pymc
БесплатноЗапускает вложенные скриптыНе проверенBayesian modeling with PyMC. Build hierarchical models, MCMC (NUTS), variational inference, LOO/WAIC comparison, posterior checks, for probabilistic programming
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PyMC Bayesian Modeling
Overview
PyMC is a Python library for Bayesian modeling and probabilistic programming. Build, fit, validate, and compare Bayesian models using PyMC's modern API (version 6.x+), including hierarchical models, MCMC sampling (NUTS), variational inference, posterior predictive checks, and model comparison (LOO, WAIC).
Current Version and Setup
PyMC 6.0.1 is the current stable release as of June 2026. It requires Python 3.12+, uses PyTensor 3 as the computational graph backend, and defaults to compiled backends such as Numba. For reproducible local environments, pin the version:
uv pip install "pymc[nutpie]==6.0.1"
The nutpie extra enables the faster Rust/Numba NUTS implementation. If using NumPyro or BlackJAX, install those optional sampler dependencies in the same environment and pin them in the project lockfile.
When to Use This Skill
This skill should be used when:
- Building Bayesian models (linear/logistic regression, hierarchical models, time series, etc.)
- Performing MCMC sampling or variational inference
- Conducting prior/posterior predictive checks
- Diagnosing sampling issues (divergences, convergence, ESS)
- Comparing multiple models using information criteria (LOO, WAIC)
- Implementing uncertainty quantification through Bayesian methods
- Working with hierarchical/multilevel data structures
- Handling missing data or measurement error in a principled way
Standard Bayesian Workflow
Follow this workflow for building and validating Bayesian models:
1. Data Preparation
import pymc as pm
import arviz as az
import numpy as np
# Load and prepare data
X = ... # Predictors
y = ... # Outcomes
# Standardize predictors for better sampling
X_mean = X.mean(axis=0)
X_std = X.std(axis=0)
X_scaled = (X - X_mean) / X_std
Key practices:
- Standardize continuous predictors (improves sampling efficiency)
- Center outcomes when possible
- Handle missing data explicitly (treat as parameters)
- Use named dimensions with
coordsfor clarity
2. Model Building
coords = {
'predictors': ['var1', 'var2', 'var3'],
'obs_id': np.arange(len(y))
}
with pm.Model(coords=coords) as model:
# Mutable data container so prediction data can be swapped later
X_data = pm.Data('X_scaled', X_scaled, dims=('obs_id', 'predictors'))
# Priors
alpha = pm.Normal('alpha', mu=0, sigma=1)
beta = pm.Normal('beta', mu=0, sigma=1, dims='predictors')
sigma = pm.HalfNormal('sigma', sigma=1)
# Linear predictor
mu = alpha + pm.math.dot(X_data, beta)
# Tie the observed variable's shape to X_data for out-of-sample prediction
y_obs = pm.Normal('y_obs', mu=mu, sigma=sigma, observed=y, shape=X_data.shape[0], dims='obs_id')
Key practices:
- Use weakly informative priors (not flat priors)
- Use
HalfNormalorExponentialfor scale parameters - Use named dimensions (
dims) instead ofshapewhen possible - Use
pm.Data()for values that will be updated for predictions
3. Prior Predictive Check
Always validate priors before fitting:
with model:
prior_pred = pm.sample_prior_predictive(draws=1000, random_seed=42)
# Visualize
az.plot_ppc(prior_pred, group='prior')
Check:
- Do prior predictions span reasonable values?
- Are extreme values plausible given domain knowledge?
- If priors generate implausible data, adjust and re-check
4. Fit Model
with model:
# Optional: Quick exploration with ADVI
# approx = pm.fit(n=20000)
# Full MCMC inference
idata = pm.sample(
draws=2000,
tune=1000,
chains=4,
target_accept=0.9,
random_seed=42,
idata_kwargs={'log_likelihood': True} # For model comparison
)
Key parameters:
draws=2000: Number of samples per chaintune=1000: Warmup samples (discarded)chains=4: Run 4 chains for convergence checkingtarget_accept=0.9: Higher for difficult posteriors (0.95-0.99)- Include
log_likelihood=Truefor model comparison - If using PyMC 6 sampler-specific kwargs, avoid deprecated
nuts_sampler_kwargs; pass explicit NUTS kwargs throughnuts={...}when needed
5. Check Diagnostics
Use the diagnostic script:
from scripts.model_diagnostics import check_diagnostics
results = check_diagnostics(idata, var_names=['alpha', 'beta', 'sigma'])
Check:
- R-hat < 1.01: Chains have converged
- ESS > 400: Sufficient effective samples
- No divergences: NUTS sampled successfully
- Trace plots: Chains should mix well (fuzzy caterpillar)
If issues arise:
- Divergences → Increase
target_accept=0.95, use non-centered parameterization - Low ESS → Sample more draws, reparameterize to reduce correlation
- High R-hat → Run longer, check for multimodality
6. Posterior Predictive Check
Validate model fit:
with model:
pm.sample_posterior_predictive(idata, extend_inferencedata=True, random_seed=42)
# Visualize
az.plot_ppc(idata)
Check:
- Do posterior predictions capture observed data patterns?
- Are systematic deviations evident (model misspecification)?
- Consider alternative models if fit is poor
7. Analyze Results
# Summary statistics
print(az.summary(idata, var_names=['alpha', 'beta', 'sigma']))
# Posterior distributions
az.plot_posterior(idata, var_names=['alpha', 'beta', 'sigma'])
# Coefficient estimates
az.plot_forest(idata, var_names=['beta'], combined=True)
8. Make Predictions
X_new = ... # New predictor values
X_new_scaled = (X_new - X_mean) / X_std
with model:
pm.set_data({'X_scaled': X_new_scaled}, coords={'obs_id': np.arange(len(X_new_scaled))})
post_pred = pm.sample_posterior_predictive(
idata,
var_names=['y_obs'],
predictions=True,
random_seed=42
)
# Extract prediction intervals
y_pred_mean = post_pred.predictions['y_obs'].mean(dim=['chain', 'draw'])
y_pred_hdi = az.hdi(post_pred.predictions, var_names=['y_obs'])
Common Model Patterns
Linear Regression
For continuous outcomes with linear relationships:
with pm.Model() as linear_model:
alpha = pm.Normal('alpha', mu=0, sigma=10)
beta = pm.Normal('beta', mu=0, sigma=10, shape=n_predictors)
sigma = pm.HalfNormal('sigma', sigma=1)
mu = alpha + pm.math.dot(X, beta)
y = pm.Normal('y', mu=mu, sigma=sigma, observed=y_obs)
Use template: assets/linear_regression_template.py
Logistic Regression
For binary outcomes:
with pm.Model() as logistic_model:
alpha = pm.Normal('alpha', mu=0, sigma=10)
beta = pm.Normal('beta', mu=0, sigma=10, shape=n_predictors)
logit_p = alpha + pm.math.dot(X, beta)
y = pm.Bernoulli('y', logit_p=logit_p, observed=y_obs)
Hierarchical Models
For grouped data (use non-centered parameterization):
with pm.Model(coords={'groups': group_names}) as hierarchical_model:
# Hyperpriors
mu_alpha = pm.Normal('mu_alpha', mu=0, sigma=10)
sigma_alpha = pm.HalfNormal('sigma_alpha', sigma=1)
# Group-level (non-centered)
alpha_offset = pm.Normal('alpha_offset', mu=0, sigma=1, dims='groups')
alpha = pm.Deterministic('alpha', mu_alpha + sigma_alpha * alpha_offset, dims='groups')
# Observation-level
mu = alpha[group_idx]
sigma = pm.HalfNormal('sigma', sigma=1)
y = pm.Normal('y', mu=mu, sigma=sigma, observed=y_obs)
Use template: assets/hierarchical_model_template.py
Critical: Always use non-centered parameterization for hierarchical models to avoid divergences.
Poisson Regression
For count data:
with pm.Model() as poisson_model:
alpha = pm.Normal('alpha', mu=0, sigma=10)
beta = pm.Normal('beta', mu=0, sigma=10, shape=n_predictors)
log_lambda = alpha + pm.math.dot(X, beta)
y = pm.Poisson('y', mu=pm.math.exp(log_lambda), observed=y_obs)
For overdispersed counts, use `NegativeBinom
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FAQ
Что делает скилл pymc?
Bayesian modeling with PyMC. Build hierarchical models, MCMC (NUTS), variational inference, LOO/WAIC comparison, posterior checks, for probabilistic programming and inference.
Как установить скилл pymc?
Скопируй папку скилла в ~/.claude/skills (вкладка Claude Code выше делает это одной командой), либо поставь как плагин.
Скилл pymc запускает скрипты?
Да, скилл несёт исполняемые скрипты. Проверь исходник перед установкой.
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