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Morgan B. Yarker

Yarker Consulting


Michel d. S. Mesquita

Uni Research Climate, Bjerknes Centre for Climate Research


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How to Design Publication-type Maps Using Google Maps and R

The statistical software R has become a widely used tool in science these days. It is free of charge, it is easy to use and it is very flexible. One of its flexibility features is the ability to create geographical maps using Google Maps (and also plotting/overlaying data on maps). 

Here, I would like to illustrate how to create a map showing weather station points in Norway on a Google Map. I will also show you how to save the map in high-resolution, so that you can use it in a publication or report. This is adapted from a plot I created for the HORDAKLIM Project, managed by Dr. Erik Kolstad at Uni Research Climate in Norway.


Installing R

If you do not have R on your machine, it is very easy to install it. You just download it from its main website at and follow the instructions there. I personally like to work with an R interface called RStudio (Fig. 1), which you can download here:


Figure 1 - Screenshot of R studio, showing a map with weather station points, where the size of the points are scaled according to the altitude of the station.


R packages you will need

In order to create the plots in this tutorial, you will need to download and load a few of packages in R. This is straightforward to do. After you open R (or RStudio), type the following there:





Now that they are installed, you don’t need to install them again. But you will need to load them whenever you use them. So, let’s load these packages to get started:






Data for this tutorial

We will create some data for the tutorial. The data contain the names of the stations, the latitude, the longitude and their altitude. If you prefer, you can also read the data from a text file. But here, we will do it directly in R. Note: the hashtag (#) below is used for comments.

# Create data

station<-c("Kaldestad", "Folgefonna", "Nesttun", "Flesland", "Midstova")





# Create data frame

stdata<-data.frame(sta=station, lat=lat, lon=lon, alt=altitude)



Classifying data into categories

We will classify our stations into four different categories. These are needed so that we can plot points with different sizes based on the station altitude. We will classify them as stations that are below 100m, between 100m and 600m, between 600m and 1200m and above 1200m.

# classify altitude into 4 categories

 stdata <- within(stdata, {

 label <- NA

 label[alt > 0 & alt <= 100] <- "A"

 label[alt > 100 & alt <= 600] <- "B"

 label[alt > 600 & alt <= 1200] <- "C"

 label[alt > 1200] <- "D"


# check the data with the classification



Making the first map

Now, we are ready to make our first map (Figure 2). We will create the map based on the latitude and longitude information from our dataset. The option zoom below can be changed, so that you can see closer or further away. So, type the following: 

# Making maps

MyMap <- MapBackground(lat=lat,lon=lon,zoom=10)


# Plot character size determined by altitude

tmp <- altitude

tmp <- tmp - min(tmp) # remove minimum

tmp <- tmp / max(tmp) # divide by maximum



Figure 2 - First map showing the five stations. The size of the stations are based on their altitude.


Second plot

Our second plot will be a bit more sophisticated, as we will use the ggplot2 package. Also, we will add a legend to the size of the stations (Figure 3). Here’s how we do that:

# Another way of plotting

basemap <- get_map(location=c(lon=mean(lon),lat=mean(lat)), zoom = 8, maptype='roadmap', source='google',crop=TRUE)


map1 <- ggmap(basemap, extent='panel', base_layer=ggplot(data=stdata, aes(x=lon, y=lat)))

# map showing point size based on altitude

map.alt <- map1+geom_point(aes(size=stdata$alt),color="darkblue")+scale_size(range=c(2,9),breaks=c(10,100,500,1000))

# add plot labels

map.alt <- map.alt + labs(x ="Longitude", y="Latitude", size = "Altitude")

# add title theme

map.alt <- map.alt + theme(plot.title = element_text(hjust = 0, vjust = 1, face = c("bold")))+theme(legend.position="bottom")



Figure 3 - map using ggplot2, which adds a legend related to the station altitude in meters.


Making a plot for a publication

Finally, if you want to save your plot in high-resolution for a publication (e.g.: 600 dpi), you can do the following:

# Map for a publication

# Plot based on altitude category

tiff("station_map.tif", res=600, compression = "lzw", height=4.8, width=4, units="in") <- map1+geom_point(aes(size=stdata$alt,group=stdata$label,


# manual color <-"#D55E00", "darkmagenta", "#0072B2","#009E73"),

                                      breaks=c("A", "B", "C","D"),

                                      labels=c("Coast", "Hill", "Mountain","High Mountain"))

# add plot labels <- + labs(x ="Longitude", y="Latitude", size = "Altitude", color="Location")

# add title theme <- + theme(legend.text = element_text(hjust = 0, vjust = 1,face = c("plain"),size=5),


                          legend.key = element_blank(), # remove gray background from legend


 theme(plot.margin = unit(x=c(0.1,0.1,0,0.1),units="in")) # ("left", "right", "bottom", "top") # remove extra margins in fig


The result is shown in Figure 4. Note that in this plot, we have added the location type and the altitude as legends in the plot.


Figure 4 - Station plot on Google Map and two types of legend: location type and altitude


I hope you have enjoyed this tutorial. If you have further questions, you are welcome to post them here.



We thank the Yarker Consulting, and the HORDAKLIM Project for making this work possible. Also, we are very grateful for Google, R, RStudio, ggplot2 and others for making their software and packages freely available!