument with the sensitivity of AMEGO could exclude nonrotating PBHs as the only DM component for masses up to7×1017g at 95% confidence level for a monochromatic mass distribution, improving upon current bounds by nearly an order of magnitude. The forecasted constraints are more stringent for PBHs that have rotation, or which follow extended mass distributions

Published

2021

48. Compact, Self-Aligned Focusing Schlieren System

Author

Brett F. Bathel and Joshua M. Weisberger

Subjects

Optics

Abstract

A novel compact, self-aligned focusing Schlieren system is presented that eliminates the need for a separate source grid and cutoff grid. A single grid element serves to both generate a projected source grid onto a retroreflective background, and to act as the cutoff grid for the reflected light. This is made possible by manipulating the polarization of the light through the system. The use of only a single grid element eliminates the need to create a cutoff grid that is perfectly matched and scaled to the source grid, and removes the need to align the source and cutoff grids to each other. The sensitivity to density objects is adjustable with the use of a polarizing prism. Images obtained with this system show similar operation to existing focusing Schlieren systems, but with much reduced complexity and setup time. Images taken with acrylic windows placed nor-mal to the optical axis further demonstrate the system’s utility for wind tunnel measurements.

Published

2021

49. A Three-Step Semi Analytical Algorithm (3SAA) for Estimating Inherent Optical Properties Over Oceanic, Coastal, and Inland Waters From Remote Sensing Reflectance

Author

Daniel S F Jorge, Hubert Loisel, Cedric Jamet, David Dessailly, Julien Demaria, Annick Bricaud, Stephane Maritorena, Xiaodong Zhang, David Antoine, Tiit Kutser, Simon Belanger, Vittorio O Brando, Jeremy Werdell, Ewa Kwiatkowska, Antoine Mangin, and Odile Fanton d'Andon

Subjects

Earth Resources And Remote Sensing, Optics

Abstract

We present a three-step inverse model (3SAA) for estimating the inherent optical properties (IOPs) of surface waters from the remote sensing reflectance spectra, Rrs(). The derived IOPs include the total (a()), phytoplankton (aphy()), and colored detrital matter (acdm()), absorption coefficients, and the total (bb()) and particulate (bbp()) backscattering coefficients. The first step uses an improved neural network approach to estimate the diffuse attenuation coefficient of downwelling irradiance from Rrs. a() and bbp() are then estimated using the LS2 model (Loisel et al., 2018), which does not require spectral assumptions on IOPs and hence can assess a() and bb() at any wavelength at which Rrs() is measured. Then, an inverse optimization algorithm is combined with an optical water class (OWC) approach to assess aphy() and acdm() from anw().The proposed model is evaluated using an in situ dataset collected in open oceanic, coastal, and inland waters. Comparisons with other standard semi-analytical algorithms (QAA and GSM), as well as match-up exercises, have also been performed. The applicability of the algorithm on OLCI observations was assessed through the analysis of global IOPs spatial patterns derived from 3SAA and GSM. The good performance of 3SAA is manifested by median absolute percentage differences (MAPD) of 13%, 23%, 34% and 34% for bbp(443), anw(443), aphy(443) and acdm(443), respectively for oceanic waters. Due to the absence of spectral constraints on IOPs in the inversion of total IOPs, and the adoption of an OWC-based approach, the performance of 3SAA is only slightly degraded in bio-optical complex inland waters.

Published

2021

50. Photonics for Space Flight Instruments

Author

Hali Jakeman-Flores

Subjects

Optics

Abstract

The Photonics group top level processes regarding development and qualification of space flight hardware for optoelectronic components and optical systems along with our contributions and successes with LIDAR systems, space flight reliability heritage, and our testing capabilities are conveyed with this power point presentation.

Published

2021