The Department of Energy's Atmospheric Radiation Measurement (ARM) Unmanned Aerospace Vehicle (UAV) Program

Stephens, Graeme L.; Ellingson, R. G.; Vitko, J.; Bolton, W.; Tooman, T. P.; Valero, Francisco; Minnis, Patrick; Pilewskie, P.; Phipps, G. S.; Sekelsky, S.M.; Carswell, J.; Miller, Steven D.; Benedetti, Angela; McCoy, Renata; Lederbuhr, A.; Bambha, Ray P.

doi:10.1175/1520-0477(2000)081<2915:tdoesa>2.3.co;2

Cited by 36 publications

(22 citation statements)

References 22 publications

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“…In general, the capacity of UAS for aerial surveying or geomatics purposes is determined by factors that are a function of size, including payload capacity, range, propulsion system, and cost (Stephens et al 2000). Size classes, including micro, mini, standard, full size, and High Altitude Long Endurance (HALE), largely define the potential for the UAS to perform desired tasks.…”

Section: Airframesmentioning

confidence: 99%

Unmanned aerial systems for precision forest inventory purposes: A review and case study

Goodbody

CoopsNicholas

MarshallPeter

et al. 2017

The Forestry Chronicle

147

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Unmanned Aerial Systems (UAS) are capable of improving the efficiency of acquisition and providing fine spatial scale data for sustainable resource management. In this paper we begin by describing differences between UAS airframes, their successes and limitations, and list contemporary research applications. UAS compatible sensor technologies are discussed, including passive and active sensors. Finally, we detail a case study where UAS updated an Enhanced Forest Inventory (EFI) for a study area in interior British Columbia. Airborne Laser Scanning (ALS) from 2013 and Digital Aerial Photogrammetric (DAP) point clouds acquired using a UAS from 2015 were used to estimate individual tree height and volume increments. A total of 246 trees were detected using Canopy Height Models (CHMs) with 70% of these trees being matched in the ALS and DAP data sets. Mean tree growth between 2013 and 2015 from the CHM and 95 th percentile of height (P95) was estimated at 0.68 ± 0.05 and 0.50 m ± 0.05 m, respectively. Similarly, mean gross tree volume increments (m 3 ) were computed as 0.05 m 3 ± 0.005 m 3 and 0.03 m 3 ± 0.005 m 3 for the CHM and P95, respectively. The results indicate that information from UAS-DAP point clouds can generate spatially and temporally accurate inventories and have potential to inform a number of sustainable forest management activities.

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Section: Airframesmentioning

confidence: 99%

Unmanned aerial systems for precision forest inventory purposes: A review and case study

Goodbody

CoopsNicholas

MarshallPeter

et al. 2017

The Forestry Chronicle

147

View full text Add to dashboard Cite

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“…Lightweight (<50 kg) unmanned aerial vehicles (UAV) provide researchers with a tool for carrying instrumentation routinely for low cost and at a reduced risk to operators. The specific use of UAVs for climate and atmospheric sciences research have included radiation measurements (Stephens et al, 2000), monitoring sea surface temperature Inoue et al, 2004) and meteorological soundings (Soddell et al, 2004). Autonomous UAV (AUAV), which fly independently of a direct operator by using a computer autopilot with GPS navigation, add additional capability, including the ability to fly coordinated missions using multiple aircraft in formation or close proximity (Ramanathan et al, 2007b).…”

Section: Introductionmentioning

confidence: 99%

Capturing vertical profiles of aerosols and black carbon over the Indian Ocean using autonomous unmanned aerial vehicles

et al. 2008

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Abstract. Measurements of the vertical distribution of aerosol properties provide essential information for generating more accurate model estimates of radiative forcing and atmospheric heating rates compared with employing remotely sensed column averaged properties. A month long campaign over the Indian Ocean during March 2006 investigated the interaction of aerosol, clouds, and radiative effects. Routine vertical profiles of aerosol and water vapor were determined using autonomous unmanned aerial vehicles equipped with miniaturized instruments. Comparisons of these airborne instruments with established ground-based instruments and in aircraft-to-aircraft comparisons demonstrated an agreement within 10%.Aerosol absorption optical depths measured directly using the unmanned aircraft differed from columnar AERONET sun-photometer results by only 20%. Measurements of total particle concentration, particle size distributions, aerosol absorption and black carbon concentrations are presented along with the trade wind thermodynamic structure from the surface to 3000 m above sea level. Early March revealed a wellmixed layer up to the cloud base at 500 m above mean sea level (m a.s.l.), followed by a decrease of aerosol concentrations with altitude. The second half of March saw the arrival of a high altitude plume existing above the mixed layer that originated from a continental source and increased aerosol concentrations by more than tenfold, yet the surface air mass showed little change in aerosol concentrations and was still predominantly influenced by marine sources. Black carbon concentrations at 1500 m above sea level increased from 70 ng/m 3 to more than 800 ng/m 3 with the arrival of this polluted plume. The absorption aerosol optical depth increased from as low as 0.005 to as much as 0.035 over the same period. The spectral dependence of the aerosol abCorrespondence to: C. E. Corrigan (ccorrigan@ucsd.edu) sorption revealed an absorption Angstrom exponent of 1.0, which is typical of an aerosol with most of its absorption attributed to black carbon and generally indicates the absorbing component originated from fossil fuel sources and other high-temperature combustion sources. The results indicate that surface measurements do not represent the aerosol properties within the elevated layers, especially if these layers are influenced by long range transport.

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“…One application for which UAVs are well suited is measurement of the sunlit bidirectional reflectance factor (BRF) [3,4], which describes the directional reflectance characteristics of a target surface. The BRF is determined by measuring the reflected radiance of the target surface from several directions and comparing those measurements to the reflected radiance of an ideal and Lambertian surface under equal illumination conditions.…”

Section: Open Accessmentioning

confidence: 99%

Acquisition of Bidirectional Reflectance Factor Dataset Using a Micro Unmanned Aerial Vehicle and a Consumer Camera

2010

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This paper describes a method for retrieving the bidirectional reflectance factor (BRF) of land-surface areas, using a small consumer camera on board an unmanned aerial vehicle (UAV) and introducing an advanced calibration routine. Images with varying view directions were taken of snow cover using the UAV. The vignetting effect was corrected from the images, and reflectance factor images were calculated using a calibrated white target as a reference. After spatial registration of the images using a corresponding point method, the target surface was divided into a grid, and a BRF was generated for each grid element. Lastly a model was fitted to the BRF dataset for data interpretation. The retrieved BRF were compared to parallel ground measurements. Comparison showed similar BRF and reflectance factor characteristics, which suggests that accurate measurements can be taken with cheap consumer cameras, if enough attention is paid to calibration of the images.

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The Department of Energy's Atmospheric Radiation Measurement (ARM) Unmanned Aerospace Vehicle (UAV) Program

Cited by 36 publications

References 22 publications

Unmanned aerial systems for precision forest inventory purposes: A review and case study

Unmanned aerial systems for precision forest inventory purposes: A review and case study

Capturing vertical profiles of aerosols and black carbon over the Indian Ocean using autonomous unmanned aerial vehicles

Acquisition of Bidirectional Reflectance Factor Dataset Using a Micro Unmanned Aerial Vehicle and a Consumer Camera

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