Preparing Data for Interpolation

Christopher Prener, Ph.D.

2022-05-30

Depending on the state of your spatial data, they may require some cleaning and modification before interpolation. The types of issues to address pre-interpolation fall into a few distinct categories:

  1. Data are not in the right format
  2. Data are not in the right coordinate system
  3. Data have variable name conflicts
  4. Data have too many variables or observations and therefore must be subset

Each of these conditions will be discussed below. The following examples assume:

library(areal)
library(dplyr)   # data wrangling
library(sf)      # spatial data operations

# load data into enviornment
race <- ar_stl_race
asthma <- ar_stl_asthma
wards <- ar_stl_wards

# create example data - non-spatial data
asthmaTbl <- ar_stl_asthma
st_geometry(asthmaTbl) <- NULL

# create example data - wrong crs
race83 <- st_transform(race, crs = 4269)

Validating Data

areal has a built-in tool for data validation, ar_validate(), that provides an excellent starting place for ensuring your data are ready to interpolate. The validation process covers the first three issues listed in the introduction. It can be run in a simple format:

ar_validate(source = asthma, target = wards, varList = "ASTHMA", method = "aw")
#> [1] TRUE

If ar_validate() returns a FALSE value, it can also be run in a verbose manner that returns a detailed tibble:

ar_validate(source = asthma, target = wards, varList = "ASTHMA", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       TRUE  
#> 3 CRS is Planar                   TRUE  
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       TRUE  
#> 6 No Variable Conflicts in Target TRUE  
#> 7 Overall Evaluation              TRUE

Use the verbose = TRUE output as a checklist to address issues before interpolating your data.

Format Issues

Data need to be loaded as sf objects in R. If ar_validate() returns FALSE for the first condition, data are not stored as sf objects:

ar_validate(source = asthmaTbl, target = wards, varList = "ASTHMA", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      FALSE 
#> 2 CRS Match                       NA    
#> 3 CRS is Planar                   NA    
#> 4 Polygon Geometries              NA    
#> 5 Variables Exist in Source       NA    
#> 6 No Variable Conflicts in Target NA    
#> 7 Overall Evaluation              FALSE

External Spatial Data

If you have external data, using st_read() is the best way to load them:

df <- sf::st_read("data.shp", stringsAsFactors = FALSE)

The st_read() function supports a variety of the most common data sources.

sp Data

If you are working with data that is an sp object in R, the sf package has a function st_as_sf() can be used to convert the object to sf:

sf_object <- sf::st_as_sf(sp_object)

Data From tidycensus and tigris

If you are using either the tidycensus or tigris packages to access spatial data, there are options for downloading data as sf objects as well. In tidycensus, the geometry = TRUE option should be used. In tigris, the class = "sf" option should be used.

stl_race <- tidycensus::get_acs(geography = "tract", state = 29, county = 510, year = 2017, 
                                table = "B02001", output = "wide", geometry = TRUE)
stl_tracts <- tigris::tracts(state = 29, county = 510, class = "sf")

Tabular Data

If you have tabular data, you will need to merge them with a shapefile or other spatial data set that contains the geometry for the corresponding spatial features. For American users, a potentially common scenario here will be table of census geography (such as tracts) that lacks the geometry for those features. These can be downloaded using tigris and then combined using dplyr. The following example assumes the tract data contains an identification number column named GEOID with the appropriate tract identifiers for St. Louis:

stl_tracts <- tigris::tracts(state = 29, county = 510, class = "sf")

tract_data <- dplyr::left_join(stl_tracts, asthmaTBL, by = "GEOID")

Coordinate Systems

Two coordinate system rules are enforced by ar_validate: both the source and the target data must be in the same coordinate system and that coordinate system must be a projected coordinate system. The sf package contains a function named st_crs() for previewing the current coordinate system of your data:

st_crs(race83)
#> Coordinate Reference System:
#>   User input: EPSG:4269 
#>   wkt:
#> GEOGCRS["NAD83",
#>     DATUM["North American Datum 1983",
#>         ELLIPSOID["GRS 1980",6378137,298.257222101,
#>             LENGTHUNIT["metre",1]]],
#>     PRIMEM["Greenwich",0,
#>         ANGLEUNIT["degree",0.0174532925199433]],
#>     CS[ellipsoidal,2],
#>         AXIS["geodetic latitude (Lat)",north,
#>             ORDER[1],
#>             ANGLEUNIT["degree",0.0174532925199433]],
#>         AXIS["geodetic longitude (Lon)",east,
#>             ORDER[2],
#>             ANGLEUNIT["degree",0.0174532925199433]],
#>     USAGE[
#>         SCOPE["Geodesy."],
#>         AREA["North America - onshore and offshore: Canada - Alberta; British Columbia; Manitoba; New Brunswick; Newfoundland and Labrador; Northwest Territories; Nova Scotia; Nunavut; Ontario; Prince Edward Island; Quebec; Saskatchewan; Yukon. Puerto Rico. United States (USA) - Alabama; Alaska; Arizona; Arkansas; California; Colorado; Connecticut; Delaware; Florida; Georgia; Hawaii; Idaho; Illinois; Indiana; Iowa; Kansas; Kentucky; Louisiana; Maine; Maryland; Massachusetts; Michigan; Minnesota; Mississippi; Missouri; Montana; Nebraska; Nevada; New Hampshire; New Jersey; New Mexico; New York; North Carolina; North Dakota; Ohio; Oklahoma; Oregon; Pennsylvania; Rhode Island; South Carolina; South Dakota; Tennessee; Texas; Utah; Vermont; Virginia; Washington; West Virginia; Wisconsin; Wyoming. US Virgin Islands.  British Virgin Islands."],
#>         BBOX[14.92,167.65,86.46,-47.74]],
#>     ID["EPSG",4269]]

The EPSG value 4269 refers to a specific type of coordinate system known as as geographic coordinate system. These data use latitude-longitude values, which vary in length and thus cannot be used to calculate area (a key component of carrying out areal interpolations). These data would fail the ar_validate() process:

ar_validate(source = race83, target = wards, varList = "TOTAL_E", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       FALSE 
#> 3 CRS is Planar                   FALSE 
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       TRUE  
#> 6 No Variable Conflicts in Target TRUE  
#> 7 Overall Evaluation              FALSE

These data fail both the matching CRS validation and the planar CRS validation because the race and wards data are in two different coordinate systems. We’ve already seen the CRS data for race above so we’ll look at the CRS data forwards`:

st_crs(wards)
#> Coordinate Reference System:
#>   User input: ESRI:102296 
#>   wkt:
#> PROJCRS["NAD_1983_HARN_StatePlane_Missouri_East_FIPS_2401",
#>     BASEGEOGCRS["NAD83(HARN)",
#>         DATUM["NAD83 (High Accuracy Reference Network)",
#>             ELLIPSOID["GRS 1980",6378137,298.257222101,
#>                 LENGTHUNIT["metre",1]]],
#>         PRIMEM["Greenwich",0,
#>             ANGLEUNIT["degree",0.0174532925199433]],
#>         ID["EPSG",4152]],
#>     CONVERSION["NAD_1983_HARN_StatePlane_Missouri_East_FIPS_2401",
#>         METHOD["Transverse Mercator",
#>             ID["EPSG",9807]],
#>         PARAMETER["Latitude of natural origin",35.8333333333333,
#>             ANGLEUNIT["degree",0.0174532925199433],
#>             ID["EPSG",8801]],
#>         PARAMETER["Longitude of natural origin",-90.5,
#>             ANGLEUNIT["degree",0.0174532925199433],
#>             ID["EPSG",8802]],
#>         PARAMETER["Scale factor at natural origin",0.999933333333333,
#>             SCALEUNIT["unity",1],
#>             ID["EPSG",8805]],
#>         PARAMETER["False easting",250000,
#>             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]],
#>     USAGE[
#>         SCOPE["Not known."],
#>         AREA["United States (USA) - Missouri - counties of Bollinger; Butler; Cape Girardeau; Carter; Clark; Crawford; Dent; Dunklin; Franklin; Gasconade; Iron; Jefferson; Lewis; Lincoln; Madison; Marion; Mississippi; Montgomery; New Madrid; Oregon; Pemiscot; Perry; Pike; Ralls; Reynolds; Ripley; Scott; Shannon; St Charles; St Francois; St Louis; Ste. Genevieve; Stoddard; Warren; Washington; Wayne."],
#>         BBOX[35.98,-91.97,40.61,-89.1]],
#>     ID["ESRI",102296]]

If these data fail that process, st_crs() can be used to identify whether the source or the target (or both) are in an inappropriate coordinate system. The EPSG value 26915 refers to another type of coordinate system known as as projected coordinate system (or “planar” data). Further, 26915 is a particular type of projected coordinate system known as the Universal Transverse Mercator coordinate system. This is a good option for using areal because it is available around the world. There are a variety of tools for identifying the appropriate UTM zone, including this excellent interactive map. Once you have an EPSG zone, the website epsg.io can be used to search for the appropriate EPSG value.

In this case, the wards data are in an appropriate system but the race data need to be transformed. The st_transform() function can be used to modify them to an appropriate coordinate system:

raceFixed <- st_transform(race83, crs = 26915)

Once this is done, these data should pass the ar_validate() process:

ar_validate(source = raceFixed, target = wards, varList = "TOTAL_E", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       FALSE 
#> 3 CRS is Planar                   TRUE  
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       TRUE  
#> 6 No Variable Conflicts in Target TRUE  
#> 7 Overall Evaluation              FALSE

Variable Conflicts

If a variable does not exist in the source data, the validation process will fail:

ar_validate(source = race, target = wards, varList = "TOTAL", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       TRUE  
#> 3 CRS is Planar                   TRUE  
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       FALSE 
#> 6 No Variable Conflicts in Target TRUE  
#> 7 Overall Evaluation              FALSE

In this case, the fix is as easy as correcting the typo in our ar_validate() call - the variable TOTAL should really be TOTAL_E:

names(race)
#>  [1] "GEOID"     "STATEFP"   "COUNTYFP"  "TRACTCE"   "NAMELSAD"  "ALAND"    
#>  [7] "AWATER"    "TOTAL_E"   "TOTAL_M"   "WHITE_E"   "WHITE_M"   "BLACK_E"  
#> [13] "BLACK_M"   "AIAN_E"    "AIAN_M"    "ASIAN_E"   "ASIAN_M"   "NHPI_E"   
#> [19] "NHPI_M"    "OTHER_E"   "OTHER_M"   "TWOPLUS_E" "TWOPLUS_M" "geometry"

Another common problem is that a variable exists in both our source and target data. For instance, we could add a TOTAL_E variable to our target data:

wardsVar <- mutate(wards, TOTAL_E = seq(1:28))

ar_validate(source = race, target = wardsVar, varList = "TOTAL_E", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       TRUE  
#> 3 CRS is Planar                   TRUE  
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       TRUE  
#> 6 No Variable Conflicts in Target FALSE 
#> 7 Overall Evaluation              FALSE

Now, we fail the validation process because there is a conflict between the source and target data - TOTAL_E exists in both data sets. We can use the select() function from dplyr to remove the offending variable from the target data before proceeding:

wardsFixed <- select(wardsVar, -TOTAL_E)

ar_validate(source = race, target = wardsFixed, varList = "TOTAL_E", method = "aw", verbose = TRUE)
#> # A tibble: 7 × 2
#>   test                            result
#>   <chr>                           <lgl> 
#> 1 sf Objects                      TRUE  
#> 2 CRS Match                       TRUE  
#> 3 CRS is Planar                   TRUE  
#> 4 Polygon Geometries              TRUE  
#> 5 Variables Exist in Source       TRUE  
#> 6 No Variable Conflicts in Target TRUE  
#> 7 Overall Evaluation              TRUE

Another option would be to rename the column using the rename() function from dplyr or by using another approach for renaming columns. Either option will work for areal’s purposes.

Subsetting

One cautionary note when using areal is that the validation process will not check to see if too many variables or observations exist in the data. Cleaning the data ahead of time so that only the relevant observations exist can help improve performance - if you have tract data for an entire state but only need a particular city, everything will go faster if you subset these data using the filter() function from dplyr:

countyData <- filter(stateData, COUNTY == 510)

Having too many columns poses an organizational problem more than anything else. We strongly encourage users to limit their interpolated data to only the needed values. For example, the wards data contains an AREA column whose units we don’t know and an OBJECTID column that is an artifact from its creation using an ESRI product:

names(wards)
#> [1] "OBJECTID" "WARD"     "AREA"     "geometry"

We can use the select() function from dplyr to remove these before interpolation since we don’t need them:

wardsSubset <- select(wards, -OBJECTID, -AREA)