| name | gis-remote-sensing-guide |
| description | GIS analysis and remote sensing workflows for geospatial research applications |
| metadata | {"openclaw":{"emoji":"🌎","category":"domains","subcategory":"geoscience","keywords":["GIS","remote sensing","geology","atmospheric science","climatology","geospatial analysis"],"source":"wentor"}} |
GIS and Remote Sensing Guide
A comprehensive skill for conducting geospatial analysis and remote sensing research. Covers data acquisition from satellite platforms, spatial analysis with open-source tools, and publication-quality map production.
Satellite Data Sources
Key Earth Observation Platforms
| Platform | Provider | Spatial Res. | Revisit | Free? | Use Case |
|---|
| Landsat 8/9 | USGS/NASA | 30m (MS), 15m (pan) | 16 days | Yes | Land cover, NDVI time series |
| Sentinel-2 | ESA/Copernicus | 10m | 5 days | Yes | Agriculture, urban mapping |
| MODIS | NASA | 250m-1km | 1-2 days | Yes | Large-scale vegetation, fire |
| Sentinel-1 | ESA | 5-20m | 6 days | Yes | SAR, flood mapping, deformation |
| SRTM/ASTER | NASA | 30m | N/A | Yes | Digital elevation models |
Data Download with Python
import ee
ee.Initialize()
def get_sentinel2_composite(aoi: ee.Geometry, start: str, end: str,
cloud_max: int = 20) -> ee.Image:
"""
Create a cloud-free Sentinel-2 composite.
Args:
aoi: Area of interest as ee.Geometry
start: Start date (YYYY-MM-DD)
end: End date (YYYY-MM-DD)
cloud_max: Maximum cloud cover percentage
"""
collection = (ee.ImageCollection('COPERNICUS/S2_SR_HARMONIZED')
.filterBounds(aoi)
.filterDate(start, end)
.filter(ee.Filter.lt('CLOUDY_PIXEL_PERCENTAGE', cloud_max)))
def mask_clouds(image):
scl = image.select('SCL')
mask = scl.neq(3).And(scl.neq(8)).And(scl.neq(9)).And(scl.neq(10))
return image.updateMask(mask)
return collection.map(mask_clouds).median().clip(aoi)
study_area = ee.Geometry.Rectangle([116.0, 39.5, 117.0, 40.5])
composite = get_sentinel2_composite(study_area, '2024-06-01', '2024-09-30')
Spatial Analysis with GeoPandas
Vector Data Processing
import geopandas as gpd
from shapely.geometry import Point
def spatial_join_analysis(points_gdf: gpd.GeoDataFrame,
polygons_gdf: gpd.GeoDataFrame,
agg_col: str) -> gpd.GeoDataFrame:
"""
Perform spatial join and aggregate point data within polygons.
"""
joined = gpd.sjoin(points_gdf, polygons_gdf, how='inner', predicate='within')
summary = joined.groupby('index_right').agg(
count=(agg_col, 'count'),
mean_value=(agg_col, 'mean'),
std_value=(agg_col, 'std')
).reset_index()
result = polygons_gdf.merge(summary, left_index=True, right_on='index_right')
return result
soil_samples = gpd.read_file('soil_data.geojson')
admin_bounds = gpd.read_file('admin_boundaries.shp')
result = spatial_join_analysis(soil_samples, admin_bounds, 'pH_value')
Remote Sensing Indices
Vegetation and Water Indices
import rasterio
import numpy as np
def compute_indices(image_path: str) -> dict:
"""Compute common remote sensing spectral indices."""
with rasterio.open(image_path) as src:
red = src.read(3).astype(float)
nir = src.read(4).astype(float)
green = src.read(2).astype(float)
swir = src.read(5).astype(float)
ndvi = (nir - red) / (nir + red + 1e-10)
ndwi = (green - nir) / (green + nir + 1e-10)
nbr = (nir - swir) / (nir + swir + 1e-10)
return {'NDVI': ndvi, 'NDWI': ndwi, 'NBR': nbr}
Map Production
For publication-quality maps, always include: scale bar, north arrow, coordinate reference system label, legend, and data source attribution. Use matplotlib with cartopy for projected maps, or folium for interactive web maps. Export at 300 DPI minimum for journal submissions.
Coordinate Reference Systems
Always verify and document the CRS. Use EPSG codes (e.g., EPSG:4326 for WGS84, EPSG:32650 for UTM Zone 50N). Reproject all layers to a common CRS before spatial operations to avoid misalignment errors.
