Nearest neighbour resizing is the most common and simplest to implement.

Assuming your image is one layer/channel, and thus one matrix:

resizePixels = function(im, w, h) {
pixels = as.vector(im)
# initial width/height
w1 = nrow(im)
h1 = ncol(im)
# target width/height
w2 = w
h2 = h
# Create empty vector
temp = vector('numeric', w2*h2)
# Compute ratios
x_ratio = w1/w2
y_ratio = h1/h2
# Do resizing
for (i in 0:(h2-1)) {
for (j in 0:(w2-1)) {
px = floor(j*x_ratio)
py = floor(i*y_ratio)
temp[(i*w2)+j] = pixels[(py*w1)+px]
}
}
m = matrix(temp, h2, w2)
return(m)
}

I'll let you figure out how to apply this to a RGB image

Heres a test run for the code above on the red channel of this image:

```
lena = readImage('~/Desktop/lena.jpg')[,,1]
display(lena)
```

```
r = resizePixels(lena, 150, 150)
display(r)
```

```
r2 = resizePixels(lena, 50, 50)
display(r2)
```

Note:

- be careful, the target widths and heights must maintain the aspect ratio of the original image or it wont work
- If you're trying to avoid
`EBImage`

, to read/write images try the package `jpeg`

methods `readJPEG`

and `writeJPEG`

`rasterImage`

can do interpolation, but probably only when actually rendered. – baptiste Jun 2 '12 at 23:19