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Combination features are those which have
transformation_type
equal to combine_linear
,
combine_min
, and combine_max
. These features
use the values of two or more subfeatures to create a new feature.
Because the form of the JSON required for combination features differs
from those of all other features, they are given special attention in
this vignette.
Of all the top-level JSON keys specified in the feature overview, only
output_feature_name
and transformation_type
are still required for combination features. As before,
output_feature_name
is the name of the feature that will be
created. The value of transformation_type
can be:
combine_linear
: calculate a linear combination of the
featurescombine_min
: calculate the minimum of the featurescombine_max
: calculate the maximum of the featuresOn top of these, combination features require a
subfeature
key, which is itself a JSON object. Its keys can
be any string (though it helps to be descriptive), and its values are
the JSON objects which define those subfeatures, sans
output_feature_name
(because those are not required). Note
that each subfeature may have a different source_table
key,
which allows the subfeatures to come from different input tables.
For linear combinations, each subfeature must further contain a
weight
key, which is a number that determines the
coefficients of each feature in the linear combination.
As before, let’s make up some data to illustrate this.
input_table <- data.frame(
id = c(1, 1, 1, 1, 2, 2, 2, 2),
diagnosis = c("A", "A", "A", "A", "A", "A", "B", "B")
)
input_table
#> id diagnosis
#> 1 1 A
#> 2 1 A
#> 3 1 A
#> 4 1 A
#> 5 2 A
#> 6 2 A
#> 7 2 B
#> 8 2 B
Suppose we want to find the number of times a patient has been diagnosed with “A” or the number of times they have been diagnosed with “B”, whichever is greater.
The number of “A” diagnoses would ordinarily be specified using the following JSON:
{
"output_feature_name": "num_A",
"source_table": "input_table",
"transformation_type": "count",
"absent_default_value": 0,
"grouping_column": "id",
"filter": {
"column": "diagnosis",
"type": "in",
"value": ["A"]
}
}
and the number of “B” diagnoses would be exactly identical to this, except with “A” replaced with “B”.
The combination feature we seek can thus be specified as in json_examples/combination1.json
.
Each subfeature is exactly the same as above, except that the
output_feature_name
key is omitted:
{
"output_feature_name": "max_of_A_and_B",
"transformation_type": "combine_max",
"subfeature": {
"num_A": {
"source_table": "input_table",
"grouping_column": "id",
"transformation_type": "count",
"absent_default_value": 0,
"filter": {
"column": "diagnosis",
"type": "in",
"value": [
"A"
]
}
},
"num_B": {
"source_table": "input_table",
"grouping_column": "id",
"transformation_type": "count",
"absent_default_value": 0,
"filter": {
"column": "diagnosis",
"type": "in",
"value": [
"B"
]
}
}
}
}
Running this gives us the expected values of 4 and 2 for the two patients respectively:
Linear combinations allow you to calculate, for example, a weighted sum of two features. Suppose we want to assign a score of 10 for every “A” diagnosis and 20 for every “B” diagnosis. We can use the same JSON as above, but with two minor modifications:
transformation_type
key set to
combine_linear
weight
key is added to each subfeature, with an
appropriate valueThe result is json_examples/combination2.json
:
{
"output_feature_name": "linear",
"transformation_type": "combine_linear",
"subfeature": {
"A_score": {
"weight": 10,
"source_table": "input_table",
"grouping_column": "id",
"transformation_type": "count",
"absent_default_value": 0,
"filter": {
"column": "diagnosis",
"type": "in",
"value": [
"A"
]
}
},
"B_score": {
"weight": 20,
"source_table": "input_table",
"grouping_column": "id",
"transformation_type": "count",
"absent_default_value": 0,
"filter": {
"column": "diagnosis",
"type": "in",
"value": [
"B"
]
}
}
}
}
and running it:
results <- run_pipeline(
data_sources = list(input_table = input_table),
feature_filenames = "json_examples/combination2.json"
)
results$features
#> id linear
#> 1 1 40
#> 2 2 60
Note that for a simple unweighted sum of features, all weights can be set to 1; and to take the difference between two features, one weight can be set to 1 and the other to -1.
Feature 3 in the LTC example vignette is an example of a combination feature, in this case, a sum of three subfeatures.
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They may not be fully stable and should be used with caution. We make no claims about them.