posteriordb
is a set of posteriors, i.e. Bayesian statistical models
and data sets, reference implementations in probabilistic programming
languages, and reference posterior inferences in the form of posterior
samples.
posteriordb
is designed to test inference algorithms across a wide
range of models and data sets. Applications include testing for
accuracy, speed, and scalability. posteriordb
can be used to test new
algorithms being developed or deployed as part of continuous integration
for ongoing regression testing algorithms in probabilistic programming
frameworks.
posteriordb
also makes it easy for students and instructors to access
various pedagogical and real-world examples with precise model
definitions, well-curated data sets, and reference posteriors.
posteriordb
is framework agnostic and easily accessible from R and
Python.
For more details regarding the use cases of posteriordb
, see
doc/use_cases.md.
See DATABASE_CONTENT.md for the details content of the posterior database.
We are happy with any help in adding posteriors, data, and models to the database! See CONTRIBUTING.md for the details on how to contribute.
To simplify the use of posteriordb
, there are convenience functions
both in R and in Python.
- For R, see the posteriordb-r repository.
- For Python, see the posteriordb-python repository.
Developing and maintaining open-source software is an important yet
often underappreciated contribution to scientific progress. Thus, please
make sure to cite it appropriately so that developers get credit for
their work. Information on how to cite posteriordb
can be found in the
CITATION.cff
file. Use the “cite this repository” button under “About” to get a
simple BibTeX or APA snippet.
As posteriordb
rely heavily on Stan, so please consider also to cite
Stan:
Carpenter B., Gelman A., Hoffman M. D., Lee D., Goodrich B., Betancourt M., Brubaker M., Guo J., Li P., and Riddell A. (2017). Stan: A probabilistic programming language. Journal of Statistical Software. 76(1). 10.18637/jss.v076.i01
The main focus of the database is simplicity, both in understanding and in use.
The following are the current design choices in designing the posterior database.
- Priors are hardcoded in model files as changing the prior changes the posterior. Create a new model to test different priors.
- Data transformations are stored as different datasets. Create new data to test different data transformations, subsets, and variable settings. This design choice makes the database larger/less memory efficient but simplifies the analysis of individual posteriors.
- Models and data has (model/data).info.json files with model and data specific information.
- Templates for different JSONs can be found in content/templates and schemas in schemas (Note: these don’t exist right now and will be added later)
- Prefix ‘syn_’ stands for synthetic data where the generative process is known and found in content/data-raw.
- All data preprocessing is included in content/data-raw.
- Specific information for different PPL representations of models is included in the PPL syntax files as comments, not in the model.info.json files.
We might update models included in posteriordb over time. However, the models will only have the same name in posteriordb if the log density is the same (up to a normalizing constant). Otherwise, we will include a new model in the database.