Early Diagnosis of Vegetation Health From High-Resolution Hyperspectral and Thermal Imagery: Lessons Learned From Empirical Relationships and Radiative Transfer Modelling

Hernández-Clemente, Rocío; Hornero, Alberto; Mõttus, Matti; Peñuelas, Josep; González-Dugo, Victoria; Jiménez, Juan Carlos; Suárez, Lola; Alonso, Luis; Zarco‐Tejada, Pablo J.

doi:10.1007/s40725-019-00096-1

Cited by 73 publications

(56 citation statements)

References 123 publications

(148 reference statements)

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“…Moreover, because of the extremely high spectral resolution and sensitivity, as well as the persistent nature of the UO's observational strategy, new metrics on vegetative health can be developed, low signal-to-noise effects such as solarinduced fluorescence [164] can be measured, and short timescale response to local air quality (e.g., particular matter or ozone [165][166][167]) can be determined to high precision by fusing (see Section 2.5) data from in situ air quality sensors with UO imagery. This has the potential to not only inform urban science studies of the impact of human use of built structures on the natural environment (see Section 4 below), but can provide operational capacity by generating advanced warning indicators of low-level plant stress [165,168].…”

Section: Urban Vegetative Healthmentioning

confidence: 99%

The Urban Observatory: A Multi-Modal Imaging Platform for the Study of Dynamics in Complex Urban Systems

et al. 2021

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We describe an “Urban Observatory” facility designed for the study of complex urban systems via persistent, synoptic, and granular imaging of dynamical processes in cities. An initial deployment of the facility has been demonstrated in New York City and consists of a suite of imaging systems—both broadband and hyperspectral—sensitive to wavelengths from the visible (∼400 nm) to the infrared (∼13 micron) operating at cadences of ∼0.01–30 Hz (characteristically ∼0.1 Hz). Much like an astronomical survey, the facility generates a large imaging catalog from which we have extracted observables (e.g., time-dependent brightnesses, spectra, temperatures, chemical species, etc.), collecting them in a parallel source catalog. We have demonstrated that, in addition to the urban science of cities as systems, these data are applicable to a myriad of domain-specific scientific inquiries related to urban functioning including energy consumption and end use, environmental impacts of cities, and patterns of life and public health. We show that an Urban Observatory facility of this type has the potential to improve both a city’s operations and the quality of life of its inhabitants.

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Section: Urban Vegetative Healthmentioning

confidence: 99%

The Urban Observatory: A Multi-Modal Imaging Platform for the Study of Dynamics in Complex Urban Systems

et al. 2021

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“…These have been restricted to the 3D modeling of trees using handheld cameras and point cloud analysis [ 28 ] and the analysis of trees’ thermal characteristics [ 29 ]. Other applications using different technologies, such as hyperspectral cameras [ 30 ] and low-cost electronic noses (e-noses) [ 31 ], using the methodology proposed can be implemented to obtain more information from trees and their environment, such as diagnosis of vegetation health.…”

Section: Introductionmentioning

confidence: 99%

Urban Green Infrastructure Monitoring Using Remote Sensing from Integrated Visible and Thermal Infrared Cameras Mounted on a Moving Vehicle

Fuentes

Tongson

Viejo

2021

Sensors

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Climate change forecasts higher temperatures in urban environments worsening the urban heat island effect (UHI). Green infrastructure (GI) in cities could reduce the UHI by regulating and reducing ambient temperatures. Forest cities (i.e., Melbourne, Australia) aimed for large-scale planting of trees to adapt to climate change in the next decade. Therefore, monitoring cities’ green infrastructure requires close assessment of growth and water status at the tree-by-tree resolution for its proper maintenance and needs to be automated and efficient. This project proposed a novel monitoring system using an integrated visible and infrared thermal camera mounted on top of moving vehicles. Automated computer vision algorithms were used to analyze data gathered at an Elm trees avenue in the city of Melbourne, Australia (n = 172 trees) to obtain tree growth in the form of effective leaf area index (LAIe) and tree water stress index (TWSI), among other parameters. Results showed the tree-by-tree variation of trees monitored (5.04 km) between 2016–2017. The growth and water stress parameters obtained were mapped using customized codes and corresponded with weather trends and urban management. The proposed urban tree monitoring system could be a useful tool for city planning and GI monitoring, which can graphically show the diurnal, spatial, and temporal patterns of change of LAIe and TWSI to monitor the effects of climate change on the GI of cities.

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“…Images acquired during an airborne campaign by AVIRIS instrument over the 020, 20, x FOR PEER REVIEW 2 of 13 yperspectral images allow to distinguish different materials on the Earth's surface, recognizing ctral signatures; thus, they are a powerful geology tool, allowing to detect several minerals ignificant implications for mining activities [9] and volcanic mapping [10]. Hyperspectral s typically collect 200 or more contiguous bands [11], enabling the reconstruction of vegetation res [12]. Agriculture studies can benefit significantly from hyperspectral imaging analysis for ring crop health status [13].…”

Section: Introductionmentioning

confidence: 99%

Comparison of PRISMA Data with Model Simulations, Hyperion Reflectance and Field Spectrometer Measurements on ‘Piano delle Concazze’ (Mt. Etna, Italy)

Romaniello

Silvestri

Buongiorno

et al. 2020

Sensors

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In this work, we compare first acquisitions from the ASI-PRISMA (Agenzia Spaziale Italiana-PRecursore IperSpettrale della Missione Applicativa) space mission with model simulations, past data acquired by the Hyperion sensor and field spectrometer measurements. The test site is ‘Piano delle Concazze’ (Mt. Etna, Italy), suitable for calibration purposes due to its homogeneity characteristics. The area measures at about 0.2 km2 and is composed of very homogeneous trachybasalt rich in plagioclase and olivine. Three PRISMA acquisitions, achieved on 31 July and 8 and 17 August 2019, are analyzed. Firstly, spectral profiles of PRISMA top of atmosphere (TOA) radiance are compared with MODerate resolution atmospheric TRANsmission (MODTRAN) simulations. The Pearson correlation coefficient is equal to 0.998 and 0.994 for VNIR (Visible and Near InfraRed) and SWIR (Short-Wave InfraRed) spectral ranges, respectively. PRISMA radiance overestimates values simulated by MODTRAN for all considered days, showing a mean bias of +5.22 and of +0.91 Wm−2sr−1µm−1 for VNIR and SWIR, respectively. The relative mean difference between reflectance values estimated by PRISMA and Hyperion, on the test area, is around +19%, despite the great difference in time acquisition (up to 19 years); PRISMA slightly overestimates Hyperion reflectance with an absolute mean difference of about +0.0083, within the variability of Hyperion acquisitions of ±0.0250 (corresponding to ±2 standard deviation). Finally, FieldSpec measurements also confirm the great quality of PRISMA reflectance estimations. The absolute mean difference results are around +0.0089 (corresponding to a relative error of about +21%). In the study, we investigate only the lower values of reflectance characterizing the test site. A more complete evaluation of PRISMA performances needs to consider other test sites with different optical characteristics.

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Early Diagnosis of Vegetation Health From High-Resolution Hyperspectral and Thermal Imagery: Lessons Learned From Empirical Relationships and Radiative Transfer Modelling

Cited by 73 publications

References 123 publications

The Urban Observatory: A Multi-Modal Imaging Platform for the Study of Dynamics in Complex Urban Systems

The Urban Observatory: A Multi-Modal Imaging Platform for the Study of Dynamics in Complex Urban Systems

Urban Green Infrastructure Monitoring Using Remote Sensing from Integrated Visible and Thermal Infrared Cameras Mounted on a Moving Vehicle

Comparison of PRISMA Data with Model Simulations, Hyperion Reflectance and Field Spectrometer Measurements on ‘Piano delle Concazze’ (Mt. Etna, Italy)

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