Skip to main content

Causal inference for quasi-experiments in Python

Project description


Build Code style: black PyPI version GitHub Repo stars Read the Docs PyPI - Downloads Interrogate codecov

CausalPy

A Python package focussing on causal inference in quasi-experimental settings. The package allows for sophisticated Bayesian model fitting methods to be used in addition to traditional OLS.

STATUS: Feel free to explore and experiment with the repository, and we very much welcome feedback (via Issues). But be aware that this code is very alpha! Expect the codebase and API to change for a while, so it is not appropriate to rely on this package for in-production or research pipelines.

Comparison to related packages

Rather than focussing on one particular quasi-experimental setting, this package aims to have broad applicability.

Another distinctive feature of this package is the ability to use different models. Currently, users can fit with scikit-learn models or Bayesian models with PyMC.

CausalImpact from Google GeoLift from Meta CausalPy from PyMC Labs
Synthetic control
Regression discontinuity
Difference in differences
Language R (but see tfcausalimpact) R Python
Models Bayesian structural timeseries Augmented synthetic control Flexible: Traditional OLS and Bayesian models

Installation

To get the latest release:

pip install CausalPy

Alternatively, if you want the very latest version of the package you can install from GitHub:

pip install git+https://github.com/pymc-labs/CausalPy.git

Quickstart

import causalpy as cp


# Import and process data
df = (
    cp.load_data("drinking")
    .rename(columns={"agecell": "age"})
    .assign(treated=lambda df_: df_.age > 21)
    )

# Run the analysis
result = cp.pymc_experiments.RegressionDiscontinuity(
    df,
    formula="all ~ 1 + age + treated",
    running_variable_name="age",
    model=cp.pymc_models.LinearRegression(),
    treatment_threshold=21,
    )

# Visualize outputs
fig, ax = result.plot();

# Get a results summary
result.summary()

Roadmap

Plans for the repository can be seen in the Issues.

Videos

Click on the thumbnail below to watch a video about CausalPy on YouTube. Youtube video thumbnail image

Overview of package capabilities

Synthetic control

This is appropriate when you have multiple units, one of which is treated. You build a synthetic control as a weighted combination of the untreated units.

Time Outcome Control 1 Control 2 Control 3
0 $y_0$ $x_{1,0}$ $x_{2,0}$ $x_{3,0}$
1 $y_1$ $x_{1,1}$ $x_{2,1}$ $x_{3,1}$
$\ldots$ $\ldots$ $\ldots$ $\ldots$ $\ldots$
T $y_T$ $x_{1,T}$ $x_{2,T}$ $x_{3,T}$
Frequentist Bayesian

The data (treated and untreated units), pre-treatment model fit, and counterfactual (i.e. the synthetic control) are plotted (top). The causal impact is shown as a blue shaded region. The Bayesian analysis shows shaded Bayesian credible regions of the model fit and counterfactual. Also shown is the causal impact (middle) and cumulative causal impact (bottom).

Geographical lift (Geolift)

We can also use synthetic control methods to analyse data from geographical lift studies. For example, we can try to evaluate the causal impact of an intervention (e.g. a marketing campaign) run in one geographical area by using control geographical areas which are similar to the intervention area but which did not recieve the specific marketing intervention.

ANCOVA

This is appropriate for non-equivalent group designs when you have a single pre and post intervention measurement and have a treament and a control group.

Group pre post
0 $x_1$ $y_1$
0 $x_2$ $y_2$
1 $x_3$ $y_3$
1 $x_4$ $y_4$
Frequentist Bayesian
coming soon

The data from the control and treatment group are plotted, along with posterior predictive 94% credible intervals. The lower panel shows the estimated treatment effect.

Difference in Differences

This is appropriate for non-equivalent group designs when you have pre and post intervention measurement and have a treament and a control group. Unlike the ANCOVA approach, difference in differences is appropriate when there are multiple pre and/or post treatment measurements.

Data is expected to be in the following form. Shown are just two units - one in the treated group (group=1) and one in the untreated group (group=0), but there can of course be multiple units per group. This is panel data (also known as repeated measures) where each unit is measured at 2 time points.

Unit Time Group Outcome
0 0 0 $y_{0,0}$
0 1 0 $y_{0,0}$
1 0 1 $y_{1,0}$
1 1 1 $y_{1,1}$
Frequentist Bayesian

The data, model fit, and counterfactual are plotted. Frequentist model fits result in points estimates, but the Bayesian analysis results in posterior distributions, represented by the violin plots. The causal impact is the difference between the counterfactual prediction (treated group, post treatment) and the observed values for the treated group, post treatment.

Regression discontinuity designs

Regression discontinuity designs are used when treatment is applied to units according to a cutoff on the running variable (e.g. $x$) which is typically not time. By looking for the presence of a discontinuity at the precise point of the treatment cutoff then we can make causal claims about the potential impact of the treatment.

Running variable Outcome Treated
$x_0$ $y_0$ False
$x_1$ $y_0$ False
$\ldots$ $\ldots$ $\ldots$
$x_{N-1}$ $y_{N-1}$ True
$x_N$ $y_N$ True
Frequentist Bayesian

The data, model fit, and counterfactual are plotted (top). Frequentist analysis shows the causal impact with the blue shaded region, but this is not shown in the Bayesian analysis to avoid a cluttered chart. Instead, the Bayesian analysis shows shaded Bayesian credible regions of the model fits. The Frequentist analysis visualises the point estimate of the causal impact, but the Bayesian analysis also plots the posterior distribution of the regression discontinuity effect (bottom).

Learning resources

Here are some general resources about causal inference:

  • The official PyMC examples gallery has a set of examples specifically relating to causal inference.
  • Angrist, J. D., & Pischke, J. S. (2009). Mostly harmless econometrics: An empiricist's companion. Princeton university press.
  • Angrist, J. D., & Pischke, J. S. (2014). Mastering'metrics: The path from cause to effect. Princeton university press.
  • Cunningham, S. (2021). Causal inference: The Mixtape. Yale University Press.
  • Huntington-Klein, N. (2021). The effect: An introduction to research design and causality. Chapman and Hall/CRC.
  • Reichardt, C. S. (2019). Quasi-experimentation: A guide to design and analysis. Guilford Publications.

License

Apache License 2.0


Support

This repository is supported by PyMC Labs.

If you are interested in seeing what PyMC Labs can do for you, then please email ben.vincent@pymc-labs.io. We work with companies at a variety of scales and with varying levels of existing modeling capacity. We also run corporate workshop training events and can provide sessions ranging from introduction to Bayes to more advanced topics.

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

CausalPy-0.0.13.tar.gz (91.3 kB view details)

Uploaded Source

Built Distribution

CausalPy-0.0.13-py3-none-any.whl (88.2 kB view details)

Uploaded Python 3

File details

Details for the file CausalPy-0.0.13.tar.gz.

File metadata

  • Download URL: CausalPy-0.0.13.tar.gz
  • Upload date:
  • Size: 91.3 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.1 CPython/3.11.4

File hashes

Hashes for CausalPy-0.0.13.tar.gz
Algorithm Hash digest
SHA256 950a86ac304889344a378dab69ac8a9afd842053a5eef93226c5f98642914b13
MD5 d1d400bc1cdc6dfcf92c1c3426812020
BLAKE2b-256 910f57e31d693b5ceeb72e782dd1b6eb0f182cbd4add0cd6f6d1260e87075f37

See more details on using hashes here.

File details

Details for the file CausalPy-0.0.13-py3-none-any.whl.

File metadata

  • Download URL: CausalPy-0.0.13-py3-none-any.whl
  • Upload date:
  • Size: 88.2 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.1 CPython/3.11.4

File hashes

Hashes for CausalPy-0.0.13-py3-none-any.whl
Algorithm Hash digest
SHA256 d83bd82ef33cdb41879d250de3ac8318ff03927ea323c2d53dc2bfe1e824cd32
MD5 aaa9ca591be4f98850ebc72f5060c2b6
BLAKE2b-256 b6fad0bac3fb94579f2ff88c81010b0a6e9c3391e0f4fd372c1d2b9e311b3753

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page