Let us assume we have a raster `A`

and two SpatialPolygon objects `[B, C]`

that are not rectangular (hexagons in this case).
For demonstrating purposes the center of hexagon `B`

is defined to be the center of our raster `A`

(see left plot below). Hexagon `C`

is shifted to the right along the horizontal axis.

```
require(raster)
require(scales)
A <- raster(nrow=2, ncol=2, xmn=-180, xmx=180, ymn=-180, ymx=180)
A[] <- c(1,2,4,5)
A.pl <- as(A, 'SpatialPolygons')
B <- SpatialPolygons(list(Polygons(list(Polygon(cbind(c(0, 100, 100, 0, -100, -100, 0),
c(100, 50, -50, -100, -50, 50, 100)))), 'B')))
C <- SpatialPolygons(list(Polygons(list(Polygon(cbind(c(40, 140, 140, 40, -60, -60, 40),
c(100, 50, -50, -100, -50, 50, 100)))), 'C')))
```

## Object B

Since hexagon `B`

is in the center, the weights should all equal 0.25.
We can easily derive from the plot that the area of the hexagons is 30000 (imagine a square that the hexagon fits in (40000) and substract 2 rectangulars (-10000), each consisting of 2 of the 4 corners you have to cut off). Therefore, each intersection area is of size 7500 and `7500/30000 = 0.25`

```
# get intersections
intsct.B <- raster::intersect(B, A.pl)
intsct.C <- raster::intersect(C, A.pl)
### B
area.B <- B@polygons[[1]]@area
weights <- unlist(lapply(intsct.B@polygons, function(x) {
slot(x, 'area')/area.B
}))
weights
> [1] 0.25 0.25 0.25 0.25
```

Now we get the value of the cells that each intersection polygon falls in and compute the mean.

```
vals <- unlist(lapply(intsct.B@polygons, function(x) {
extract(A, data.frame(t(slot(x, 'labpt'))))
}))
sum(weights * vals)
> [1] 3
```

As we would expect, the mean of `c(1, 2, 4, 5)`

is `3`

.

## Object C

Now lets do the same with object `C`

```
### C
area.C <- C@polygons[[1]]@area
weights <- unlist(lapply(intsct.C@polygons, function(x) {
slot(x, 'area')/area.C
}))
weights
> [1] 0.13 0.37 0.13 0.37
vals <- unlist(lapply(intsct.C@polygons, function(x) {
extract(A, data.frame(t(slot(x, 'labpt'))))
}))
sum(weights * vals)
> [1] 3.24
```

Again, as we would expect the mean is bigger (since the weights for the cells with values 2 and 5 are higher). Also, since we shifted the hexagon along one axis only, it makes sense that 2 weights occur twice.

## Raster with higher number of cells

The next plot shows the intersections of `B`

(left hand side) and `C`

(rhs) with a `4x4`

raster with values `c(1:8, 10:17)`

. For `B`

there are 12 intersections and for `C`

8. Notice again that the mean for `B`

is exactly 9 because of the symmetry.

This should work for any `SpatialPolygons`

object. Be sure to use the same CRS for the objects you throw into `intersect`

.

`extract`

is unable to deliver. If you read`?extract`

, you will notice " If y represents polygons, the extract method returns the values of the cells of a Raster* object that are covered by a polygon.A cell is covered if its center is inside the polygon(but see the weights option for considering partly covered cells;". Perhaps you could coerce your raster to a polygon (`rasterToPolygons`

) and find areas of overlap using`rgeos`

package? – Roman Luštrik Apr 25 '17 at 11:27