An illustrative example
To perform multidimensional queries, the multistar class was defined in the starschemar package. A multistar implements the star schemas: it has a table for each dimension and a table for the facts; however, it can contain multiple fact tables with some dimensions in common.
Using the functions defined in starschemar package, starting from a flat table implemented by means of a tibble, we can generate a multistar object.
If we already have a star schema, geomultistar package offers functions to generate a multistar object from the fact and dimension tables in tibble format.
Generate a multistar object
In this case, we are going to suppose that we have tables of facts and dimensions in tibble format, which we have imported into R. In particular, we have the tables mrs_fact_age, mrs_fact_cause, mrs_where, mrs_when and mrs_who, obtained from the example presented in package starschemar: Two fact tables that share two of the three dimensions.
Add fact tables
We create an empty object, to which we will add elements. First we have to add a fact table, later we will add dimension tables or other fact tables.
library(tidyr)
library(geomultistar)
ms <- multistar() %>%
add_facts(
fact_name = "mrs_age",
fact_table = mrs_fact_age,
measures = "n_deaths",
nrow_agg = "count"
) For the facts we indicate a name, the table that contains its data and the names of the columns that contain the measures.
You can indicate an aggregation function associated with each measure. This parameter should be defined only if some measure is not additive. In this case it is not necessary.
Finally, you can indicate the name of a field that represents the number of rows grouped in each query: You can indicate the name of an existing column in the table for that purpose, or the name that you want to give to the column to be added if none exists. In this case, the name of a column in the table is assigned.
Next we add another table of facts with characteristics similar to the previous one.
ms <- ms %>%
add_facts(
fact_name = "mrs_cause",
fact_table = mrs_fact_cause,
measures = c("pneumonia_and_influenza_deaths", "other_deaths"),
nrow_agg = "nrow_agg"
)In this case, the column that contains the number of grouped rows precisely has the name that is assigned by default.
Add dimension tables
Once we have at least one fact table, we can add dimension tables.
ms <- ms %>%
add_dimension(
dimension_name = "where",
dimension_table = mrs_where,
dimension_key = "where_pk",
fact_name = "mrs_age",
fact_key = "where_fk"
)For each dimension we define its name, the table that contains the data, the name of the primary key and, for the table of facts with which we are going to relate it, its name and the name of the corresponding foreign key.
To establish the relationship successfully, it is verified that there is referential integrity between the tables using the indicated columns. The columns corresponding to the primary and foreign keys are renamed and are no longer available for queries. If you want to keep the field in the dimension, it can be indicated by a parameter, as is shown below by parameter key_as_data.
ms <- ms %>%
add_dimension(
dimension_name = "when",
dimension_table = mrs_when,
dimension_key = "when_pk",
fact_name = "mrs_age",
fact_key = "when_fk",
key_as_data = TRUE
) %>%
add_dimension(
dimension_name = "who",
dimension_table = mrs_who,
dimension_key = "who_pk",
fact_name = "mrs_age",
fact_key = "who_fk"
)If a dimension is related to more than one fact table, when it is added, its relationship to only one can be defined. Later, additional relationships can be defined, as we will see next.
Relate dimensions
Once a dimension is included in the multistar, we can relate it to other fact tables.
ms <- ms %>%
relate_dimension(dimension_name = "where",
fact_name = "mrs_cause",
fact_key = "where_fk") %>%
relate_dimension(dimension_name = "when",
fact_name = "mrs_cause",
fact_key = "when_fk")In this case, to specify the dimension we only have to indicate its name.
Additional operations on the multistar object
Through the previous operations, we generate a multistar object to which we can apply the operations defined in the starschemar package for this class. At this moment we can export it as a flat table, using multistar_as_flat_table, or define multidimensional queries, as we will later use dimensional_query.
Define geographic dimensions and attributes
To define the dimensions and geographic attributes of a multistar object, we must define a geomultistar specialization from it, which allows to store this information.
We create a geomultistar object from a multistar one defining the names of the dimensions that contain geographic information. In the example only one dimension.
library(sf)
#> Linking to GEOS 3.8.0, GDAL 3.0.4, PROJ 6.3.1
gms <-
geomultistar(ms, geodimension = "where")For each attribute of a geographic dimension that we want to use in queries, we can define a vector layer with which a relationship can be established using one or more attributes of the dimension.
gms <- gms %>%
define_geoattribute(
attribute = "city",
from_layer = usa_cities,
by = c("city" = "city", "state" = "state")
) For the city attribute, a relationship is defined with a vector layer in sf format (usa_cities), using the city and state attributes2 that have the same name in the layer.
Sometimes there may be problems establishing the correspondence between the geographic attributes and the vector layer: Instances may remain unrelated. To detect these situations, we can query the rows that do not have associated geometry using the following function.
The result obtained is shown below.
| city | state | geometry |
|---|---|---|
| Unknown | Unknown | POINT EMPTY |
In this case, for the unknown cities, their location has not been determined. There may be several because other geographic data of less granularity may be known.
In the same way, the relationship for county with the corresponding layer (usa_counties) is defined.
gms <- gms %>%
define_geoattribute(
attribute = "county",
from_layer = usa_counties,
by = c("county" = "county", "state" = "state")
) We check if they have all been related.
And the result obtained is shown below.
| county | state | geometry |
|---|---|---|
| Unknown | Unknown | GEOMETRYCOLLECTION EMPTY |
It also happens for the same instances. In this case we can see that the associated geometry is of a different type.
In the case of state the definition is carried out by associating the code to the corresponding one in the layer (usa_states).
gms <- gms %>%
define_geoattribute(
attribute = c("state"),
from_layer = usa_states,
by = c("state" = "state")
) Additionally, for an attribute we can generate its layer from the one associated with another related attribute of the dimension. This is what has been done below for division.
In this case, the vector layer is generated from the data available in the layer under consideration. Sometimes this is precisely what is desired. If not, look for a vector layer at that level of detail.
If no attribute name is indicated, this operation is applied to the rest of the attributes of the dimension that do not have an associated vector layer by any of the methods presented, as shown below.
With this we have all the attributes of the dimension with an associated layer, defined at its level of granularity3. On the other hand, we can change the layer of any attribute at any time, independently of the rest.
Define multidimensional queries
Multidimensional queries are defined from a multistar object in the starschemar package. Since we are working with geomultistar, a specialization of multistar, we can use this object to define the query.
library(starschemar)
gdqr <- dimensional_query(gms) %>%
select_dimension(name = "where",
attributes = c("division_name", "region_name")) %>%
select_dimension(name = "when",
attributes = c("year", "week")) %>%
select_fact(name = "mrs_age",
measures = c("n_deaths")) %>%
select_fact(
name = "mrs_cause",
measures = c("pneumonia_and_influenza_deaths", "other_deaths")
) %>%
filter_dimension(name = "when", week <= "03")The definition functions of this type of queries are quite intuitive, they are explained in the vignette of package starschemar.
If we use the function run_query of the mentioned package, a normal multidimensional query is executed, as shown below.
The result of this type of query is a multistar object, which we can transform into a flat table to display it more easily, as we do below for the first rows..
| year | week | division_name | region_name | n_deaths | count | pneumonia_and_influenza_deaths | other_deaths | mrs_cause_nrow_agg |
|---|---|---|---|---|---|---|---|---|
| 1962 | 01 | East North Central | Midwest | 2258 | 75 | 113 | 2145 | 16 |
| 1962 | 01 | East South Central | South | 526 | 35 | 31 | 495 | 7 |
| 1962 | 01 | Middle Atlantic | Northeast | 3452 | 86 | 173 | 3279 | 20 |
| 1962 | 01 | Mountain | West | 414 | 35 | 34 | 380 | 8 |
| 1962 | 01 | New England | Northeast | 785 | 57 | 56 | 729 | 14 |
| 1962 | 01 | Pacific | West | 1567 | 67 | 56 | 1511 | 14 |
| 1962 | 01 | South Atlantic | South | 1271 | 59 | 58 | 1213 | 12 |
| 1962 | 01 | West North Central | Midwest | 936 | 46 | 47 | 889 | 10 |
| 1962 | 01 | West South Central | South | 1243 | 65 | 66 | 1177 | 13 |
| 1962 | 02 | East North Central | Midwest | 2289 | 76 | 115 | 2174 | 16 |
| 1962 | 02 | East South Central | South | 575 | 33 | 36 | 539 | 7 |
| 1962 | 02 | Middle Atlantic | Northeast | 3426 | 90 | 157 | 3269 | 20 |
Run queries adding geographic information
If instead of executing the standard query, we execute run_geoquery function, from this package, we automatically obtain a vector layer at the finest possible level of detail, depending on the definition of the query.
The first rows of the result can be seen below in table form.
| year | week | division_name | region_name | n_deaths | count | pneumonia_and_influenza_deaths | other_deaths | mrs_cause_nrow_agg | geometry |
|---|---|---|---|---|---|---|---|---|---|
| 1962 | 01 | East North Central | Midwest | 2258 | 75 | 113 | 2145 | 16 | MULTIPOLYGON (((-91.51 40.2… |
| 1962 | 01 | East South Central | South | 526 | 35 | 31 | 495 | 7 | MULTIPOLYGON (((-88.47 31.8… |
| 1962 | 01 | Middle Atlantic | Northeast | 3452 | 86 | 173 | 3279 | 20 | MULTIPOLYGON (((-75.56 39.6… |
| 1962 | 01 | Mountain | West | 414 | 35 | 34 | 380 | 8 | POLYGON ((-109.1 31.33, -11… |
| 1962 | 01 | New England | Northeast | 785 | 57 | 56 | 729 | 14 | MULTIPOLYGON (((-71.63 41.1… |
| 1962 | 01 | Pacific | West | 1567 | 67 | 56 | 1511 | 14 | MULTIPOLYGON (((-156 19.78,… |
| 1962 | 01 | South Atlantic | South | 1271 | 59 | 58 | 1213 | 12 | MULTIPOLYGON (((-81.81 24.5… |
| 1962 | 01 | West North Central | Midwest | 936 | 46 | 47 | 889 | 10 | POLYGON ((-91.42 40.38, -91… |
| 1962 | 01 | West South Central | South | 1243 | 65 | 66 | 1177 | 13 | POLYGON ((-91.17 33, -91.07… |
| 1962 | 02 | East North Central | Midwest | 2289 | 76 | 115 | 2174 | 16 | MULTIPOLYGON (((-91.51 40.2… |
| 1962 | 02 | East South Central | South | 575 | 33 | 36 | 539 | 7 | MULTIPOLYGON (((-88.47 31.8… |
| 1962 | 02 | Middle Atlantic | Northeast | 3426 | 90 | 157 | 3269 | 20 | MULTIPOLYGON (((-75.56 39.6… |
The result is a vector layer that we can save, perform spatial analysis or queries on it, or we can see it as a map, using the functions associated with the sf class.
Although we have indicated in the query the attributes division_name and region_name, as can be seen in the figure, the result obtained is at the finest granularity level, in this case at the division_name level.
Only the parts of the divisions made up of states where there is recorded data are shown. If we wanted to show the full extent of each division, we should have explicitly associated a layer at that level.
Get wide tables
In geographic layers, geographic objects usually are not repeated. The tables are wide: for each object the rest of the attributes are defined as columns. By means of the parameter wider we can indicate that we want a result of this type.
The first rows of the result can be seen below in table form.
| fid | year | division_name | region_name | n_deaths_01 | n_deaths_02 | n_deaths_03 | count_01 | count_02 | count_03 | pneumonia_and_influenza_deaths_01 | pneumonia_and_influenza_deaths_02 | pneumonia_and_influenza_deaths_03 | other_deaths_01 | other_deaths_02 | other_deaths_03 | mrs_cause_nrow_agg_01 | mrs_cause_nrow_agg_02 | mrs_cause_nrow_agg_03 | geometry |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | 1962 | East North Central | Midwest | 2258 | 2289 | 2314 | 75 | 76 | 75 | 113 | 115 | 125 | 2145 | 2174 | 2189 | 16 | 16 | 16 | MULTIPOLYGON (((-91.51 40.2… |
| 2 | 1962 | East South Central | South | 526 | 575 | 650 | 35 | 33 | 32 | 31 | 36 | 44 | 495 | 539 | 606 | 7 | 7 | 7 | MULTIPOLYGON (((-88.47 31.8… |
| 3 | 1962 | Middle Atlantic | Northeast | 3452 | 3426 | 3413 | 86 | 90 | 91 | 173 | 157 | 160 | 3279 | 3269 | 3253 | 20 | 20 | 20 | MULTIPOLYGON (((-75.56 39.6… |
| 4 | 1962 | Mountain | West | 414 | 411 | 472 | 35 | 34 | 35 | 34 | 21 | 29 | 380 | 390 | 443 | 8 | 8 | 8 | POLYGON ((-109.1 31.33, -11… |
| 5 | 1962 | New England | Northeast | 785 | 785 | 726 | 57 | 61 | 57 | 56 | 52 | 48 | 729 | 733 | 678 | 14 | 14 | 14 | MULTIPOLYGON (((-71.63 41.1… |
| 6 | 1962 | Pacific | West | 1567 | 1823 | 1637 | 67 | 67 | 66 | 56 | 70 | 76 | 1511 | 1753 | 1561 | 14 | 14 | 14 | MULTIPOLYGON (((-156 19.78,… |
| 7 | 1962 | South Atlantic | South | 1271 | 1179 | 1319 | 59 | 58 | 57 | 58 | 54 | 62 | 1213 | 1125 | 1257 | 12 | 12 | 12 | MULTIPOLYGON (((-81.81 24.5… |
| 8 | 1962 | West North Central | Midwest | 936 | 1040 | 936 | 46 | 47 | 47 | 47 | 74 | 55 | 889 | 966 | 881 | 10 | 10 | 10 | POLYGON ((-91.42 40.38, -91… |
| 9 | 1962 | West South Central | South | 1243 | 1096 | 1297 | 65 | 63 | 59 | 66 | 67 | 85 | 1177 | 1029 | 1212 | 13 | 13 | 13 | POLYGON ((-91.17 33, -91.07… |
We can see that the attributes that are multivalued for each geographic object have been eliminated from the result table, and new measurement columns have been generated: one for each combination of values of these attributes with the original measurements.
The meaning of the name of the columns of the measurements is part of the result obtained, also in table format, as can be seen below.
| id_variable | measure | week |
|---|---|---|
| n_deaths_01 | n_deaths | 01 |
| n_deaths_02 | n_deaths | 02 |
| n_deaths_03 | n_deaths | 03 |
| count_01 | count | 01 |
| count_02 | count | 02 |
| count_03 | count | 03 |
| pneumonia_and_influenza_deaths_01 | pneumonia_and_influenza_deaths | 01 |
| pneumonia_and_influenza_deaths_02 | pneumonia_and_influenza_deaths | 02 |
| pneumonia_and_influenza_deaths_03 | pneumonia_and_influenza_deaths | 03 |
| other_deaths_01 | other_deaths | 01 |
| other_deaths_02 | other_deaths | 02 |
| other_deaths_03 | other_deaths | 03 |
In this case there was only one variable with a multiplicity greater than one. If there were more variables in this situation, they would be added to this table in the same way.
This dictionary table and layer structure can be saved in GeoPackage format using the save_as_geopackage function.
The GeoPackages thus obtained can be used directly, for example in QGIS.