// Fit, summarize, plot, and interpret a chosen CausalPy experiment. Use after the causal method has been selected, including when configuring PyMC/sklearn models and scale-aware custom priors.
Choose the appropriate CausalPy experiment class from a causal question, data structure, treatment assignment, and identification assumptions. Use before writing analysis code when the method is not yet settled.
Review CausalPy pull requests end-to-end by classifying PR type, checking branch freshness, mergeability, remote CI, correctness, security, tests, docs, and maintainer concerns. Use when asked to review a PR, assess a branch before merge, summarize PR risks, or request changes.
Create, evaluate, and triage GitHub issues for CausalPy. Use when filing a bug, proposing an enhancement, analyzing existing issues, or splitting large work into parent-child sub-issues.
Bring a pull request to green by syncing with main, resolving conflicts safely, and fixing failing checks with CausalPy conventions.
Turn issues into PRs, handle commits, and run prek checks consistently.
Perform structured research and turn findings into an implementation plan.
| name | running-causalpy-experiments |
| description | Fit, summarize, plot, and interpret a chosen CausalPy experiment. Use after the causal method has been selected, including when configuring PyMC/sklearn models and scale-aware custom priors. |
Use this skill when the CausalPy experiment class is already known or has just been selected by choosing-causalpy-methods. This skill is for execution: preparing data, instantiating the experiment, choosing a model backend, setting sane priors, inspecting outputs, plotting, and communicating results.
DataFrame with the data layout required by the chosen experiment.sample_kwargs and scale-aware priors when predictors or outcomes are not standardized.summary(), effect_summary(), print_coefficients(), and plot() only where the chosen experiment supports them.cp.Pipeline, cp.EstimateEffect, and cp.SensitivityAnalysis when robustness matters.cp.pymc_models.LinearRegression, configure priors for beta and the observation noise inside y_hat.WeightedSumFitter, SoftmaxWeightedSumFitter, and SyntheticDifferenceInDifferencesWeightFitter.PropensityScore, standardize continuous confounders or use coefficient priors that imply plausible log-odds shifts.InstrumentalVariableRegression, priors are passed at the experiment level through priors=... and should reflect the scale of both the treatment-stage and outcome-stage regressions.experiment.summary(): Prints a method-specific summary where implemented.experiment.effect_summary(): Returns a decision-ready structured effect summary where implemented.experiment.plot(): Visualizes fitted values, counterfactuals, effects, or diagnostics where implemented.experiment.print_coefficients(): Shows model coefficients for model-backed experiments.result = cp.Pipeline(...).run(): Runs estimation, sensitivity checks, and report generation as a reproducible workflow.InversePropensityWeighting.plot() is intentionally a stub. Use plot_ate() and plot_balance_ecdf() instead.InversePropensityWeighting.effect_summary() is not implemented. Inspect ATE draws, overlap, balance, and weight stability instead.InstrumentalVariable.plot(), summary(), and effect_summary() are not implemented, so inspect model outputs and first-stage/second-stage diagnostics directly.PanelRegression.effect_summary() is not implemented because panel fixed-effects models report coefficient-level estimates rather than time-window impacts. Use summary(), print_coefficients(), and plot() or plot_coefficients().