Convert from .csv to a Shapefile
Overview
Teaching: 30 min
Exercises: 15 minQuestions
How can I import CSV files as shapefiles in R?
Objectives
Import .csv files containing x,y coordinate locations into R as a data frame.
Convert a data frame to a spatial object.
Export a spatial object to a text file.
Things You’ll Need To Complete This Episode
See the lesson homepage for detailed information about the software, data, and other prerequisites you will need to work through the examples in this episode.
This episode will review how to import spatial points stored in .csv
(Comma Separated Value) format into R as an sf
spatial object. We will also reproject data imported from a shapefile format, export this data as a shapefile, and plot raster and vector data as layers in the same plot.
Spatial Data in Text Format
The HARV_PlotLocations.csv
file contains x, y
(point) locations for study
plot where NEON collects data on
vegetation and other ecological metrics.
We would like to:
- Create a map of these plot locations.
- Export the data in a
shapefile
format to share with our colleagues. This shapefile can be imported into any GIS software. - Create a map showing vegetation height with plot locations layered on top.
Spatial data are sometimes stored in a text file format (.txt
or .csv
). If
the text file has an associated x
and y
location column, then we can
convert it into an sf
spatial object. The sf
object allows us to store both the x,y
values that represent the coordinate location
of each point and the associated attribute data - or columns describing each
feature in the spatial object.
We will continue using the sf
and raster
packages in this episode.
Import .csv
To begin let’s import a .csv
file that contains plot coordinate x, y
locations at the NEON Harvard Forest Field Site (HARV_PlotLocations.csv
) and look at the structure of
that new object:
plot_locations_HARV <-
read.csv("data/NEON-DS-Site-Layout-Files/HARV/HARV_PlotLocations.csv")
str(plot_locations_HARV)
'data.frame': 21 obs. of 16 variables:
$ easting : num 731405 731934 731754 731724 732125 ...
$ northing : num 4713456 4713415 4713115 4713595 4713846 ...
$ geodeticDa: chr "WGS84" "WGS84" "WGS84" "WGS84" ...
$ utmZone : chr "18N" "18N" "18N" "18N" ...
$ plotID : chr "HARV_015" "HARV_033" "HARV_034" "HARV_035" ...
$ stateProvi: chr "MA" "MA" "MA" "MA" ...
$ county : chr "Worcester" "Worcester" "Worcester" "Worcester" ...
$ domainName: chr "Northeast" "Northeast" "Northeast" "Northeast" ...
$ domainID : chr "D01" "D01" "D01" "D01" ...
$ siteID : chr "HARV" "HARV" "HARV" "HARV" ...
$ plotType : chr "distributed" "tower" "tower" "tower" ...
$ subtype : chr "basePlot" "basePlot" "basePlot" "basePlot" ...
$ plotSize : int 1600 1600 1600 1600 1600 1600 1600 1600 1600 1600 ...
$ elevation : num 332 342 348 334 353 ...
$ soilTypeOr: chr "Inceptisols" "Inceptisols" "Inceptisols" "Histosols" ...
$ plotdim_m : int 40 40 40 40 40 40 40 40 40 40 ...
We now have a data frame that contains 21 locations (rows) and 16 variables (attributes). Note that all of our character data was imported into R as factor (categorical) data. Next, let’s explore the dataframe to determine whether it contains columns with coordinate values. If we are lucky, our .csv
will contain columns labeled:
- “X” and “Y” OR
- Latitude and Longitude OR
- easting and northing (UTM coordinates)
Let’s check out the column names of our dataframe.
names(plot_locations_HARV)
[1] "easting" "northing" "geodeticDa" "utmZone" "plotID"
[6] "stateProvi" "county" "domainName" "domainID" "siteID"
[11] "plotType" "subtype" "plotSize" "elevation" "soilTypeOr"
[16] "plotdim_m"
Identify X,Y Location Columns
Our column names include several fields that might contain spatial information. The plot_locations_HARV$easting
and plot_locations_HARV$northing
columns contain coordinate values. We can confirm
this by looking at the first six rows of our data.
head(plot_locations_HARV$easting)
[1] 731405.3 731934.3 731754.3 731724.3 732125.3 731634.3
head(plot_locations_HARV$northing)
[1] 4713456 4713415 4713115 4713595 4713846 4713295
We have coordinate values in our data frame. In order to convert our
data frame to an sf
object, we also need to know the CRS
associated with those coordinate values.
There are several ways to figure out the CRS of spatial data in text format.
- We can check the file metadata in hopes that the CRS was recorded in the data.
- We can explore the file itself to see if CRS information is embedded in the file header or somewhere in the data columns.
Following the easting
and northing
columns, there is a geodeticDa
and a
utmZone
column. These appear to contain CRS information
(datum
and projection
). Let’s view those next.
head(plot_locations_HARV$geodeticDa)
[1] "WGS84" "WGS84" "WGS84" "WGS84" "WGS84" "WGS84"
head(plot_locations_HARV$utmZone)
[1] "18N" "18N" "18N" "18N" "18N" "18N"
It is not typical to store CRS information in a column. But this particular
file contains CRS information this way. The geodeticDa
and utmZone
columns
contain the information that helps us determine the CRS:
geodeticDa
: WGS84 – this is geodetic datum WGS84utmZone
: 18
In
When Vector Data Don’t Line Up - Handling Spatial Projection & CRS in R
we learned about the components of a proj4
string. We have everything we need
to assign a CRS to our data frame.
To create the proj4
associated with UTM Zone 18 WGS84 we can look up the
projection on the Spatial Reference website, which contains a list of CRS formats for each projection. From here, we can extract the proj4 string for UTM Zone 18N WGS84.
However, if we have other data in the UTM Zone 18N projection, it’s much
easier to use the st_crs()
function to extract the CRS in proj4
format from that object and
assign it to our
new spatial object. We’ve seen this CRS before with our Harvard Forest study site (point_HARV
).
st_crs(point_HARV)
Coordinate Reference System:
User input: WGS 84 / UTM zone 18N
wkt:
PROJCRS["WGS 84 / UTM zone 18N",
BASEGEOGCRS["WGS 84",
DATUM["World Geodetic System 1984",
ELLIPSOID["WGS 84",6378137,298.257223563,
LENGTHUNIT["metre",1]]],
PRIMEM["Greenwich",0,
ANGLEUNIT["degree",0.0174532925199433]],
ID["EPSG",4326]],
CONVERSION["UTM zone 18N",
METHOD["Transverse Mercator",
ID["EPSG",9807]],
PARAMETER["Latitude of natural origin",0,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8801]],
PARAMETER["Longitude of natural origin",-75,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8802]],
PARAMETER["Scale factor at natural origin",0.9996,
SCALEUNIT["unity",1],
ID["EPSG",8805]],
PARAMETER["False easting",500000,
LENGTHUNIT["metre",1],
ID["EPSG",8806]],
PARAMETER["False northing",0,
LENGTHUNIT["metre",1],
ID["EPSG",8807]]],
CS[Cartesian,2],
AXIS["(E)",east,
ORDER[1],
LENGTHUNIT["metre",1]],
AXIS["(N)",north,
ORDER[2],
LENGTHUNIT["metre",1]],
ID["EPSG",32618]]
The output above shows that the points shapefile is in
UTM zone 18N. We can thus use the CRS from that spatial object to convert our
non-spatial dataframe into an sf
object.
Next, let’s create a crs
object that we can use to define the CRS of our
sf
object when we create it.
utm18nCRS <- st_crs(point_HARV)
utm18nCRS
Coordinate Reference System:
User input: WGS 84 / UTM zone 18N
wkt:
PROJCRS["WGS 84 / UTM zone 18N",
BASEGEOGCRS["WGS 84",
DATUM["World Geodetic System 1984",
ELLIPSOID["WGS 84",6378137,298.257223563,
LENGTHUNIT["metre",1]]],
PRIMEM["Greenwich",0,
ANGLEUNIT["degree",0.0174532925199433]],
ID["EPSG",4326]],
CONVERSION["UTM zone 18N",
METHOD["Transverse Mercator",
ID["EPSG",9807]],
PARAMETER["Latitude of natural origin",0,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8801]],
PARAMETER["Longitude of natural origin",-75,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8802]],
PARAMETER["Scale factor at natural origin",0.9996,
SCALEUNIT["unity",1],
ID["EPSG",8805]],
PARAMETER["False easting",500000,
LENGTHUNIT["metre",1],
ID["EPSG",8806]],
PARAMETER["False northing",0,
LENGTHUNIT["metre",1],
ID["EPSG",8807]]],
CS[Cartesian,2],
AXIS["(E)",east,
ORDER[1],
LENGTHUNIT["metre",1]],
AXIS["(N)",north,
ORDER[2],
LENGTHUNIT["metre",1]],
ID["EPSG",32618]]
class(utm18nCRS)
[1] "crs"
.csv to sf object
Next, let’s convert our dataframe into an sf
object. To do
this, we need to specify:
- The columns containing X (
easting
) and Y (northing
) coordinate values - The CRS that the column coordinate represent (units are included in the CRS) - stored in our
utmCRS
object.
We will use the st_as_sf()
function to perform the conversion.
plot_locations_sp_HARV <- st_as_sf(plot_locations_HARV, coords = c("easting", "northing"), crs = utm18nCRS)
We should double check the CRS to make sure it is correct.
st_crs(plot_locations_sp_HARV)
Coordinate Reference System:
User input: WGS 84 / UTM zone 18N
wkt:
PROJCRS["WGS 84 / UTM zone 18N",
BASEGEOGCRS["WGS 84",
DATUM["World Geodetic System 1984",
ELLIPSOID["WGS 84",6378137,298.257223563,
LENGTHUNIT["metre",1]]],
PRIMEM["Greenwich",0,
ANGLEUNIT["degree",0.0174532925199433]],
ID["EPSG",4326]],
CONVERSION["UTM zone 18N",
METHOD["Transverse Mercator",
ID["EPSG",9807]],
PARAMETER["Latitude of natural origin",0,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8801]],
PARAMETER["Longitude of natural origin",-75,
ANGLEUNIT["Degree",0.0174532925199433],
ID["EPSG",8802]],
PARAMETER["Scale factor at natural origin",0.9996,
SCALEUNIT["unity",1],
ID["EPSG",8805]],
PARAMETER["False easting",500000,
LENGTHUNIT["metre",1],
ID["EPSG",8806]],
PARAMETER["False northing",0,
LENGTHUNIT["metre",1],
ID["EPSG",8807]]],
CS[Cartesian,2],
AXIS["(E)",east,
ORDER[1],
LENGTHUNIT["metre",1]],
AXIS["(N)",north,
ORDER[2],
LENGTHUNIT["metre",1]],
ID["EPSG",32618]]
Plot Spatial Object
We now have a spatial R object, we can plot our newly created spatial object.
ggplot() +
geom_sf(data = plot_locations_sp_HARV) +
ggtitle("Map of Plot Locations")
Plot Extent
In
Open and Plot Shapefiles in R
we learned about spatial object extent. When we plot several spatial layers in
R using ggplot
, all of the layers of the plot are considered in setting the boundaries
of the plot. To show this, let’s plot our aoi_boundary_HARV
object with our vegetation plots.
ggplot() +
geom_sf(data = aoi_boundary_HARV) +
geom_sf(data = plot_locations_sp_HARV) +
ggtitle("AOI Boundary Plot")
When we plot the two layers together, ggplot
sets the plot boundaries
so that they are large enough to include all of the data included in all of the layers.
That’s really handy!
Challenge - Import & Plot Additional Points
We want to add two phenology plots to our existing map of vegetation plot locations.
Import the .csv:
HARV/HARV_2NewPhenPlots.csv
into R and do the following:
- Find the X and Y coordinate locations. Which value is X and which value is Y?
- These data were collected in a geographic coordinate system (WGS84). Convert the dataframe into an
sf
object.- Plot the new points with the plot location points from above. Be sure to add a legend. Use a different symbol for the 2 new points!
If you have extra time, feel free to add roads and other layers to your map!
Answers
1) First we will read in the new csv file and look at the data structure.
newplot_locations_HARV <- read.csv("data/NEON-DS-Site-Layout-Files/HARV/HARV_2NewPhenPlots.csv") str(newplot_locations_HARV)
'data.frame': 2 obs. of 13 variables: $ decimalLat: num 42.5 42.5 $ decimalLon: num -72.2 -72.2 $ country : chr "unitedStates" "unitedStates" $ stateProvi: chr "MA" "MA" $ county : chr "Worcester" "Worcester" $ domainName: chr "Northeast" "Northeast" $ domainID : chr "D01" "D01" $ siteID : chr "HARV" "HARV" $ plotType : chr "tower" "tower" $ subtype : chr "phenology" "phenology" $ plotSize : int 40000 40000 $ plotDimens: chr "200m x 200m" "200m x 200m" $ elevation : num 358 346
2) The US boundary data we worked with previously is in a geographic WGS84 CRS. We can use that data to establish a CRS for this data. First we will extract the CRS from the
country_boundary_US
object and confirm that it is WGS84.geogCRS <- st_crs(country_boundary_US) geogCRS
Coordinate Reference System: User input: WGS 84 wkt: GEOGCRS["WGS 84", DATUM["World Geodetic System 1984", ELLIPSOID["WGS 84",6378137,298.257223563, LENGTHUNIT["metre",1]]], PRIMEM["Greenwich",0, ANGLEUNIT["degree",0.0174532925199433]], CS[ellipsoidal,2], AXIS["latitude",north, ORDER[1], ANGLEUNIT["degree",0.0174532925199433]], AXIS["longitude",east, ORDER[2], ANGLEUNIT["degree",0.0174532925199433]], ID["EPSG",4326]]
Then we will convert our new data to a spatial dataframe, using the
geogCRS
object as our CRS.newPlot.Sp.HARV <- st_as_sf(newplot_locations_HARV, coords = c("decimalLon", "decimalLat"), crs = geogCRS)
Next we’ll confirm that the CRS for our new object is correct.
st_crs(newPlot.Sp.HARV)
Coordinate Reference System: User input: WGS 84 wkt: GEOGCRS["WGS 84", DATUM["World Geodetic System 1984", ELLIPSOID["WGS 84",6378137,298.257223563, LENGTHUNIT["metre",1]]], PRIMEM["Greenwich",0, ANGLEUNIT["degree",0.0174532925199433]], CS[ellipsoidal,2], AXIS["latitude",north, ORDER[1], ANGLEUNIT["degree",0.0174532925199433]], AXIS["longitude",east, ORDER[2], ANGLEUNIT["degree",0.0174532925199433]], ID["EPSG",4326]]
We will be adding these new data points to the plot we created before. The data for the earlier plot was in UTM. Since we’re using
ggplot
, it will reproject the data for us.3) Now we can create our plot.
ggplot() + geom_sf(data = plot_locations_sp_HARV, color = "orange") + geom_sf(data = newPlot.Sp.HARV, color = "lightblue") + ggtitle("Map of All Plot Locations")
Export a Shapefile
We can write an R spatial object to a shapefile using the st_write
function
in sf
. To do this we need the following arguments:
- the name of the spatial object (
plot_locations_sp_HARV
) - the directory where we want to save our shapefile
(to use
current = getwd()
or you can specify a different path) - the name of the new shapefile (
PlotLocations_HARV
) - the driver which specifies the file format (ESRI Shapefile)
We can now export the spatial object as a shapefile.
st_write(plot_locations_sp_HARV,
"data/PlotLocations_HARV.shp", driver = "ESRI Shapefile")
Key Points
Know the projection (if any) of your point data prior to converting to a spatial object.
Convert a data frame to an
sf
object using thest_as_sf()
function.Export an
sf
object as text using thest_write()
function.