Normalized Multi-band Drought Index

Normalized Multi-band Drought Index for vegetation applications Vegetation indices quantify plant health, biomass, and photosynthetic activity by exploiting the contrast between how plants absorb visible light for photosynthesis and reflect near-infrared radiation from their cellular structure. NMDI is particularly suited for vegetation. The general formula is (N - (S1 - S2))/(N + (S1 - S2)), which requires N and S1 and S2 spectral bands.

NMDI is supported by 3 satellite sensors in our database, including Landsat 8/9, Sentinel-2, WorldView 3. Each sensor uses different band designations — for example, Landsat 8/9 uses the formula (B5 - (B6 - B7))/(B5 + (B6 - B7)), while Sentinel-2 uses (B8 - (B11 - B12))/(B8 + (B11 - B12)). Select a sensor above to see its specific band mapping.

NMDI requires N (770-900 nm), S1 (1550-1750 nm), S2 (2080-2350 nm). Vegetation strongly absorbs red light for photosynthesis while reflecting near-infrared light from its mesophyll cell structure, making this contrast a reliable indicator of plant vigour.

Both Python and R code samples are provided above. In Python, use rasterio to load individual band GeoTIFF files and numpy for the arithmetic. In R, the terra package handles raster operations efficiently. The key is to load bands as floating-point arrays to avoid integer division, and to handle division-by-zero cases where the denominator equals zero. For production use, consider applying a valid data mask to exclude no-data pixels before calculation.

While NDVI is the most common vegetation index, NMDI provides complementary information that NDVI cannot capture on its own. The choice of index depends on your application, sensor availability, and atmospheric conditions.