Single World Intervention Graphs: A simple framework for unifying graphs and potential outcomes with applications to mediation analysis
Time: 2025-12-30
Published By: Jing Liu
Speaker(s): Thomas Richardson (University of Washington)
Time: 10:00-11:00 January 6, 2026
Venue: Room 29, Quan Zhai, BICMR
ABSTRACT:
Causal models based on potential outcomes, also known as counterfactuals, were introduced by Neyman (1923) and extended to observational settings by Rubin (1974). Causal Directed Acyclic Graphs (DAGs) are another framework, originally introduced by Wright (1921), but subsequently significantly generalized and extended by Spirtes et al. (1993), Pearl (1995), and Dawid (2002), among others.
In this talk I will first present a simple approach to unifying these two approaches via Single-World Intervention Graphs (SWIGs). The SWIG encodes the counterfactual independences associated with a specific hypothetical intervention on a set of treatment variables. The nodes on the SWIG are the corresponding counterfactual random variables. This represents a counterfactual model originally introduced by Robins (1986) using event trees, known as Finest Fully Randomized Causally Interpretable Structured Tree Graphs (FFRCISTG).
Malinsky et al. (2019) show that this synthesis leads to a simplification of the do-calculus of Pearl (1995) that clarifies and separates the underlying concepts. Recently we have also shown that a (minimal) version of the SWIG framework is equivalent to a reformulation of the causal decision diagrams of Dawid (2021).
By expanding the graph, SWIGs may also be used to describe a novel interventionist approach to mediation analysis whereby treatment is decomposed into multiple separable components. This provides a means of discussing direct effects without reference to ''cross-world” independence assumptions, nested counterfactuals or interventions on the mediator. The theory preserves the dictum ''no causation without manipulation'' and makes questions of mediation empirically testable in future randomized controlled trials.
This is joint work with James M. Robins (Harvard) and Ilya Shpitser (Johns Hopkins).
