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Differentiable Invariant Causal Discovery

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arxiv 2205.15638 v4 pith:TPFUUFXA submitted 2022-05-31 cs.LG cs.DSstat.ME

Differentiable Invariant Causal Discovery

classification cs.LG cs.DSstat.ME
keywords causaldicddifferentiablediscoveryenvironmentsdatalearningacross
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Learning causal structure from observational data is a fundamental challenge in machine learning. However, the majority of commonly used differentiable causal discovery methods are non-identifiable, turning this problem into a continuous optimization task prone to data biases. In many real-life situations, data is collected from different environments, in which the functional relations remain consistent across environments, while the distribution of additive noises may vary. This paper proposes Differentiable Invariant Causal Discovery (DICD), utilizing the multi-environment information based on a differentiable framework to avoid learning spurious edges and wrong causal directions. Specifically, DICD aims to discover the environment-invariant causation while removing the environment-dependent correlation. We further formulate the constraint that enforces the target structure equation model to maintain optimal across the environments. Theoretical guarantees for the identifiability of proposed DICD are provided under mild conditions with enough environments. Extensive experiments on synthetic and real-world datasets verify that DICD outperforms state-of-the-art causal discovery methods up to 36% in SHD. Our code will be open-sourced.

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