Tracking 21st century climate dynamics of the Third Pole: An analysis of topo-climate impacts on snow cover in the central Himalaya using Google Earth Engine

La Tierra y su biosfera están cambiando constantemente, por lo tanto, es fundamental detectar los cambios con el fin de entender su impacto en los ecosistemas terrestres. Los esquemas de monitoreo de ecosistemas han evolucionado rápidamente en las ultimas décadas. En el caso del monitoreo forestal, los métodos y herramientas que facilitan la utilización de imágenes satelitales permiten realizar este monitoreo con el cual se puede detectar donde y cuando un bosque es eliminado o afectado debido a un evento de deforestación o bien de fuego, lo anterior casi en tiempo real. Estas nuevas herramientas están disponibles para su implementación, sin embargo, ningún paı́s de la región centroamericana y el Caribe ha implementado un sistema como herramienta de decisión dentro de una estructura de gobierno central o federal debido a la ausencia de programas de transferencia de tecnologı́a o programas de capacitación de talento local. Los sensores remotos proporcionan mediciones consistentes y repetibles que permiten la captura de los efectos de muchos procesos que causan el cambio, incluyendo, por ejemplo, incendios, ataques de insectos, agentes de cambio naturales y antropogénicas como por ejemplo, la deforestación, la urbanización, la agricultura, etc. Las series temporales de imágenes de satélite proporcionan maneras para detectar y vigilar cambios en el tiempo y en el espacio, esto consistentemente durante los últimos 30 años a nivel mundial. Los incendios forestales afectan el proceso de sucesión del bosque, no obstante, es muy limitada la existencia de estudios locales que relacionen el efecto de los incendios forestales con las diferencias en la información espectral a partir de sensoramiento remoto. En el presente estudio se plantea y propone la utilización y aprovechamiento de lo que se ha denominado grandes datos, especialmente con el advenimiento muchas plataformas de sensores remotos como Landsat, MODIS y recientemente Sentinel, para identificar cuál es el efecto de los incendios forestales en la sucesión y sus elementos perturbadores, como por ejemplo, la presencia de lianas. Se procesaron las series temporales se usó la plataforma digital Google Earth Engine, que permitió la selección y reducción de la información espacial de los ı́ndices de vegetación en tendencia, estacionalidad y residuos. Se analizó la respuesta de estos ı́ndices en sitios con diferente afectación por incendios forestales. Con estos índices se pretende desarrollar modelos de clasificación de series espaciales de tiempo de los ı́ndices y poder ası́ comprender los cambios en el tiempo y el espacio de los ecosistemas afectados por incendios forestales. Preliminarmente, se encontró una relación entre la incidencia de los incendios forestales y el fenómeno del Niño-Oscilación del Sur para el índice de vegetación denominado índice de área foliar. Además, la evidencia indica que el índice normalizado de vegetación si presenta diferencias respecto a los sitios que tienen un historial de fuegos diferente. El establecer esta relación implica estudiar también los regı́menes de precipitación y temperatura. El descomponer las series de tiempo facilitó la correlación con otras series de tiempo, permitiendo establecer las bases de un monitoreo y a su vez, relacionar las índices de vegetación y su variación con otros elementos climáticos, como por ejemplo, el efecto ENOS.

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CROP CLASSIFICATION IN KARSHI STEPPE USING REMOTE SENSING INFORMATION AND GOOGLE EARTH ENGINE TOOL

European Science Review ◽

10.29013/esr-18-9.10.1-130-132 ◽

2018 ◽

pp. 130-132

Author(s):

Z. A. Gafurov ◽

S. B. Eltazarov ◽

T. A. Akhmedova

Keyword(s):

Remote Sensing ◽

Google Earth ◽

Google Earth Engine ◽

Crop Classification

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Eva Parra-Membrives/Albrecht Classen (Hrsg. / Eds.): Literatur am Rand: Perspektiven der Trivialliteratur vom Mittelalter bis zum 21. Jahrhundert // Literature on the Margin: Perspectives on Trivial Literature from the Middle Ages to the 21st Century. Tübingen. Narr-Verlag, 2013.

Jahrbuch für Internationale Germanistik ◽

10.3726/ja501_295 ◽

2018 ◽

Vol 50 (1) ◽

pp. 295-296

Author(s):

Peter Pabisch

Keyword(s):

Middle Ages ◽

21St Century ◽

Comparative Studies ◽

The Third ◽

Language Studies ◽

The Middle Ages ◽

Literature And Language

Abstract The three scholarly works of recent years illuminate the versatility of their main editor Albrecht Classen in the interdisciplinary world of comparative studies, in literature and language studies. Together with his colleague Eva Parra-Membrives he offers insights on trivial literature also in view of bestsellers concerning the first two works under discussion here. The third work on multilingualism in the middle ages he edited alone. For all the works he found an impressive number of contributors who fill the chalice of offerings in a most versatile canon of topics.

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Phát triển thuật toán giám sát lũ lụt vùng Đồng bằng sông cửu Long dựa vào nền tảng Google Earth Engine

Can Tho University Journal of Science ◽

10.22144/ctu.jvn.2018.157 ◽

2018 ◽

Vol 54(9) ◽

pp. 29

Author(s):

Võ Quốc Tuấn ◽

Nguyễn Thiên Hoa ◽

Huỳnh Thị Kim Nhân ◽

Đặng Hoàng Khải

Keyword(s):

Google Earth ◽

Google Earth Engine

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Land surface evapotranspiration estimation combining soil texture information and global reanalysis datasets in Google Earth Engine

Remote Sensing Letters ◽

10.1080/2150704x.2019.1633487 ◽

2019 ◽

Vol 10 (10) ◽

pp. 929-938 ◽

Cited By ~ 4

Author(s):

Elisabet Walker ◽

Virginia Venturini

Keyword(s):

Soil Texture ◽

Land Surface ◽

Google Earth ◽

Texture Information ◽

Google Earth Engine ◽

Evapotranspiration Estimation ◽

Global Reanalysis

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Assessing the Effect of Training Sampling Design on the Performance of Machine Learning Classifiers for Land Cover Mapping Using Multi-Temporal Remote Sensing Data and Google Earth Engine

Remote Sensing ◽

10.3390/rs13081433 ◽

2021 ◽

Vol 13 (8) ◽

pp. 1433

Author(s):

Shobitha Shetty ◽

Prasun Kumar Gupta ◽

Mariana Belgiu ◽

S. K. Srivastav

Keyword(s):

Machine Learning ◽

Remote Sensing ◽

Random Sampling ◽

Sampling Design ◽

Remote Sensing Data ◽

Google Earth ◽

Machine Learning Classifiers ◽

Learning Classifiers ◽

Multi Temporal ◽

Google Earth Engine

Machine learning classifiers are being increasingly used nowadays for Land Use and Land Cover (LULC) mapping from remote sensing images. However, arriving at the right choice of classifier requires understanding the main factors influencing their performance. The present study investigated firstly the effect of training sampling design on the classification results obtained by Random Forest (RF) classifier and, secondly, it compared its performance with other machine learning classifiers for LULC mapping using multi-temporal satellite remote sensing data and the Google Earth Engine (GEE) platform. We evaluated the impact of three sampling methods, namely Stratified Equal Random Sampling (SRS(Eq)), Stratified Proportional Random Sampling (SRS(Prop)), and Stratified Systematic Sampling (SSS) upon the classification results obtained by the RF trained LULC model. Our results showed that the SRS(Prop) method favors major classes while achieving good overall accuracy. The SRS(Eq) method provides good class-level accuracies, even for minority classes, whereas the SSS method performs well for areas with large intra-class variability. Toward evaluating the performance of machine learning classifiers, RF outperformed Classification and Regression Trees (CART), Support Vector Machine (SVM), and Relevance Vector Machine (RVM) with a >95% confidence level. The performance of CART and SVM classifiers were found to be similar. RVM achieved good classification results with a limited number of training samples.

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Monitoring Dynamic Changes of Vegetation Cover in the Tarim River Basin Based with Landsat Imagery and Google Earth Engine

IGARSS 2020 - 2020 IEEE International Geoscience and Remote Sensing Symposium ◽

10.1109/igarss39084.2020.9323924 ◽

2020 ◽

Author(s):

Tian Zhao ◽

Yang Yang ◽

Xihan Mu

Keyword(s):

River Basin ◽

Vegetation Cover ◽

Landsat Imagery ◽

Google Earth ◽

Tarim River ◽

Tarim River Basin ◽

Dynamic Changes ◽

The Tarim River ◽

Google Earth Engine ◽

The Tarim River Basin

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Pixel- vs. Object-Based Landsat 8 Data Classification in Google Earth Engine Using Random Forest: The Case Study of Maiella National Park

Remote Sensing ◽

10.3390/rs13122299 ◽

2021 ◽

Vol 13 (12) ◽

pp. 2299

Author(s):

Andrea Tassi ◽

Daniela Gigante ◽

Giuseppe Modica ◽

Luciano Di Martino ◽

Marco Vizzari

Keyword(s):

Land Cover ◽

National Park ◽

Time Window ◽

Central Italy ◽

Google Earth ◽

Data Cube ◽

Landsat 8 ◽

Change Analysis ◽

Object Based ◽

Google Earth Engine

With the general objective of producing a 2018–2020 Land Use/Land Cover (LULC) map of the Maiella National Park (central Italy), useful for a future long-term LULC change analysis, this research aimed to develop a Landsat 8 (L8) data composition and classification process using Google Earth Engine (GEE). In this process, we compared two pixel-based (PB) and two object-based (OB) approaches, assessing the advantages of integrating the textural information in the PB approach. Moreover, we tested the possibility of using the L8 panchromatic band to improve the segmentation step and the object’s textural analysis of the OB approach and produce a 15-m resolution LULC map. After selecting the best time window of the year to compose the base data cube, we applied a cloud-filtering and a topography-correction process on the 32 available L8 surface reflectance images. On this basis, we calculated five spectral indices, some of them on an interannual basis, to account for vegetation seasonality. We added an elevation, an aspect, a slope layer, and the 2018 CORINE Land Cover classification layer to improve the available information. We applied the Gray-Level Co-Occurrence Matrix (GLCM) algorithm to calculate the image’s textural information and, in the OB approaches, the Simple Non-Iterative Clustering (SNIC) algorithm for the image segmentation step. We performed an initial RF optimization process finding the optimal number of decision trees through out-of-bag error analysis. We randomly distributed 1200 ground truth points and used 70% to train the RF classifier and 30% for the validation phase. This subdivision was randomly and recursively redefined to evaluate the performance of the tested approaches more robustly. The OB approaches performed better than the PB ones when using the 15 m L8 panchromatic band, while the addition of textural information did not improve the PB approach. Using the panchromatic band within an OB approach, we produced a detailed, 15-m resolution LULC map of the study area.

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