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Folktables is a Python package that provides access to datasets derived from the US Census, facilitating the benchmarking of machine learning algorithms. The package includes a suite of pre-defined prediction tasks in domains including income, employment, health, transportation, and housing, and also includes tools for creating new prediction tasks of interest in the US Census data ecosystem. The package additionally enables systematic studies of the effect of distribution shift, as each prediction task can be instantiated on datasets spanning multiple years and all states within the US.

Why the name? Folktables is a neologism describing tabular data about individuals. It emphasizes that data has the power to create and shape narratives about populations and challenges us to think carefully about the data we collect and use.

For more information about these datasets, including the motivations behind their curation and some examples of empirical findings, please see our paper and/or this video presentation.

Table of Contents

  1. Basic installation instructions
  2. Quick start examples
  3. Prediction tasks in folktables
  4. Scope and limitations
  5. Citing folktables
  6. References

Folktables is still under active development! If you find bugs or have feature requests, please file a Github issue. We welcome all kinds of issues, especially those related to correctness, documentation, performance, and new features.

Motivated by Datasheets for datasets (Gebru et al.), please see [Datasheet] for the Folktables datasheet.

Basic installation instructions

  1. (Optionally) create a virtual environment
python3 -m venv folkenv
source folkenv/bin/activate
  1. Install via pip
pip install folktables

You can also install folktables directly from source.

git clone https://github.com/zykls/folktables.git
cd folktables
pip install -r requirements.txt

Quick start examples

Folktables contains a suite of prediction tasks derived from US Census data that can be easily downloaded and used for a variety of benchmarking tasks. For information about the features, response, or group membership coding for any of the datasets, please refer to the ACS PUMS documentation.

Evaluating algorithms for fair machine learning

We first construct a data source for the 2018 yearly American Community Survey, download the corresponding data for Alabama, and use this data to instantiate a prediction task of interest, for example, the ACSEmployment task.

from folktables import ACSDataSource, ACSEmployment

data_source = ACSDataSource(survey_year='2018', horizon='1-Year', survey='person')
acs_data = data_source.get_data(states=["AL"], download=True)
features, label, group = ACSEmployment.df_to_numpy(acs_data)

Next we train a simple model on this dataset and use the group labels to evaluate the model's violation of equality of opportunity, a common fairness metric.

import numpy as np
from sklearn.linear_model import LogisticRegression
from sklearn.model_selection import train_test_split
from sklearn.pipeline import make_pipeline
from sklearn.preprocessing import StandardScaler

X_train, X_test, y_train, y_test, group_train, group_test = train_test_split(
    features, label, group, test_size=0.2, random_state=0)

###### Your favorite learning algorithm here #####
model = make_pipeline(StandardScaler(), LogisticRegression())
model.fit(X_train, y_train)

yhat = model.predict(X_test)

white_tpr = np.mean(yhat[(y_test == 1) & (group_test == 1)])
black_tpr = np.mean(yhat[(y_test == 1) & (group_test == 2)])

# Equality of opportunity violation: 0.0871
white_tpr - black_tpr

The ACS data source contains data for all fifty states, each of which has a slightly different distribution of features and response. This increases the diversity of environments in which we can evaluate our methods. For instance, we can generate another ACSEmployment task using data from Texas and repeat the experiment

acs_tx = data_source.get_data(states=["TX"], download=True)
tx_features, tx_label, tx_group = ACSEmployment.df_to_numpy(acs_tx)

features, label, group = ACSEmployment.df_to_numpy(acs_tx)
X_train, X_test, y_train, y_test, group_train, group_test = train_test_split(
    tx_features, tx_label, tx_group, test_size=0.2, random_state=0)

model = make_pipeline(StandardScaler(), LogisticRegression())
model.fit(X_train, y_train)

yhat = model.predict(X_test)
white_tpr = np.mean(yhat[(y_test == 1) & (group_test == 1)])
black_tpr = np.mean(yhat[(y_test == 1) & (group_test == 2)])

# Equality of opportunity violation: 0.0397
white_tpr - black_tpr

Distribution shift across states

Each prediction problem in Folktables can be instantiated on data from every US state. This allows us to not just construct a diverse set of test environments, but also to use Folktables to study questions aroud distribution shift. For example, we can train a classifier using data from California and then evaluate it on data from Michigan.

from folktables import ACSDataSource, ACSIncome
from sklearn.linear_model import LogisticRegression

data_source = ACSDataSource(survey_year='2018', horizon='1-Year', survey='person')
ca_data = data_source.get_data(states=["CA"], download=True)
mi_data = data_source.get_data(states=["MI"], download=True)
ca_features, ca_labels, _ = ACSIncome.df_to_numpy(ca_data)
mi_features, mi_labels, _ = ACSIncome.df_to_numpy(mi_data)

# Plug-in your method for tabular datasets
model = LogisticRegression()

# Train on CA data
model.fit(ca_features, ca_labels)

# Test on MI data
model.score(mi_features, mi_labels)

Distribution shift across time

In addition to the variation in distributions across states discussed previously, Folktables also contains ACS data for several different years, which itself constitutes a form of temporal distribution shift. For example, we can train a classifier using data from California in 2014 and evaluate how it's equality of opportunity violation or accuracy varies over time.

from folktables import ACSDataSource, ACSPublicCoverage
from sklearn.linear_model import LogisticRegression

# Download 2014 data
data_source = ACSDataSource(survey_year=2014, horizon='1-Year', survey='person')
acs_data14 = data_source.get_data(states=["CA"], download=True)
features14, labels14, _ = ACSPublicCoverage.df_to_numpy(acs_data14)

# Train model on 2014 data
# Plug-in your method for tabular datasets
model = LogisticRegression()
model.fit(features14, labels14)

# Evaluate model on 2015-2018 data
accuracies = []
for year in [2015, 2016, 2017, 2018]:
    data_source = ACSDataSource(survey_year=year, horizon='1-Year', survey='person')
    acs_data = data_source.get_data(states=["CA"], download=True)
    features, labels, _ = ACSPublicCoverage.df_to_numpy(acs_data)
    accuracies.append(model.score(features, labels))

Extract data in CSV with pandas

The data can be easily extracted in CSV format from a pandas dataframe.

from folktables import ACSDataSource, ACSIncome

data_source = ACSDataSource(survey_year='2018', horizon='1-Year', survey='person')
ca_data = data_source.get_data(states=["CA"], download=True)

ca_features, ca_labels, _ = ACSIncome.df_to_pandas(ca_data)

ca_features.to_csv('ca_features.csv', index=False)
ca_labels.to_csv('ca_labels.csv', index=False)

Take a look at the examples for encoding the categorical features with the df_to_pandas method.

Prediction tasks in folktables

Folktables provides the following pre-defined prediction tasks:

Each of these tasks can be instantiated on different ACS PUMS data samples, as illustrated in the quick start examples. Further details about each task can also be found in acs.py, where they are defined. For example, the ACSIncome task is defined by a list of the features that are included (features), the target variable of interest (target), the transformation applied to that variable (target_transform), the group membership variable (group), and any preprocessing or postprocessing functions (preprocess and postprocess) :

ACSIncome = folktables.BasicProblem(
    features=[
        'AGEP',
        'COW',
        'SCHL',
        'MAR',
        'OCCP',
        'POBP',
        'RELP',
        'WKHP',
        'SEX',
        'RAC1P',
    ],
    target='PINCP',
    target_transform=lambda x: x > 50000,    
    group='RAC1P',
    preprocess=folktables.adult_filter,
    postprocess=lambda x: np.nan_to_num(x, -1),
)

Creating a new prediction task

Folktables also makes it seamless to construct new prediction tasks based on US Census data. For example, we may be interested in modifying the predefined ACSIncome task by 1) removing the age feature from the task, 2) lowering the income threshold that determines the binary labels to $25000, and 3) setting the group membership variable to 'SEX' instead of 'RAC1P'. We can define this new task ACSIncomeNew as follows:

ACSIncomeNew = folktables.BasicProblem(
    features=[
        'COW',
        'SCHL',
        'MAR',
        'OCCP',
        'POBP',
        'RELP',
        'WKHP',
        'SEX',
        'RAC1P',
    ],
    target='PINCP',
    target_transform=lambda x: x > 25000,    
    group='SEX',
    preprocess=folktables.adult_filter,
    postprocess=lambda x: np.nan_to_num(x, -1),
)

Every field defining the prediction task can be modified, and all variables in the ACS PUMS data release are valid to include as features or as the target. Please see the ACS PUMS data dictionary for the full list of variables available. Also note that to protect privacy, the Census Bureau adds small perturbations to some variables, such as age, and may swap some variable values between similar individuals, when those values are relatively uncommon in the general population. These perturbations keep marginal statistics unchanged, but could affect conclusions drawn about individual predictive accuracy. Please see Accuracy of the PUMS and ASEC documentation for details on such perturbations.

Scope and limitations

Census data is often used by social scientists to study the extent of inequality in income, employment, education, housing or other aspects of life. Such important substantive investigations should necessarily inform debates about discrimination in classification scenarios within these domains. However, folktables' contribution is not in this direction. The package uses Census data for the empirical study of machine learning algorithms that attempt to predict outcomes for individuals. Folktables may be used to compare different methods on axes including accuracy, robustness, and fairness metric satisfaction, in an array of different concrete settings. The distinction we draw between benchmark data and substantive domain-specific investigations resonates with recent work that points out issues with using data about risk assessments tools from the criminal justice domain as machine learning benchmarks [1].

Another notable if obvious limitation of our work is that it is entirely US-centric. A richer dataset ecosystem covering international contexts within the algorithmic fairness community is still lacking. Although empirical work in the Global South is central in other disciplines, there continues to be much need for the North American fairness community to engage with it more strongly [2].

License and terms of use

Folktables provides code to download data from the American Community Survey (ACS) Public Use Microdata Sample (PUMS) files managed by the US Census Bureau. The data itself is governed by the terms of use provided by the Census Bureau. For more information, see https://www.census.gov/data/developers/about/terms-of-service.html

The Adult reconstruction dataset is a subsample of the IPUMS CPS data available from https://cps.ipums.org/. The data are intended for replication purposes only. Individuals analyzing the data for other purposes must submit a separate data extract request directly via IPUMS CPS. Individuals are not to redistribute the data without permission. Contact ipums@umn.edu for redistribution requests.

Citing folktables

If you use the Folktables datasets or the Adult reconstruction, we encourage you to cite our paper introducing the datasets:

@article{ding2021retiring,
  title={Retiring Adult: New Datasets for Fair Machine Learning},
  author={Ding, Frances and Hardt, Moritz and Miller, John and Schmidt, Ludwig},
  journal={Advances in Neural Information Processing Systems},
  volume={34},
  year={2021}
}

If you make use of the Adult Reconstruction, please additionally cite [3].

References

<a id="1">[1]</a> M. Bao, A. Zhou, S. Zottola, B. Brubach, S. Desmarais, A. Horowitz, K. Lum, and S. Venkatasubramanian. It’s compaslicated: The messy relationship between RAI datasets and algorithmic fairness benchmarks. arXiv preprint arXiv:2106.05498, 2021.

<a id="2">[2]</a> R. Abebe, K. Aruleba, A. Birhane, S. Kingsley, G. Obaido, S. L. Remy, and S. Sadagopan. Narratives and counternarratives on data sharing in Africa. In Proc. of the ACM Conference on Fairness, Accountability, and Transparency, pages 329–341, 2021.

<a id="3">[3]</a> S. Flood, M. King, R. Rodgers, S. Ruggles and J. Robert Warren. Integrated Public Use Microdata Series, Current Population Survey: Version 8.0 [dataset]. Minneapolis, MN: IPUMS, 2020. https://doi.org/10.18128/D030.V8.0