My end goal in asking this question was to write a script where I can arbitrarily change the number of `kmeans`

clusters and quickly visualize the results with `voronoi`

polygons that cover my desired area region.

I haven't quite accomplished this yet, but I have made enough progress that I figured posting what I have may lead to a quicker solution.

```
# Create Input Data.Frame
input <- as.data.frame(cbind(x$long, x$lat))
colnames(input) <- c("long", "lat")
# Set Seed and Run Clustering Procedure
set.seed(123)
km <- kmeans(input, 35)
# Format Output for Plotting
centers <- as.data.frame(cbind(km$centers[,1], km$centers[,2]))
colnames(centers) <- c("long", "lat")
cent.id <- cbind(ID = 1:dim(centers)[1], centers)
# Create Spatial Points Data Frame for Calculating Voronoi Polygons
coords <- centers[,1:2]
vor_pts <- SpatialPointsDataFrame(coords, centers, proj4string = CRS("+proj=longlat +datum=WGS84"))
```

I also found the below.function while searching for a solution online.

```
# Function to Extract Voronoi Polygons
SPdf_to_vpoly <- function(sp) {
# tile.list extracts the polygon data from the deldir computation
vor_desc <- tile.list(deldir(sp@coords[,1], sp@coords[,2]))
lapply(1:length(vor_desc), function(i) {
# tile.list gets us the points for the polygons but we
# still have to close them, hence the need for the rbind
tmp <- cbind(vor_desc[[i]]$x, vor_desc[[i]]$y)
tmp <- rbind(tmp, tmp[1,])
# Now we can make the polygons
Polygons(list(Polygon(tmp)), ID = i)
}) -> vor_polygons
# Hopefully the caller passed in good metadata
sp_dat <- sp@data
# This way the IDs should match up with the data & voronoi polys
rownames(sp_dat) <- sapply(slot(SpatialPolygons(vor_polygons), 'polygons'), slot, 'ID')
SpatialPolygonsDataFrame(SpatialPolygons(vor_polygons), data = sp_dat)
}
```

With the above function defined polygons can be extracted accordingly

```
vor <- SPdf_to_vpoly(vor_pts)
vor_df <- fortify(vor)
```

In order to get the `voronoi`

polygons to fit nicely with a US map I downloaded cb_2014_us_state_20m from the `Census`

website and ran the following:

```
# US Map Plot to Intersect with Voronoi Polygons - download from census link and place in working directory
us.shp <- readOGR(dsn = ".", layer = "cb_2014_us_state_20m")
state.abb <- state.abb[!state.abb %in% c("HI", "AK")]
Low48 <- us.shp[us.shp@data$STUSPS %in% state.abb,]
# Define Area Polygons and Projections and Calculate Intersection
Low48.poly <- as(Low48, "SpatialPolygons")
vor.poly <- as(vor, "SpatialPolygons")
proj4string(vor.poly) <- proj4string(Low48.poly)
intersect <- gIntersection(vor.poly, Low48.poly, byid = T)
# Convert to Data Frames to Plot with ggplot
Low48_df <- fortify(Low48.poly)
int_df <- fortify(intersect)
```

From here I could visualize my results using `ggplot`

like before:

```
# Plot Results
StateMap <- ggplot() + geom_polygon(data = Low48_df, aes(x = long, y = lat, group = group), col = "white")
StateMap +
geom_polygon(data = int_df, aes(x = long, y = lat, group = group, fill = id), alpha = .4) +
geom_point(data = input, aes(x = long, y = lat), col = factor(km$cluster)) +
geom_label(data = centers, aes(x = long, y = lat, label = row.names(centers)), alpha =.2) +
scale_fill_hue(guide = 'none') +
coord_map("albers", lat0 = 30, lat1 = 40)
```

### Summary of Updates

The overlapping `voronoi`

polygons still aren't a perfect fit (I'm guessing due to a lack of input data in the pacific northwest) although I'd imagine that should be a simple fix and I'll try to update that as soon as possible. Also if I alter the number of `kmeans centroids`

in the beginning of my function and then re-run everything the polygons don't look very nice at all which is not what I was originally hoping for. I'll continue to update with improvements.