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Eintrag Nr. 54838
Utilization of deep learning tools to map and monitor biological soil crusts
Übergeordnete Einträge
ID
TITEL
DATENTYP
AUTOR
JAHR
10627
Dauerbeobachtung Schuttgräben/Abbauflächen
Project
Fachbereich Naturschutz und Naturraum
2012
Weitere Informationen
https://doi.org/10.1016/j.ecoinf.2023.102417
Interne Informationen
-
Externe Informationen
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Datentyp
Publication
Dateiname
-
Pfad
-
Alternativ/Online Name
-
Autor/Ersteller
Herdy, Stefan; Rodríguez-Caballero, Emilio; Pock, Thomas; Weber, Bettina
Medium
File (digital)
Jahr
2024
Monat
0
Aufbewahrungsort
-
Bemerkungen/Beschreibung
Biological soil crusts (biocrusts) form a layer of only one to few centimeters depth on the soil surface and occur mostly in hot and cold deserts. Biocrusts have a major impact on different processes in these ecosystems, like carbon and nitrogen cycling, biodiversity preservation, erosion protection and soil dust emission reduction, but also react highly sensitive upon climate alterations and land use intensification. Therefore, monitoring tools are required to keep track of the changes of these specialized communities in an altering environment. In the current study, we applied a semantic image segmentation approach, using neural networks. One main problem to be solved was, that the training data and target data, on which the model is applied, are often recorded with different camera devices. This leads to different statistical properties of the image data, like different scale, resolution, brightness etc., which could significantly affect the models performance. To solve this problem, we propose a new domain adaption method using a joint energy-based approach. To test a semantic segmentation approach in general, we utilized biocrust imagery taken in Utah (United States of America) and two sub datasets from the National Park Gesause (Austria). Here, we achieved highly reliable results with an overall classification accuracy of 85.9% for the USA data and 88.6% and 91.4%, respectively, for the two sub datasets of the National Park Gesause. To test our joint energy-based domain adaption approach, we used the two sub datasets from the National Park Gesause, which were recorded with different camera devices. With this newly established approach, we improved the accuracy of our segmentation on the unlabeled sub dataset from 70.4% to 75.3%. The results suggest that joint energy-based modelling is a well-suited domain adaption method for semantic segmentation that could be applied to face various deep learning and image-based biomonitoring challenges.
Abgeleitete Einträge
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