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This PDF file contains the front matter associated with SPIE Proceedings Volume 10406 including the Title Page, Copyright information, Table of Contents, Introduction, and Conference Committee listing.
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Enabling Technologies and Techniques for Trace Gases Measurements
An airborne 2-μm triple-pulse integrated path differential absorption (IPDA) lidar is currently under development at NASA Langley Research Center (LaRC). This lidar targets both atmospheric carbon dioxide (CO2) and water vapor (H2O) column measurements, simultaneously. Advancements in the development of this IPDA lidar are presented in this paper. Updates on advanced two-micron triple-pulse high-energy laser transmitter will be given including packaging and lidar integration status. In addition, receiver development updates will also be presented. This includes a state-of-the-art detection system integrated at NASA Goddard Space Flight Center. This detection system is based on a newly developed HgCdTe (MCT) electron-initiated avalanche photodiode (e-APD) array. Future plan for IPDA lidar system for ground integration, testing and flight validation will be discussed.
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In 2013, Harris and Atmospheric and Environmental Research developed the greenhouse gas laser imaging tomography
experiment (GreenLITE™) under a cooperative agreement with the National Energy Technology Laboratory of the
Department of Energy. The system uses a pair of high-precision, intensity-modulated, continuous-wave (IMCW)
transceivers and a series of retroreflectors to generate overlapping atmospheric density measurements from absorption of
a particular greenhouse gas (e.g. CO2 or CH4), to provide an estimate of the two-dimensional spatial distribution of the
gas within the area of interest. The system can take measurements over areas ranging from approximately 0.04 square
kilometers (km2) to 25 km2 (~200 meters (m) × 200 m, up to ~5 km × 5 km). Multiple GreenLITE™ CO2 demonstrations
have been carried out to date, including a full year, November 04, 2015 through November 14, 2016, deployment over a
25 km2 area of downtown Paris, France. In late 2016, the GreenLITE™ system was converted to provide similar
measurements for CH4. Recent experiments showed that GreenLITE™ CH4 concentration readings correlated with an insitu
instrument, calibrated with World Meteorological Organization traceable gas purchased from the NOAA Earth
Systems Research Laboratory, to within approximately 0.5% of CH4 background or ~10-15 parts per billion. Several
experiments are planned in 2017 to further evaluate the accuracy of the CH4 and CO2 retrieved concentration values
compared to the calibrated in situ instrument and to demonstrate the feasibility of GreenLITE™ for environmental and
safety monitoring of CO2 and CH4 in industrial applications.
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Atmospheric methane (CH4) is the second most important anthropogenic greenhouse gas with approximately 25 times the radiative forcing of carbon dioxide (CO2) per molecule. CH4 also contributes to pollution in the lower atmosphere through chemical reactions leading to ozone production. Recent developments of LIDAR measurement technology for CH4 have been previously reported by Goddard Space Flight Center (GSFC). In this paper, we report on a novel, high-performance tunable semiconductor laser technology developed by Freedom Photonics for the 1650nm wavelength range operation, and for LIDAR detection of CH4. Devices described are monolithic, with simple control, and compatible with low-cost fabrication techniques. We present 3 different types of tunable lasers implemented for this application.
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Fibertek has developed and demonstrated an ideal high-power; low-risk; low-size, weight, and power (SWaP) 2051 nm laser design meeting the lidar requirements for satellite-based global measurement of carbon dioxide (CO2). The laser design provides a path to space for either a coherent lidar approach being developed by NASA Jet Propulsion Laboratory (JPL)1,2 or an Integrated Path Differential Lidar (IPDA) approach developed by Harris Corp using radio frequency (RF) modulation and being flown as part of a NASA Earth Venture Suborbital Mission—NASA’s Atmospheric Carbon and Transport – America.3,4 The thulium (Tm) fiber laser amplifies a <500 kHz linewidth distributed feedback (DFB) laser up to 25 W average power in a polarization maintaining (PM) fiber. The design manages and suppresses all deleterious non-linear effects that can cause linewidth broadening or amplified spontaneous emission (ASE) and meets all lidar requirements. We believe the core laser components, architecture, and design margins can support a coherent or IPDA lidar 10-year space mission. With follow-on funding Fibertek can adapt an existing space-based Technology Readiness Level 6 (TRL-6), 20 W erbium fiber laser package for this Tm design and enable a near-term space mission with an electrical-to-optical (e-o) efficiency of <20%.
A cladding-pumped PM Tm fiber-based amplifier optimized for high efficiency and high-power operation at 2051 nm is presented. The two-stage amplifier has been demonstrated to achieve 25 W average power and <16 dB polarization extinction ratio (PER) out of a single-mode PM fiber using a <500 kHz linewidth JPL DFB laser5-7 and 43 dB gain. The power amplifier’s optical conversion efficiency is 53%. An internal efficiency of 58% is calculated after correcting for passive losses. The two-stage amplifier sustains its highly efficient operation for a temperature range of 5-40°C. The absence of stimulated Brillouin scattering (SBS) for the narrow linewidth amplification shows promise for further power scaling.
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Methane emissions from natural gas production, storage, and transportation are potential sources of greenhouse gas emissions. Methane leaks also constitute revenue loss potential from operations. Since 2013, Ball Aerospace has been developing advanced airborne sensors using integrated path differential absorption (IPDA) LIDAR instrumentation to identify methane, propane, and longer-chain alkanes in the lowest region of the atmosphere. Additional funding has come from the U.S. Department of Transportation, Pipeline and Hazardous Materials Administration (PHMSA) to upgrade instrumentation to a broader swath coverage of up to 400 meters while maintaining high spatial sampling resolution and geolocation accuracy. Wide area coverage allows efficient mapping of emissions from gathering and distribution networks, processing facilities, landfills, natural seeps, and other distributed methane sources. This paper summarizes the benefits of advanced instrumentation for aerial methane emission mapping, describes the operating characteristics and design of this upgraded IPDA instrumentation, and reviews technical challenges encountered during development and deployment.
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One of the most important applications of a space-based Doppler Wind Lidar (DWL) would be to improve atmospheric analyses and weather forecasting. Since the mid-1980s, Observing System Simulation Experiments (OSSEs) have been conducted to evaluate the potential impact of space-based DWL data on numerical weather prediction (NWP). All of these OSSEs have shown significant beneficial impact on global analyses and forecasts. In more recent years, a limited number of experiments have been conducted to evaluate the potential impact of DWL data on hurricane forecasting and also to begin to evaluate the impact of real airborne DWL observations. These latest studies suggest that DWL can complement existing hurricane observations effectively and have the potential to contribute to improved hurricane track and intensity forecasting.
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Global wind measurements are critically needed to improve and extend NOAA weather forecasting that impacts U.S.
economic activity such as agriculture crop production, as well as hurricane forecasting, flooding, and FEMA disaster
planning.1 NASA and the 2007 National Research Council (NRC) Earth Science Decadal Study have also identified
global wind measurements as critical for global change research. NASA has conducted aircraft-based wind lidar
measurements using 2 um Ho:YLF lasers, which has shown that robust wind measurements can be made. Fibertek
designed and demonstrated a high-efficiency, 100 W average power continuous wave (CW) 1940 nm thulium (Tm)-
doped fiber laser bread-board system meeting all requirements for a NASA Earth Science spaceflight 2 μm Ho:YLF
pump laser. Our preliminary design shows that it is possible to package the laser for high-reliability spaceflight operation
in an ultra-compact ~ 2″x8″x14″ size and weight <8.5 lbs. A spaceflight 100 W polarization maintaining (PM) Tm laser
provides a path to space for a pulsed, Q-switched 2 μm Ho:YLF laser with ~ 30-80 mJ/pulse range at 100-200 Hz
repletion rates.
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We are developing a family of fast, widely–tunable cw diode-pumped single frequency solid-state lasers, called Swift. The Swift laser architecture is compatible with operation using many different solid-state laser crystals for operation at various emission lines between 1 and 2.1 micron. The initial prototype Swift laser using a Tm,Ho:YLF laser crystal near 2.05 micron wavelength achieved over 100 mW of single frequency cw output power, up to 50 GHz-wide, fast, mode-hop-free piezoelectric tunability, and ~ 100 kHz/ms frequency stability. For the Tm,Ho:YLF laser material, the fast 50 GHz tuning range can be centered at any wavelength from 2047-2059 nm using appropriate intracavity spectral filters. The frequency stability and power are sufficient to serve as the local oscillator (LO) laser in long-range coherent wind-measuring lidar systems, as well as a frequency-agile master oscillator (MO) or injection-seed source for larger pulsed transmitter lasers. The rapid and wide frequency tunablity meets the requirements for integrated-path or range-resolved differential absorption lidar or applications where targets with significantly different line of sight velocities (Doppler shifts) must be tracked. Initial demonstration of an even more compact version of the Swift is also described which requires less prime power and produces less waste heat.
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A new method for calibration of water vapor Raman lidars based on first principles is proposed. The calibration constant
of a Raman lidar is derived from a set of water vapor and nitrogen Raman backscatter signals measured with the lidar
receiver in a cell filled with reference humidity mixture. The reference humidity mixture is prepared gravimetrically. The
water vapor mixing ratio is calculated directly as ratio of the mass of water to the mass of air or nitrogen. Since mass is a
fundamental quantity, this method yields an absolute value of water vapor mixing ratio which translates to the lidar
calibration constant.
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AdvR, through support of the NASA SBIR program, has developed fiber-based components and sub-systems that are routinely used on NASA’s airborne missions, and is now developing an environmentally hardened, diode-based, locked wavelength, seed laser for future space-based high spectral resolution lidar applications. The seed laser source utilizes a fiber-coupled diode laser, a fiber-coupled, calibrated iodine reference module to provide an absolute wavelength reference, and an integrated, dual-element, nonlinear optical waveguide component for second harmonic generation, spectral formatting and wavelength locking. The diode laser operates over a range close to 1064.5 nm, provides for stabilization of the seed to the desired iodine transition and allows for a highly-efficient, fully-integrated seed source that is well-suited for use in airborne and space-based environments. A summary of component level environmental testing and spectral purity measurements with a seeded Nd:YAG laser will be presented. A direct-diode, wavelength-locked seed laser will reduce the overall size weight and power (SWaP) requirements of the laser transmitter, thus directly addressing the need for developing compact, efficient, lidar component technologies for use in airborne and space-based environments.
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The spatial distributions of flying insects are not well understood since most sampling methods - Malaise traps, sticky traps, vacuum traps, light traps - are not suited to documenting movements or changing distributions of various insects on short time scales. These methods also capture and kill the insects. To noninvasively monitor the spatial distributions of flying insects, we developed and implemented a scanning lidar system that measured wing-beat-modulated scattered laser light. The oscillating signal from wing-beat returns allowed for reliable separation of lidar returns for insects and stationary objects. Transmitting and receiving optics were mounted to a telescope that was attached to a scanning mount. As it scanned, the lidar collected and analyzed the light scattered from insect wings of various species. Mount position and pulse time-of-flight determined spatial location and spectral analysis of the backscattered light provided clues to insect identity. During one day of a four-day field campaign at Grand Teton National Park in June of 2016, 76 very likely insects and 662 somewhat likely insects were detected, with a maximum range to the insect of 87.6 m for very likely insects
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A master-oscillator power amplifier (MOPA) based 1550 nm wavelength fiber laser transmitter has been developed for
Space-to-Earth communication application, utilizing Telcordia rated 1550 nm seed laser, pump lasers, and fiber optics.
With adequate pre-screening of electrical components, the fiber laser transmitter has been in operation since its original
launch in April 2014, for 30 months. This presents as a relatively cost-effective route for low-earth-orbit optical
communication as well as LIDAR applications.
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The recent several years we developed the Scheimpflug lidar method. We combined an invention from the 19th century
with modern optoelectronics such as diode lasers and CMOS array from the 21st century. The approach exceeds
expectations of background suppression, sensitivity and resolution beyond known from time-of-flight lidars. We
accomplished multiband elastic atmospheric lidars for resolving single particles and aerosol plumes from 405 nm to 1550
nm. We pursued hyperspectral differential absorption lidar for molecular species. We demonstrated a simple method of
inelastic hyperspectral lidar for profiling aquatic environments and vegetation structure. Not least, we have developed
polarimetric Scheimpflug lidar with multi-kHz sampling rates for remote modulation spectroscopy and classification of
aerofauna. All these advances are thanks to the Scheimpflug principle. Here we give a review of how far we have come
and shed light on the limitations and opportunities for future directions. In particular, we show how the biosphere can be
resolved with unsurpassed resolution in space and time, and share our expectation on how this can revolutionize
ecological analysis and management in relation to agricultural pests, disease vectors and pollinator problematics.
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Recently, developments in airborne sensors and easy to fly, reliable, low-cost commercial Unmanned Aerial Vehicles,
UAVs, have opened a new era for high quality and reliable mapping from UAVs using remote sensing techniques. The
restricted payload capacity of low-cost UAVs imposes constraints on the quality of their navigation systems and the sensors
they can carry. Therefore, LIDAR sensors with limited sample rate are utilized within the UAV system. This article
introduces several applications that utilizes UAV-LIDAR systems, processing of a sample dataset downloaded from the
internet and a new system that is being developed and flown. Our data was collected with DJI S900 Hexacopter and a
VLP-16 LIDAR system from Velodyne. We then process the raw data to generate the 3D point cloud. The test site is a
farming site so we classified the points into ground points and vegetation points. The results are very promising as an early
research investigation. Currently, we are planning for other flights with more rigorous systems and quantitative evaluation.
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A bistatic CCD camera lidar (CLidar) was used at the National Oceanic and Atmospheric Administration’s Mauna Loa
Observatory (MLO) to map aerosol light scattering. Laser light from a 532 nm, Nd:YAG laser was vertically transmitted
into the atmosphere and the scatter off clouds, aerosols and air molecules was detected using a CCD camera with wide
angle optics and a laser line filter. The intensity of each CCD camera pixel imaging the beam was normalized to a
molecular scattering model in an aerosol free region for subtraction of molecular scattering. Aerosol extinction was
derived using a column average aerosol phase function derived from AERONET sun photometer measurements at MLO.
The CLidar design allows measurements of aerosol scattering all the way to the ground without an overlap correction.
MLO, at 3397 m.a.s.l., typically receives free tropospheric air. During spring months, prevailing winds can occasionally
transport dust from Asian sources with high dust activity over MLO. Aerosol scattering measurements were taken by the
CLidar during spring months at MLO and revealed extinction peaks at mid-range altitudes. Back trajectories of air
parcels from MLO at the altitudes of these peaks were conducted using NOAA’s Hybrid Single Particle Lagrangian
Integrated Trajectory (HYSPLIT) model and it was found that they passed over regions of Eastern Asia known as
sources of high dust activity. Relative humidity data from radiosondes and the NOAA stratospheric lidar’s water vapor
channel were examined to differentiate aerosol scattering from tenuous cloud scattering. This paper presents aerosol
extinction data with observations of Asian dust as measured by the CLidar during spring months at MLO.
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In this study, multiple remote sensing and in-situ measurements are combined in order to obtain a comprehensive
understanding of the aerosol distribution in New York City. Measurement of the horizontal distribution of aerosols is
performed using a scanning eye-safe elastic-backscatter micro-pulse lidar. Vertical distribution of aerosols is measured
with a co-located ceilometer. Furthermore, our analysis also includes in-situ measurements of particulate matter and
wind speed and direction. These observations combined show boundary layer dynamics as well as transport and
inhomogeneous spatial distribution of aerosols, which are of importance for air quality monitoring.
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