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#Learn-GEE learning ML using GEE (Google Earth Engine) javascript API as a beginner

google earth engine with javascript api

Capture d'écran 2024-07-08 111938 Capture d'écran 2024-07-08 111954 Capture d'écran 2024-07-08 112021 Capture d'écran 2024-07-08 111921

learning results: ( the repo contains more than what is presented here )

Part I: Programming and Remote Sensing Basics Objective: To gain a fundamental understanding of remote sensing data and programming. Activities: Programming Basics: Learned the basics of programming, including defining variables, printing values, and other fundamental steps. Displaying Remote Sensing Data: Acquired skills to display remote sensing data using software tools and basic programming scripts. Earth Engine Data Catalog: Explored the extensive data catalog of Earth Engine, understanding the types and sources of data available. Remote Sensing Vocabulary: Familiarized myself with the key vocabulary and concepts in remote sensing, which is essential for both novices and those starting with Earth Engine. Outcome: Developed a strong foundation in programming and remote sensing, enabling me to efficiently handle remote sensing data and perform basic operations. Capture d'écran 2024-07-19 212121 RGB composite of stable nighttime lights (2013, 2003, 1993) Capture d'écran 2024-07-19 212023 Global Forest Change 2000–2020 tree cover loss (yellow–red) and 2000 tree cover (black-green) Capture d'écran 2024-07-19 211833 3 NAIP color-IR composite over the San Francisco airport

Part II: Interpreting Images Objective: To understand and apply basic operations on individual satellite images. Activities: Manipulating Image Bands: Learned how to manipulate bands of remote sensing images to form indices. Image Classification: Applied various supervised and unsupervised classification techniques to categorize remote sensing images. Result Assessment and Adjustment: Gained skills in assessing classification results and making necessary adjustments to improve accuracy. Outcome: Enhanced my ability to interpret and analyze satellite images, leading to more accurate and meaningful insights from remote sensing data.

Capture d'écran 2024-07-19 214739 Thresholded water, forest, and non-forest image based on NDVI for Seattle, Washington, Capture d'écran 2024-07-19 214922 CART classification
Capture d'écran 2024-07-19 214943 CART regression Capture d'écran 2024-07-19 215003 Random forest classified image
Capture d'écran 2024-07-19 215021 K-means classification Capture d'écran 2024-07-19 215505 Chart showing accuracy per number of random forest trees

Part III: Advanced Image Processing Objective: To apply advanced image processing techniques to remote sensing data. Activities: Band Regression: Learned to find relationships between two or more bands using regression analysis. Tasseled Cap and Principal Components Transformations: Applied linear combinations of bands to produce tasseled cap and principal components transformations. Morphological Operations: Performed morphological operations on classified images to highlight or de-emphasize spatial characteristics. Object-Based Image Analysis: Conducted object-based image analysis, grouping pixels into spectrally similar and spatially contiguous clusters. Outcome: Acquired advanced image processing skills, enabling me to perform complex analyses and derive sophisticated insights from remote sensing data. Capture d'écran 2024-07-19 220056 True-color Sentinel-2 image Capture d'écran 2024-07-19 220200 Pixel-based unsupervised classification using four-class k-means unsupervised classification and bands from the visible spectrum Capture d'écran 2024-07-19 220214 Pixel-based unsupervised classification using four-class k-means unsupervised classification and bands from outside of the visible spectrum Capture d'écran 2024-07-19 220119 SNIC clusters