Your search keyword '"Teja Kattenborn"' showing total 5 results

1. From spectra to plant functional traits: Transferable multi-trait models from heterogeneous and sparse data

Author

Eya Cherif, Hannes Feilhauer, Katja Berger, Phuong D. Dao, Michael Ewald, Tobias B. Hank, Yuhong He, Kyle R. Kovach, Bing Lu, Philip A. Townsend, and Teja Kattenborn

Subjects

Soil Science, Geology, Computers in Earth Sciences

Published

2023

2. UAV data as alternative to field sampling to map woody invasive species based on combined Sentinel-1 and Sentinel-2 data

Author

Andreas Braun, Fabian Ewald Fassnacht, Teja Kattenborn, Javier Lopatin, and Michael Förster

Subjects

Synthetic aperture radar, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Multispectral image, Reference data (financial markets), Soil Science, Sampling (statistics), Hyperspectral imaging, Geology, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Photogrammetry, Spatial ecology, Environmental science, Computers in Earth Sciences, Scale (map), 0105 earth and related environmental sciences, Remote sensing

Abstract

Invasive plant species can pose major threats to biodiversity, ecosystem functioning and services. Satellite based remote sensing has evolved as an important technology to spatially map the occurrence of invasive species in space and time. With the new era of the Sentinel missions, Synthetic Aperture Radar (SAR) and multispectral data are now freely available and repeatedly acquired on a high spatial and temporal resolution for the entire globe. However, the high potential of such sensors for automatic mapping procedures cannot be fully harnessed without sufficient and appropriate reference data for model calibration. Reference data are commonly acquired in field surveys, which however, are often relatively expensive and affected by sampling and observer bias. Moreover, a direct transferability to the remote sensing perspective and scale is difficult. Accordingly, we firstly assess the potential of Unmanned Aerial Vehicles (UAV) for semi-automatic reference data acquisition on species cover of three woody invasive species Pinus radiata, Ulex europaeus and Acacia dealbata occurring in Chile. Secondly, we test the upscaling of the estimated species cover to the spatial scale of Sentinel-1 and Sentinel-2. The proposed workflow includes the visual sampling of respective canopies in UAV orthomosaics and the subsequent spatial extrapolations using MaxEnt with spectral (RGB, Hyperspectral), textural (2D) and canopy structural (3D) predictors derived from UAV-based photogrammetry. These UAV-based maps are then used to train random forest models with multitemporal Sentinel-1 and Sentinel-2 data to map the invasive species cover on large spatial scales. Our results show that the semi-automatic UAV-based mapping of the three invasive species results in accurate predictions. Depending on the predictor combination, the correlation was 0.70, 0.77 and 0.90 for Pinus radiatia, Ulex europaeus, Acacia dealbata, respectively. Among the three species, we observed clear differences in the model performance between the tested photogrammetric predictors and their combinations (spectral, 2D texture or 3D structure). For scaling up the UAV-based estimates to the satellite-scale, the Sentinel-2 data (multispectral) were more important than Sentinel-1 data (SAR). An independent validation revealed that the R2 of the upscaling accounted for 0.78 or higher for all species and RMSE lower than 12%. Our results hence demonstrate that UAV-based reference data acquisitions are a promising alternative to traditional field surveys if the target species are directly identifiable in the UAV data.

Published

2019

3. Mapping plant species in mixed grassland communities using close range imaging spectroscopy

Author

Javier Lopatin, Teja Kattenborn, Fabian Ewald Fassnacht, and Sebastian Schmidtlein

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pixel, 0211 other engineering and technologies, Imaging spectrometer, Soil Science, Hyperspectral imaging, Geology, 02 engineering and technology, Vegetation, 01 natural sciences, Grassland, Environmental science, Forb, Ecosystem, Computers in Earth Sciences, Image resolution, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing

Abstract

Grasslands are one of the ecosystems that have been strongly affected by anthropogenic impacts. The state-of-the-art in monitoring changes in grassland species composition is to conduct repeated plot-based vegetation surveys that assess the occurrence and cover of plants. These plot-based surveys are typically limited to comparably small areas and the quality of the cover estimates depends strongly on the experience and performance of the surveyors. Here, we investigate the possibility of a semi-automated, image-based method for cover estimates, by analyzing the applicability of very high spatial resolution hyperspectral data to classify grassland species at the level of individuals. This individual-oriented approach is seen as an alternative to community-oriented remote sensing depicting canopy reflectance as the total of mixed species reflectance. An AISA + imaging spectrometer mounted on a scaffold was used to scan 1 m 2 grassland plots and assess the impact of four sources of variation on the predicted species cover: (1) the spatial resolution of the scans, (2) complexity, i.e. species number and structural diversity, (3) the species cover and (4) the share of functional types (graminoids and forbs). Classifications were conducted using a support vector machine classification with a linear kernel, obtaining a median Kappa of ~ 0.8. Species cover estimations reached median r 2 and root mean square errors (RMSE) of ~ 0.6 and ~ 6.2% respectively. We found that the spatial resolution and diversity level (mainly structural diversity) were the most important sources of variation affecting the performance of the proposed approach. A spatial resolution below 1 cm produced relatively good models for estimating species-specific coverages (r 2 = ~ 0.6; RMSE = ~ 7.5%) while predictions using pixel sizes over that threshold failed in this individual-oriented approach (r 2 = ~ 0.17; RMSE = ~ 20.7%). Areas with low inter-species overlap were better suited than areas with frequent inter-species overlap. We conclude that the application of very high resolution hyperspectral remote sensing in environments with low structural heterogeneity is suited for individual-oriented mapping of grassland plant species.

Published

2017

4. Using aboveground vegetation attributes as proxies for mapping peatland belowground carbon stocks

Author

Jorge F. Perez-Quezada, Teja Kattenborn, Javier Lopatin, Mauricio Galleguillos, and Sebastian Schmidtlein

Subjects

Peat, Soil Science, Hyperspectral imaging, Climate change, Geology, Vegetation, Random forest, Vegetation type, Environmental science, Physical geography, Allometry, Species richness, Computers in Earth Sciences, Remote sensing

Abstract

Peatlands are key reservoirs of belowground carbon (C) and their monitoring is important to assess the rapid changes in the C cycle caused by climate change and direct anthropogenic impacts. Frequently, information of peatland area and vegetation type estimated by remote sensing has been used along with soil measurements and allometric functions to estimate belowground C stocks. Despite the accuracy of such approaches, there is still the need to find mappable proxies that enhance predictions with remote sensing data while reducing field and laboratory efforts. Therefore, we assessed the use of aboveground vegetation attributes as proxies to predict peatland belowground C stocks. First, the ecological relations between remotely detectable vegetation attributes (i.e. vegetation height, aboveground biomass, species richness and floristic composition of vascular plants) and belowground C stocks were obtained using structural equation modeling (SEM). SEM was formulated using expert knowledge and trained and validated using in-situ information. Second, the SEM latent vectors were spatially mapped using random forests regressions with UAV-based hyperspectral and structural information. Finally, this enabled us to map belowground C stocks using the SEM functions parameterized with the random forests derived maps. This SEM approach resulted in higher accuracies than a direct application of a purely data-driven random forests approach with UAV data, with improvements of r 2 from 0.39 to 0.54, normalized RMSE from 31.33% to 20.24% and bias from −0.73 to 0.05. Our case study showed that: (1) vegetation height, species richness and aboveground biomass are good proxies to map peatland belowground C stocks, as they can be estimated using remote sensing data and hold strong relationships with the belowground C gradient; and (2) SEM is facilitates to incorporate theoretical knowledge in empirical modeling approaches.

Published

2019

5. Advantages of retrieving pigment content [μg/cm2] versus concentration [%] from canopy reflectance

Author

Pablo J. Zarco-Tejada, Teja Kattenborn, Felix Schiefer, Sebastian Schmidtlein, German Centre for Air and Space Travel, and Federal Ministry of Economics and Technology (Germany)

Subjects

Pigments, Canopy, Plant functioning, Concentration, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Soil Science, Context (language use), 02 engineering and technology, Plant health, Photosynthesis, 01 natural sciences, Anthocyanins, Atmosphere, chemistry.chemical_compound, Pigment, Radiative transfer, Computers in Earth Sciences, Carotenoid, 0105 earth and related environmental sciences, Remote sensing, chemistry.chemical_classification, Geology, Chlorophylls, Carotenoids, 020801 environmental engineering, Content, Horticulture, chemistry, Chlorophyll, visual_art, visual_art.visual_art_medium

Abstract

Photosynthesis is essential for life on earth as it, inter alia, influences the composition of the atmosphere and is the driving mechanism of primary production. Photosynthesis is particularly controlled by leaf pigments such as chlorophyll, carotenoids or anthocyanins. Incoming solar radiation is mainly captured by chlorophyll, whereas plant organs are also protected from excess radiation by carotenoids and anthocyanins. Current and upcoming optical earth observation sensors are sensitive to these radiative processes and thus feature a high potential for mapping the spatial and temporal variation of these photosynthetic pigments. In the context of remote sensing, leaf pigments are either quantified as leaf area-based content [μg/cm2] or as leaf mass-based concentration [g/g or %]. However, these two metrics are fundamentally different, and until now there has been neither an in-depth discussion nor a consensus on which metric to choose. This is notable considering the amount of studies that do not explicitly differentiate between pigment content and concentration. We therefore seek to outline the differences between both metrics and thus show that the remote sensing of leaf pigment concentration [%] is unsubstantial. This is due to the fact that, firstly, pigment concentration is likely to primarily reflect variation in leaf mass per area and not pigments itself. Second, the radiative transfer in plant leaves is especially determined by the absolute content of pigments in a leaf and not its relative concentration to other leaf constituents. And third, as a ratio, pigment concentration is an ambiguous metric, which further complicates the quantification of leaf pigments at the canopy scale. Given these issues related to the use of chlorophyll concentration, we thus conclude that remote sensing of leaf pigments should be primarily performed on an area basis [μg/cm2]., The project was funded by the German Aerospace Center (DLR) on behalf of the Federal Ministry of Economics and Technology (BMWi), FKZ50EE 1347.

Published

2019