The iscan-dag
library is a Python 3 package designed for detecting which variables, if any, have undergone a causal mechanism shift given multiple datasets.
iSCAN operates through a systematic process:
- For each dataset, iSCAN initially evaluates the Hessian of the data distribution at each sample. This step helps identify the leaf variables (nodes) for all the datasets.
- Subsequently, for the identified leaf variable, iSCAN evaluates at each sample the Hessian of the data distribution for the pooled data (resembling a mixture distribution). Then, based on the variance of the Hessian values, iSCAN determines if the given leaf node has undergone a mechanism shift (termed shifted node).
The steps above are applied iteratively, eliminating the identified leaf variable across all datasets at each iteration. See iscan.est_node_shifts
for more details.
As an optional step, the library also includes a function to detect structural changes (termed shifted edges). As a by-product of detecting shifted nodes, iSCAN also estimates a topological ordering of the causal variables. Thus, allowing for the use of recent methods on variable (parents) selection. The current implementation of iSCAN employs FOCI
to identify the parent set of shifted nodes in each dataset. See iscan.est_struct_shifts
for more details.
This is an implementation of the following paper:
[1] Chen T., Bello K., Aragam B., Ravikumar P. (2023). "iSCAN: Identifying Causal Mechanism Shifts among Nonlinear Additive Noise Models". Advances in Neural Information Processing Systems.
If you find this code useful, please consider citing:
@article{chen2023iscan,
title={iSCAN: identifying causal mechanism shifts among nonlinear additive noise models},
author={Chen, Tianyu and Bello, Kevin and Aragam, Bryon and Ravikumar, Pradeep},
journal={Advances in Neural Information Processing Systems},
volume={36},
year={2023}
}
- Shifted nodes are detected without the need to estimate the DAG structure for each dataset.
- iSCAN is agnostic to the type of score's Jacobian estimator. The current implementation is based on a kernelized Stein's estimator. See
stein_hess
for details. - iSCAN's time complexity is not influenced by the underlying graph density and will run faster than methods such as DCI or UT-IGSP for a large number of variables due to its omission of (non)parametric conditional independence tests.
We recommend using a virtual environment via virtualenv
or conda
, and use pip
to install the iscan-dag
package.
$ pip install -U iscan-dag
See an example of how to use iSCAN in this iPython notebook.
We propose a new method for directly identifying changes (shifts) of causal mechanisms from multiple heterogeneous datasets, which are assumed to be originated by related structural causal models (SCMs) over the same set of variables.
iSCAN considers that each SCM belongs to the general class of nonlinear additive noise models (ANMs), thus, generalizing prior work that assumed linear models. We assume that each dataset is generated from an interventional (observational if no variables are intervened) distribution of an underlying graph
In [1], we prove that the Hessian of the log-density function of the mixture distribution reveals information about changes (shifts) in general non-parametric functional mechanisms for the leaf variables. Thus, allowing for the detection of shifted nodes. Our method leads to significant improvements in identifying shifted nodes.
Theorem 1 (see [1]).
Let
- Python 3.6+
numpy
igraph
torch
scikit-learn
rpy2
(R interface to use theFOCI
library).GPy
(Library to sample from Gaussian processes)kneed
(Used for the elbow heuristic)pandas
-
score_estimator.py
: Estimates the diagonal of the Hessian of$\log p(x)$ at the provided samples points. -
utils.py
: Utility functions for generating synthetic data, and evaluating the results -
shifted_nodes.py
: Implements iSCAN, providing detected shifted nodes. -
shifted_edges.py
: Implements the discovery of structural changes (shifted edges). -
my_foci.R
: R implementation that usesFOCI
for finding parents based on given nodes and topological order.
We thank the authors of the SCORE for making their code available. Part of our code is based on their implementation, especially the score_estimator.py
file.