Incorporation of Unmanned Aerial Vehicle (UAV) Point Cloud Products into Remote Sensing Evapotranspiration Models

Aboutalebi, Mahyar; Torres‐Rua, Alfonso F.; McKee, Mac; Kustas, W. P.; Nieto, Héctor; Alsina, María Mar; White, William A.; Prueger, John H.; McKee, L.; Alfieri, Joseph G.; Hipps, Lawrence E.; Coopmans, Calvin; Dokoozlian, Nick

doi:10.3390/rs12010050

Cited by 31 publications

(17 citation statements)

References 92 publications

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“…Additionally, to the geometry, each 3D point also stored the colour which was used to discriminate between vegetation and bare soil. Aboutalebi et al [26] used UAV-based 3D information to monitor and assess vineyard plant's condition. Different aspects of 3D point cloud were used to estimate height, volume, surface area, and projected surface area of plant's canopy.…”

Section: Introductionmentioning

confidence: 99%

Automatic Grapevine Trunk Detection on UAV-Based Point Cloud

et al. 2020

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The optimisation of vineyards management requires efficient and automated methods able to identify individual plants. In the last few years, Unmanned Aerial Vehicles (UAVs) have become one of the main sources of remote sensing information for Precision Viticulture (PV) applications. In fact, high resolution UAV-based imagery offers a unique capability for modelling plant’s structure making possible the recognition of significant geometrical features in photogrammetric point clouds. Despite the proliferation of innovative technologies in viticulture, the identification of individual grapevines relies on image-based segmentation techniques. In that way, grapevine and non-grapevine features are separated and individual plants are estimated usually considering a fixed distance between them. In this study, an automatic method for grapevine trunk detection, using 3D point cloud data, is presented. The proposed method focuses on the recognition of key geometrical parameters to ensure the existence of every plant in the 3D model. The method was tested in different commercial vineyards and to push it to its limit a vineyard characterised by several missing plants along the vine rows, irregular distances between plants and occluded trunks by dense vegetation in some areas, was also used. The proposed method represents a disruption in relation to the state of the art, and is able to identify individual trunks, posts and missing plants based on the interpretation and analysis of a 3D point cloud. Moreover, a validation process was carried out allowing concluding that the method has a high performance, especially when it is applied to 3D point clouds generated in phases in which the leaves are not yet very dense (January to May). However, if correct flight parametrizations are set, the method remains effective throughout the entire vegetative cycle.

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Section: Introductionmentioning

confidence: 99%

Automatic Grapevine Trunk Detection on UAV-Based Point Cloud

et al. 2020

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“…UAS have the great potential to complement relatively low-cost ground-based measurements with an airborne in-situ component and contribute to various diverse atmospheric applications, especially over regions where surface measurements are impossible or hard to perform on a regular basis, for example over oceans. Some of them deal with (1) the calibration/validation of lidar and satellite aerosol products, e.g., of the Aerosol, Clouds and Trace Gases Research Infrastructure (ACTRIS, http:/actris.net/, accessed on 5 May 2021), (2) in-situ cloud sensing [12], (3) the representation of groundbased observations (e.g., of new particle formation [13]), ( 4) the mapping of ground-based emissions for Integrated Carbon Observation System (ICOS), and ( 5) the detection and mapping of air pollution episodes. UAS can also be valuable tools for hyperspectral or multispectral monitoring of ecosystems and hence contribute to the understanding of land-atmosphere interactions [14].…”

Section: Locationmentioning

confidence: 99%

“…Although a number of routine balloon-borne measurements (e.g., based on radiosondes and ozonesondes) already take place, most airborne measurements are sporadic and campaign-based, and do not meet the needs of long-term monitoring of the upper levels of the atmosphere. Recent developments, mostly in aerosol technology, allowed for in-situ airborne atmospheric observations conducted with sensors on-board Unmanned Aerial Vehicles (UAVs) [6][7][8][9][10][11][12], as described in Table 1.…”

Section: Introductionmentioning

confidence: 99%

The Unmanned Systems Research Laboratory (USRL): A New Facility for UAV-Based Atmospheric Observations

et al. 2021

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The Unmanned Systems Research Laboratory (USRL) of the Cyprus Institute is a new mobile exploratory platform of the EU Research Infrastructure Aerosol, Clouds and Trace Gases Research InfraStructure (ACTRIS). USRL offers exclusive Unmanned Aerial Vehicle (UAV)-sensor solutions that can be deployed anywhere in Europe and beyond, e.g., during intensive field campaigns through a transnational access scheme in compliance with the drone regulation set by the European Union Aviation Safety Agency (EASA) for the research, innovation, and training. UAV sensor systems play a growing role in the portfolio of Earth observation systems. They can provide cost-effective, spatial in-situ atmospheric observations which are complementary to stationary observation networks. They also have strong potential for calibrating and validating remote-sensing sensors and retrieval algorithms, mapping close-to-the-ground emission point sources and dispersion plumes, and evaluating the performance of atmospheric models. They can provide unique information relevant to the short- and long-range transport of gas and aerosol pollutants, radiative forcing, cloud properties, emission factors and a variety of atmospheric parameters. Since its establishment in 2015, USRL is participating in major international research projects dedicated to (1) the better understanding of aerosol-cloud interactions, (2) the profiling of aerosol optical properties in different atmospheric environments, (3) the vertical distribution of air pollutants in and above the planetary boundary layer, (4) the validation of Aeolus satellite dust products by utilizing novel UAV-balloon-sensor systems, and (5) the chemical characterization of ship and stack emissions. A comprehensive overview of the new UAV-sensor systems developed by USRL and their field deployments is presented here. This paper aims to illustrate the strong scientific potential of UAV-borne measurements in the atmospheric sciences and the need for their integration in Earth observation networks.

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“…A selected list of efforts are mentioned here: a) Landsat-UAV data harmonization (Aboutalebi et al, 2018b) to evaluate potential biases on UAV information and direct comparison to Landsat satellite products; b) Atmospheric impact on UAS thermal information (Torres-Rua, 2017), to address atmospheric conditions with the advent of stronger UAVs (e.g. BVLOS); c) UAV optical and thermal spectral and spatial uncertainty impact (McKee et al, 2018) to evaluate potential issues caused by spectral and location biases towards estimation of evapotranspiration; d) Shadow impact on UAS optical and thermal products (Aboutalebi et al, 2019a), to evaluate shadow effect in orchards and vineyards on vegetation indices, to biomass and surface energy balance; e) Estimation of energy balance fluxes for vineyards crops using UAS (Nieto et al, 2015;Nieto et al, 2019), an adaptation of the TSEB approach to the uniqueness of vine orchards; f) Soil water estimation using UAS (Hassan-Esfahani et al, 2015), application of machine learning approaches for soil water content; g)Yield and biomass estimation using UAS (Aboutalebi et al, 2018a); h) use of point cloud in estimation of evapotranspiration (Aboutalebi et al, 2020); and i) Pixel size impact on the estimation of ET using UAV (Nassar et al, 2020), to assess the changes in ET estimation accuracy for energy balance and ET with fine and coarser pixels. These studies, along with other researchers (Kustas et al, 2018), provide the necessary support for additional UAV development such as use of beyond line of sight UAVs and drone swarm, real-time agricultural applications, and integration of UAV and satellite information for agriculture.…”

Section: Utah Utah State University ─ Aggieair Uav Research Programmentioning

confidence: 99%

A Decade of Unmanned Aerial Systems in Irrigated Agriculture in the Western U.S.

Chávez¹,

Torres‐Rua²,

Woldt³

et al. 2020

Applied Engineering in Agriculture

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Highlights Unmanned aerial systems (UAS) are able to provide data for precision irrigation management. Improvements are needed regarding UAS platforms, sensors, processing software, and regulations. Integration of multi-scale imagery into scientific irrigation scheduling tools are needed for technology adoption. Abstract . Several research institutes, laboratories, academic programs, and service companies around the United States have been developing programs to utilize small unmanned aerial systems (sUAS) as an instrument to improve the efficiency of in-field water and agronomical management. This article describes a decade of efforts on research and development efforts focused on UAS technologies and methodologies developed for irrigation management, including the evolution of aircraft and sensors in contrast to data from satellites. Federal Aviation Administration (FAA) regulations for UAS operation in agriculture have been synthesized along with proposed modifications to enhance UAS contributions to irrigated agriculture. Although it is feasible to use sUAS technology to produce maps of actual crop coefficients, actual crop evapotranspiration, and soil water deficits, for irrigation management, the technology and regulations need to evolve further to facilitate a successful wide adoption and application. Improvements and standards are needed in terms of cameras’ spectral (bands) ranges, radiometric resolutions and associated calibrations, fuel/power technology for longer missions, better imagery processing software, and easier FAA approval of higher altitudes flight missions among other issues. Furthermore, the sUAS technology would play a larger role in irrigated agriculture when integrating multi-scale data (sUAS, ground-based or proximal, satellite) and soil water sensors is addressed, including the need for advances on processing large amounts of data from multiple and different sources, and integration into scientific irrigation scheduling (SIS) systems for convenience of decision making. Desirable technological innovations, and features of the next generation of UAS platforms, sensors, software, and methods for irrigated agriculture, are discussed. Keywords: Agricultural water management, Irrigation prescription mapping, Irrigation scheduling, Precision irrigation, Remote sensing, Sensors, Spatial crop evaOotranspiration, Unmanned aerial systems.

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Incorporation of Unmanned Aerial Vehicle (UAV) Point Cloud Products into Remote Sensing Evapotranspiration Models

Cited by 31 publications

References 92 publications

Automatic Grapevine Trunk Detection on UAV-Based Point Cloud

Automatic Grapevine Trunk Detection on UAV-Based Point Cloud

The Unmanned Systems Research Laboratory (USRL): A New Facility for UAV-Based Atmospheric Observations

A Decade of Unmanned Aerial Systems in Irrigated Agriculture in the Western U.S.

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