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arxiv: 2504.11076 · v2 · pith:WW5B2R7Onew · submitted 2025-04-15 · 📊 stat.ME · cs.LG

Using Time Structure to Estimate Causal Effects

classification 📊 stat.ME cs.LG
keywords timecausaleffectsseriesdirectunderadditionalapproach
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There exist several approaches for estimating causal effects in time series when latent confounding is present. Many of these approaches rely on additional auxiliary observed variables or time series such as instruments, negative controls or time series that satisfy the front- or backdoor criterion in certain graphs. In this paper, we present a novel approach for estimating direct (and via Wright's path rule total) causal effects in a time series setup which does not rely on additional auxiliary observed variables or time series. This approach assumes that the underlying time series is a Structural Vector Autoregressive (SVAR) process and estimates direct causal effects by solving certain linear equation systems made up of different covariances and model parameters. We state sufficient graphical criteria in terms of the so-called full time graph under which these linear equations systems are uniquely solvable and under which their solutions contain the to-be-identified direct causal effects as components. We also state sufficient lag-based criteria under which the previously mentioned graphical conditions are satisfied and, thus, under which direct causal effects are identifiable. Several numerical experiments underline the correctness and applicability of our results.

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Cited by 1 Pith paper

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  1. Identifying Direct Causal Effects in Latent Factor Models by Accounting for Unidentified Parents

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    New identification criterion for direct effects in latent factor models that accounts for unidentified parents to handle denser confounding graphs, with network-flow based algorithm.