README.md
In ttrodrigz/iterake: Tools for iterative raking
iterake 
Overview
iterake’s main utility is creating row weights using a process called
iterative raking. Iterative raking (also known as rim weighting), is one
of several methods used to correct the deviation between the marginal
proportions in a sample and a known population, or, universe as it was
first referred to (Deming & Stephan 1940) for a given set of variables.
iterake is designed with speed and simplicity in mind. The weighting
algorithm is powered by
data.table and takes
advantage of its fast
grouping
and joining.
Workflow
The weighting process with iterake is fairly straightforward, we
suggest:
- Use the
universe() function to build your population.
- The univerise is constructed with one or more categories where
the marginal probabilites are known. These categories are built
with the
category() function.
- If you want to use the natural marginal proportions from an
existing dataset as your targets, you can use
inherit_category(). Just make sure the name given to the
category matches the existing data and the data you intend to
weight.
- Compare the marginal proportions in your sample with the population
with
compare_margins() function.
- If needed, create weights for your data using
iterake().
- Use
compare_margins() again to verify that the weighted
proportions in your sample now match the population.
- Check the performance of the weighting model with
weight_stats().
Installation
# Install the development version from GitHub
install.packages("remotes")
remotes::install_github("ttrodrigz/iterake")
Motivating Example
Say you have conducted a study by randomly sampling 400 individuals from
a population. You were dilligent in monitoring the responses to make
sure the makeup of the sample adequately reflected the population. But,
due to chance, slightly too many males and individuals under 50 years of
age entered the sample.
You know from experts in your field that 60% of the population from
which you sampled are female, and 20% of the population are less than 50
years old. Let’s build a data set to use as an example:
library(tibble)
N <- 400
set.seed(101)
df <- tibble(
id = 1:N,
Sex = sample(
x = c("Male", "Female"),
size = N,
replace = TRUE,
prob = c(0.42, 0.58)
),
Under50 = sample(
x = c(T, F),
size = N,
replace = TRUE,
prob = c(0.22, 0.78)
)
)
df
#> # A tibble: 400 x 3
#> id Sex Under50
#> <int> <chr> <lgl>
#> 1 1 Female FALSE
#> 2 2 Female TRUE
#> 3 3 Male FALSE
#> 4 4 Male TRUE
#> 5 5 Female FALSE
#> 6 6 Female TRUE
#> 7 7 Male FALSE
#> 8 8 Female TRUE
#> 9 9 Male TRUE
#> 10 10 Female FALSE
#> # ... with 390 more rows
Step 1: Build the universe
Simply supply the data you intend on weighting, and build weighting
categories by using the category() function.
library(iterake)
uni <- universe(
data = df,
category(
name = "Sex",
buckets = c("Male", "Female"),
targets = c(0.4, 0.6)
),
category(
name = "Under50",
buckets = c(TRUE, FALSE),
targets = c(0.2, 0.8)
)
)
Step 2: Compare marginal proportions prior to weighting
This is the time to inspect the differences in proportions between the
sample and the population. A large discrepancy will require extreme
weights, and in some cases the algorithm may not even converge. Before
you decide to weight, keep in mind that weighting the data decreases
accuracy. In some cases it is best to deal with the fact your sample
doesn’t perfectly match the population.
compare_margins(universe = uni)
#> # A tibble: 4 x 6
#> category bucket uwgt_n uwgt_prop targ_prop uwgt_diff
#> <chr> <chr> <int> <dbl> <dbl> <dbl>
#> 1 Sex Male 174 0.435 0.4 0.0350
#> 2 Sex Female 226 0.565 0.6 -0.035
#> 3 Under50 TRUE 86 0.215 0.2 0.0150
#> 4 Under50 FALSE 314 0.785 0.8 -0.015
Step 3: Weight the data
If weighting is necessary, pass the universe object to iterake().
df_wgt <- iterake(universe = uni)
#>
#> -- iterake summary -------------------------------------------------------------
#> Convergence: Success
#> Iterations: 4
#>
#> Unweighted N: 400.00
#> Effective N: 397.57
#> Weighted N: 400.00
#> Efficiency: 99.4%
#> Loss: 0.006
df_wgt
#> # A tibble: 400 x 4
#> id Sex Under50 weight
#> <int> <chr> <lgl> <dbl>
#> 1 1 Female FALSE 1.08
#> 2 2 Female TRUE 0.992
#> 3 3 Male FALSE 0.937
#> 4 4 Male TRUE 0.862
#> 5 5 Female FALSE 1.08
#> 6 6 Female TRUE 0.992
#> 7 7 Male FALSE 0.937
#> 8 8 Female TRUE 0.992
#> 9 9 Male TRUE 0.862
#> 10 10 Female FALSE 1.08
#> # ... with 390 more rows
Step 4: Compare marginal proportions after weighting
compare_margins(
universe = uni,
data = df_wgt,
weight = weight,
plot = TRUE
)
#> # A tibble: 4 x 9
#> category bucket uwgt_n wgt_n uwgt_prop wgt_prop targ_prop uwgt_diff
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 Sex Male 174 160. 0.435 0.400 0.4 0.0350
#> 2 Sex Female 226 240. 0.565 0.6 0.6 -0.035
#> 3 Under50 TRUE 86 80 0.215 0.2 0.2 0.0150
#> 4 Under50 FALSE 314 320. 0.785 0.800 0.8 -0.015
#> # ... with 1 more variable: wgt_diff <dbl>
Step 5: Inspect weights
Again, weights much higher or lower than 1 are undesirable, check the
output with weight_stats() to inspect the quality of the weights.
Details about what each of the statistics mean can be found in the
documentation.
weight_stats(df_wgt[["weight"]])
#> # A tibble: 1 x 7
#> uwgt_n wgt_n eff_n loss efficiency min_wgt max_wgt
#> <int> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 400 400. 398. 0.00611 0.994 0.862 1.08
ttrodrigz/iterake documentation built on March 27, 2024, 12:48 a.m.
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
iterake
Overview
iterake’s main utility is creating row weights using a process called iterative raking. Iterative raking (also known as rim weighting), is one of several methods used to correct the deviation between the marginal proportions in a sample and a known population, or, universe as it was first referred to (Deming & Stephan 1940) for a given set of variables.
iterake is designed with speed and simplicity in mind. The weighting algorithm is powered by data.table and takes advantage of its fast grouping and joining.
Workflow
The weighting process with iterake is fairly straightforward, we
suggest:
- Use the
universe()function to build your population.- The univerise is constructed with one or more categories where
the marginal probabilites are known. These categories are built
with the
category()function. - If you want to use the natural marginal proportions from an
existing dataset as your targets, you can use
inherit_category(). Just make sure the name given to the category matches the existing data and the data you intend to weight.
- The univerise is constructed with one or more categories where
the marginal probabilites are known. These categories are built
with the
- Compare the marginal proportions in your sample with the population
with
compare_margins()function. - If needed, create weights for your data using
iterake(). - Use
compare_margins()again to verify that the weighted proportions in your sample now match the population. - Check the performance of the weighting model with
weight_stats().
Installation
# Install the development version from GitHub
install.packages("remotes")
remotes::install_github("ttrodrigz/iterake")
Motivating Example
Say you have conducted a study by randomly sampling 400 individuals from a population. You were dilligent in monitoring the responses to make sure the makeup of the sample adequately reflected the population. But, due to chance, slightly too many males and individuals under 50 years of age entered the sample.
You know from experts in your field that 60% of the population from which you sampled are female, and 20% of the population are less than 50 years old. Let’s build a data set to use as an example:
library(tibble)
N <- 400
set.seed(101)
df <- tibble(
id = 1:N,
Sex = sample(
x = c("Male", "Female"),
size = N,
replace = TRUE,
prob = c(0.42, 0.58)
),
Under50 = sample(
x = c(T, F),
size = N,
replace = TRUE,
prob = c(0.22, 0.78)
)
)
df
#> # A tibble: 400 x 3
#> id Sex Under50
#> <int> <chr> <lgl>
#> 1 1 Female FALSE
#> 2 2 Female TRUE
#> 3 3 Male FALSE
#> 4 4 Male TRUE
#> 5 5 Female FALSE
#> 6 6 Female TRUE
#> 7 7 Male FALSE
#> 8 8 Female TRUE
#> 9 9 Male TRUE
#> 10 10 Female FALSE
#> # ... with 390 more rows
Step 1: Build the universe
Simply supply the data you intend on weighting, and build weighting
categories by using the category() function.
library(iterake)
uni <- universe(
data = df,
category(
name = "Sex",
buckets = c("Male", "Female"),
targets = c(0.4, 0.6)
),
category(
name = "Under50",
buckets = c(TRUE, FALSE),
targets = c(0.2, 0.8)
)
)
Step 2: Compare marginal proportions prior to weighting
This is the time to inspect the differences in proportions between the sample and the population. A large discrepancy will require extreme weights, and in some cases the algorithm may not even converge. Before you decide to weight, keep in mind that weighting the data decreases accuracy. In some cases it is best to deal with the fact your sample doesn’t perfectly match the population.
compare_margins(universe = uni)
#> # A tibble: 4 x 6
#> category bucket uwgt_n uwgt_prop targ_prop uwgt_diff
#> <chr> <chr> <int> <dbl> <dbl> <dbl>
#> 1 Sex Male 174 0.435 0.4 0.0350
#> 2 Sex Female 226 0.565 0.6 -0.035
#> 3 Under50 TRUE 86 0.215 0.2 0.0150
#> 4 Under50 FALSE 314 0.785 0.8 -0.015
Step 3: Weight the data
If weighting is necessary, pass the universe object to iterake().
df_wgt <- iterake(universe = uni)
#>
#> -- iterake summary -------------------------------------------------------------
#> Convergence: Success
#> Iterations: 4
#>
#> Unweighted N: 400.00
#> Effective N: 397.57
#> Weighted N: 400.00
#> Efficiency: 99.4%
#> Loss: 0.006
df_wgt
#> # A tibble: 400 x 4
#> id Sex Under50 weight
#> <int> <chr> <lgl> <dbl>
#> 1 1 Female FALSE 1.08
#> 2 2 Female TRUE 0.992
#> 3 3 Male FALSE 0.937
#> 4 4 Male TRUE 0.862
#> 5 5 Female FALSE 1.08
#> 6 6 Female TRUE 0.992
#> 7 7 Male FALSE 0.937
#> 8 8 Female TRUE 0.992
#> 9 9 Male TRUE 0.862
#> 10 10 Female FALSE 1.08
#> # ... with 390 more rows
Step 4: Compare marginal proportions after weighting
compare_margins(
universe = uni,
data = df_wgt,
weight = weight,
plot = TRUE
)
#> # A tibble: 4 x 9
#> category bucket uwgt_n wgt_n uwgt_prop wgt_prop targ_prop uwgt_diff
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 Sex Male 174 160. 0.435 0.400 0.4 0.0350
#> 2 Sex Female 226 240. 0.565 0.6 0.6 -0.035
#> 3 Under50 TRUE 86 80 0.215 0.2 0.2 0.0150
#> 4 Under50 FALSE 314 320. 0.785 0.800 0.8 -0.015
#> # ... with 1 more variable: wgt_diff <dbl>
Step 5: Inspect weights
Again, weights much higher or lower than 1 are undesirable, check the
output with weight_stats() to inspect the quality of the weights.
Details about what each of the statistics mean can be found in the
documentation.
weight_stats(df_wgt[["weight"]])
#> # A tibble: 1 x 7
#> uwgt_n wgt_n eff_n loss efficiency min_wgt max_wgt
#> <int> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 400 400. 398. 0.00611 0.994 0.862 1.08
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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