yotarazona / scikit-eo

A Python package for Remote Sensing Data Analysis
https://yotarazona.github.io/scikit-eo/
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scikit-eo: A Python package for Remote Sensing Data Analysis

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Journal of Open Source Software

Citation

Please, to cite the scikit-eo package in publications, use this paper:

Tarazona, Y., Benitez-Paez, F., Nowosad, J., Drenkhan, F., Nowosad, J., and Timaná, M. (2024). scikit-eo: A Python package for Remote Sensing Data Analysis. Journal of Open Source Software, 9(99), 6692. DOI: 10.21105/joss.06692

Introduction

Nowadays, remotely sensed data has increased dramatically. Microwaves and optical images with different spatial and temporal resolutions are available and are used to monitor a variety of environmental issues such as deforestation, land degradation, land use and land cover change, among others. Although there are efforts (i.e., Python packages, forums, communities, etc.) to make available line-of-code tools for pre-processing, processing and analysis of satellite imagery, there is still a gap that needs to be filled. In other words, too much time is still spent by many users developing Python lines of code. Algorithms for mapping land degradation through a linear trend of vegetation indices, fusion optical and radar images to classify vegetation cover, and calibration of machine learning algorithms, among others, are not available yet.

Therefore, scikit-eo is a Python package that provides tools for remote sensing. This package was developed to fill the gaps in remotely sensed data processing tools. Most of the tools are based on scientific publications, and others are useful algorithms that will allow processing to be done in a few lines of code. With these tools, the user will be able to invest time in analyzing the results of their data and not spend time on elaborating lines of code, which can sometimes be stressful.

Tools for Remote Sensing

Name of functions/classes Description
mla Machine Learning (Random Forest, Support Vector Machine, Decition Tree, Naive Bayes, Neural Network, etc.)
calmla Calibrating supervised classification in Remote Sensing (e.g., Monte Carlo Cross-Validation, Leave-One-Out Cross-Validation, etc.)
confintervalML Information of confusion matrix by proportions of area, overall accuracy, user's accuracy with confidence interval and estimated area with confidence interval as well.
rkmeans K-means classification
calkmeans This function allows to calibrate the kmeans algorithm. It is possible to obtain the best k value and the best embedded algorithm in kmeans.
pca Principal Components Analysis
atmosCorr Atmospheric Correction of satellite imagery
deepLearning Deep Learning algorithms
linearTrend Linear trend is useful for mapping forest degradation or land degradation
fusionrs This algorithm allows to fuse images coming from different spectral sensors (e.g., optical-optical, optical and SAR or SAR-SAR). Among many of the qualities of this function, it is possible to obtain the contribution (%) of each variable in the fused image
sma Spectral Mixture Analysis - Classification sup-pixel
tassCap The Tasseled-Cap Transformation.

You will find more algorithms!.

Dependencies used by scikit-eo

All dependencies used by scikit-eo are as follows:

numpy, pandas, matplotlib, rasterio, seaborn, statsmodels, scikit-learn, scipy, pytest, dbfread, fiona and geopandas. By installing scikit-eo all these packages will be installed!.

Installation

To use scikit-eo it is necessary to install it. There are two options:

1. From PyPI

scikit-eo is available on PyPI, so to install it, run this command in your terminal:

pip install scikeo

2. Installing from source

It is also possible to install the latest development version directly from the GitHub repository with:

pip install git+https://github.com/yotarazona/scikit-eo

containerizing scikit-eo

Note: It is a recommended practice to provide some instructions for isolating/containerizing scikit-eo. It would benefit their use and thus avoid that some dependencies are not compatible with others. For example, conda provides an easy solution.

conda create -n scikiteo python = 3.8

Then, activate the environment created

conda activate scikiteo

Then finally, scikit-eo can be install within this new environment using via PyPI or from the GitHub repository.

Example

1.0 Applying Machine Learning

Libraries to be used:

import rasterio
import numpy as np
from scikeo.mla import MLA
from scikeo.process import extract
import matplotlib.pyplot as plt
import matplotlib as mpl
import geopandas as gpd
from scikeo.plot import plotRGB
from scikeo.writeRaster import writeRaster

2.0 Optical image

Landsat-8 OLI (Operational Land Imager) will be used to obtain in order to classify using Random Forest (RF). This image, which is in surface reflectance with bands:

This image will be downloaded using the following codes:

import requests, zipfile
from io import BytesIO

# Defining the zip file URL
url = 'https://github.com/yotarazona/data/raw/main/data/01_machine_learning.zip'

# Split URL to get the file name
filename = url.split('/')[-1]

# Downloading the file by sending the request to the URL
req = requests.get(url)

# extracting the zip file contents
file = zipfile.ZipFile(BytesIO(req.content))
file.extractall()

3.0 Supervised Classification using Random Forest

Image and endmembers

data_dir = "01_machine_learning/"

# satellite image
path_raster = data_dir + "LC08_232066_20190727_SR.tif"
img = rasterio.open(path_raster)

# endmembers
path_endm = data_dir + "endmembers.shp"
endm = gpd.read_file(path_endm)
# endmembers
endm = extract(img, endm)
endm

header

Instance of mla():

inst = MLA(image = img, endmembers = endm)

Applying Random Forest:

svm_class = inst.SVM(training_split = 0.7)

4.0 Results

Dictionary of results

svm_class.keys()

Overall accuracy

svm_class.get('Overall_Accuracy')

Kappa index

svm_class.get('Kappa_Index')

Confusion matrix or error matrix

svm_class.get('Confusion_Matrix')

header

Preparing the image before plotting

# Let's define the color palette
palette = mpl.colors.ListedColormap(["#2232F9","#F922AE","#229954","#7CED5E"])

Applying the plotRGB() algorithm is easy:

# Let´s plot
fig, axes = plt.subplots(nrows = 1, ncols = 2, figsize = (15, 9))

# satellite image
plotRGB(img, title = 'Image in Surface Reflectance', ax = axes[0])

# class results
axes[1].imshow(svm_class.get('Classification_Map'), cmap = palette)
axes[1].set_title("Classification map")
axes[1].grid(False)

header

This result shows us how we can use the scikit-eo python package in order to obtaind a Land Cover map. Following this tutorial is it possible to use different algorithms such as Support Vector Machine, Decision Tree, Neural Networks, amont others.

Acknowledgment

Special thanks to:

Credits

This package was created with Cookiecutter

Logo inspiration

The logo on the package is inspired by fog oasis known as "lomas".