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I am overlaying a world map from the maps package onto a ggplot2 raster geometry. However, this raster is not centered on the prime meridian (0 deg), but on 180 deg (roughly the Bering Sea and the Pacific). The following code gets the map and recenters the map on 180 degree:

world_map = data.frame(map(plot=FALSE)[c("x","y")])
names(world_map) = c("lon","lat")
world_map = within(world_map, {
  lon = ifelse(lon < 0, lon + 360, lon)
ggplot(aes(x = lon, y = lat), data = world_map) + geom_path()

which yields the following output:

enter image description here

Quite obviously there are the lines draw between polygons that are on one end or the other of the prime meridian. My current solution is to replace points close to the prime meridian by NA, replacing the within call above by:

world_map = within(world_map, {
  lon = ifelse(lon < 0, lon + 360, lon)
  lon = ifelse((lon < 1) | (lon > 359), NA, lon)
ggplot(aes(x = lon, y = lat), data = world_map) + geom_path()

Which leads to the correct image. I now have a number of question:

  1. There must be a better way of centering the map on another meridian. I tried using the orientation parameter in map, but setting this to orientation = c(0,180,0) did not yield the correct result, in fact it did not change anything to the result object (all.equal yielded TRUE).
  2. Getting rid of the horizontal stripes should be possible without deleting some of the polygons. It might be that solving point 1. also solves this point.
share|improve this question
If you're just interested in centring the map around 180 deg., the map "world2" in the maps package or a high-resolution version "world2Hires" in the mapdata package are already centered on 180 deg. The rest of your code works fine. – Jim M. May 16 '12 at 18:53
Thanks for the comment! I am still interested in a flexible solution though. – Paul Hiemstra May 17 '12 at 6:38
Are you only interested in a ggplot solution? I would do most of this using sp and related packages, but don't know anything about converting sp's Spatial* objects (especially the raster-representing ones) to ggplot... – Josh O'Brien May 23 '12 at 20:58
Sp classes to something ggplot2 can use is quite easy. So I'm open to sp based answers. – Paul Hiemstra May 23 '12 at 21:38
@PaulHiemstra -- Is this (from a month or two previous) also a solution?… – Josh O'Brien Jun 26 '12 at 13:32

2 Answers 2

up vote 11 down vote accepted

Here's a different approach. It works by:

  1. Converting the world map from the maps package into a SpatialLines object with a geographical (lat-long) CRS.
  2. Projecting the SpatialLines map into the Plate Carée (aka Equidistant Cylindrical) projection centered on the Prime Meridian. (This projection is very similar to a geographical mapping).
  3. Cutting in two segments that would otherwise be clipped by left and right edges of the map. (This is done using topological functions from the rgeos package.)
  4. Reprojecting to a Plate Carée projection centered on the desired meridian (lon_0 in terminology taken from the PROJ_4 program used by spTransform() in the rgdal package).
  5. Identifying (and removing) any remaining 'streaks'. I automated this by searching for lines that cross g.e. two of three widely separated meridians. (This also uses topological functions from the rgeos package.)

This is obviously a lot of work, but leaves one with maps that are minimally truncated, and can be easily reprojected using spTransform(). To overlay these on top of raster images with base or lattice graphics, I first reproject the rasters, also using spTransform(). If you need them, grid lines and labels can likewise be projected to match the SpatialLines map.

library(maptools)   ## map2SpatialLines(), pruneMap()
library(rgdal)      ## CRS(), spTransform()
library(rgeos)      ## readWKT(), gIntersects(), gBuffer(), gDifference() 

## Convert a "maps" map to a "SpatialLines" map
makeSLmap <- function() {
    llCRS <- CRS("+proj=longlat +ellps=WGS84")
    wrld <- map("world", interior = FALSE, plot=FALSE,
            xlim = c(-179, 179), ylim = c(-89, 89))
    wrld_p <- pruneMap(wrld, xlim = c(-179, 179))
    map2SpatialLines(wrld_p, proj4string = llCRS)

## Clip SpatialLines neatly along the antipodal meridian
sliceAtAntipodes <- function(SLmap, lon_0) {
    ## Preliminaries
    long_180 <- (lon_0 %% 360) - 180
    llCRS  <- CRS("+proj=longlat +ellps=WGS84")  ## CRS of 'maps' objects
    eqcCRS <- CRS("+proj=eqc")
    ## Reproject the map into Equidistant Cylindrical/Plate Caree projection 
    SLmap <- spTransform(SLmap, eqcCRS)
    ## Make a narrow SpatialPolygon along the meridian opposite lon_0
    L  <- Lines(Line(cbind(long_180, c(-89, 89))), ID="cutter")
    SL <- SpatialLines(list(L), proj4string = llCRS)
    SP <- gBuffer(spTransform(SL, eqcCRS), 10)
    ## Use it to clip any SpatialLines segments that it crosses
    ii <- which(gIntersects(SLmap, SP, byid=TRUE))
    # Replace offending lines with split versions
    # (but skip when there are no intersections (as, e.g., when lon_0 = 0))
    if(length(ii)) { 
        SPii <- gDifference(SLmap[ii], SP, byid=TRUE)
        SLmap <- rbind(SLmap[-ii], SPii)  

## re-center, and clean up remaining streaks
recenterAndClean <- function(SLmap, lon_0) {
    llCRS <- CRS("+proj=longlat +ellps=WGS84")  ## map package's CRS
    newCRS <- CRS(paste("+proj=eqc +lon_0=", lon_0, sep=""))
    ## Recenter 
    SLmap <- spTransform(SLmap, newCRS)
    ## identify remaining 'scratch-lines' by searching for lines that
    ## cross 2 of 3 lines of longitude, spaced 120 degrees apart
    v1 <-spTransform(readWKT("LINESTRING(-62 -89, -62 89)", p4s=llCRS), newCRS)
    v2 <-spTransform(readWKT("LINESTRING(58 -89, 58 89)",   p4s=llCRS), newCRS)
    v3 <-spTransform(readWKT("LINESTRING(178 -89, 178 89)", p4s=llCRS), newCRS)
    ii <- which((gIntersects(v1, SLmap, byid=TRUE) +
                 gIntersects(v2, SLmap, byid=TRUE) +
                 gIntersects(v3, SLmap, byid=TRUE)) >= 2)

## Put it all together:
Recenter <- function(lon_0 = -100, grid=FALSE, ...) {                        
    SLmap <- makeSLmap()
    SLmap2 <- sliceAtAntipodes(SLmap, lon_0)
    recenterAndClean(SLmap2, lon_0)

## Try it out
par(mfrow=c(2,2), mar=rep(1, 4))
plot(Recenter(-90), col="grey40"); box() ## Centered on 90w 
plot(Recenter(0),   col="grey40"); box() ## Centered on prime meridian
plot(Recenter(90),  col="grey40"); box() ## Centered on 90e
plot(Recenter(180), col="grey40"); box() ## Centered on International Date Line

enter image description here

share|improve this answer
This is great and works a treat. Is there a way to do something similar with a SpatialPolygons object so we can keep the country border information? – Peter Ellis Jul 6 '12 at 1:42
@PeterEllis -- That's what I first tried, using (IIRC) rgeos' gBuffer() to make a thin vertical polygon along the splitting meridian, and then gDifference() to cut the SpatialPolygons that it crossed. Unfortunately, rgeos' polygon-checking standards are too high, & it rejected any SpatialPolygons I could create from the map object, with messages about invalid topologies etc. I banged my head against the wall for too long trying to fix the polygons, so if you figure anything out, please do let me know! Alternatively, does the solution I linked in comments to the question above work? – Josh O'Brien Jul 6 '12 at 13:09
up vote 18 down vote

This may be somewhat tricky but you can do by:

mp1 <- fortify(map(fill=TRUE, plot=FALSE))
mp2 <- mp1
mp2$long <- mp2$long + 360
mp2$group <- mp2$group + max(mp2$group) + 1
mp <- rbind(mp1, mp2)
ggplot(aes(x = long, y = lat, group = group), data = mp) + 
  geom_path() + 
  scale_x_continuous(limits = c(0, 360))

enter image description here

By this setup you can easily set the center (i.e., limits):

ggplot(aes(x = long, y = lat, group = group), data = mp) + 
  geom_path() + 
  scale_x_continuous(limits = c(-100, 260))

enter image description here


Here I put some explanations:

The whole data looks like:

ggplot(aes(x = long, y = lat, group = group), data = mp) + geom_path()

enter image description here

but by scale_x_continuous(limits = c(0, 360)), you can crop a subset of the region from 0 to 360 longitude.

And in geom_path, the data of same group are connected. So if mp2$group <- mp2$group + max(mp2$group) + 1 is absent, it looks like: enter image description here

share|improve this answer
any chance of sketching how that actually works (to a curious non-r-user)? – andrew cooke May 17 '12 at 3:39
+1, works nicely! Although I am still curious if I can prevent tinkereing with the output of map, and specifying it by changing the input of map. – Paul Hiemstra May 17 '12 at 6:38
As map(orientation = c(90, 0, 180), projection="mercator") also fails, there may be no way. – kohske May 21 '12 at 2:06
Great solution. Is there a way to make it work if you want to map fill to country as well? – Peter Ellis Jul 6 '12 at 0:20

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