Learn R Programming

RStoolbox (version 0.2.4)

sam: Spectral Angle Mapper

Description

Calculates the angle in spectral space between pixels and a set of reference spectra (endmembers) for image classification based on spectral similarity.

Usage

sam(img, em, angles = FALSE, ...)

Arguments

img

RasterBrick or RasterStack. Remote sensing imagery (usually hyperspectral)

em

Matrix or data.frame with endmembers. Each row should contain the endmember spectrum of a class, i.e. columns correspond to bands in img. It is reccomended to set the rownames to class names.

angles

Logical. If TRUE a RasterBrick containing each one layer per endmember will be returned containing the spectral angles.

...

further arguments to be passed to writeRaster

Value

RasterBrick or RasterLayer If angles = FALSE a single Layer will be returned in which each pixel is assigned to the closest endmember class (integer pixel values correspond to row order of em.

Details

For each pixel the spectral angle mapper calculates the angle between the vector defined by the pixel values and each endmember vector. The result of this is one raster layer for each endmember containing the spectral angle. The smaller the spectral angle the more similar a pixel is to a given endmember class. In a second step one can the go ahead an enforce thresholds of maximum angles or simply classify each pixel to the most similar endmember.

Examples

Run this code
# NOT RUN {
library(raster)
library(ggplot2)
## Load example data-set
data(lsat) 

## Sample endmember spectra 
## First location is water, second is open agricultural vegetation
pts <- data.frame(x = c(624720, 627480), y = c(-414690, -411090))
endmembers <- extract(lsat, pts)
rownames(endmembers) <- c("water", "vegetation")

## Calculate spectral angles
lsat_sam <- sam(lsat, endmembers, angles = TRUE)
plot(lsat_sam)

## Classify based on minimum angle
lsat_sam <- sam(lsat, endmembers, angles = FALSE)

# }
# NOT RUN {
ggR(lsat_sam, forceCat = TRUE, geom_raster=TRUE) + 
        scale_fill_manual(values = c("blue", "green"), labels = c("water", "vegetation"))
# }

Run the code above in your browser using DataLab