Scalable Computation of Causal Bounds

J. Mach. Learn. Res. Pub Date : 2023-08-04 DOI:10.48550/arXiv.2308.02709

Madhumitha Shridharan, G. Iyengar

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引用次数: 2

Abstract

We consider the problem of computing bounds for causal queries on causal graphs with unobserved confounders and discrete valued observed variables, where identifiability does not hold. Existing non-parametric approaches for computing such bounds use linear programming (LP) formulations that quickly become intractable for existing solvers because the size of the LP grows exponentially in the number of edges in the causal graph. We show that this LP can be significantly pruned, allowing us to compute bounds for significantly larger causal inference problems compared to existing techniques. This pruning procedure allows us to compute bounds in closed form for a special class of problems, including a well-studied family of problems where multiple confounded treatments influence an outcome. We extend our pruning methodology to fractional LPs which compute bounds for causal queries which incorporate additional observations about the unit. We show that our methods provide significant runtime improvement compared to benchmarks in experiments and extend our results to the finite data setting. For causal inference without additional observations, we propose an efficient greedy heuristic that produces high quality bounds, and scales to problems that are several orders of magnitude larger than those for which the pruned LP can be solved.

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因果界的可伸缩计算

我们考虑的问题是计算因果图上的因果查询的边界与未观察到的混杂和离散值观察变量，其中可辨识性不成立。现有的计算这种边界的非参数方法使用线性规划(LP)公式，由于LP的大小随着因果图中边的数量呈指数增长，这种公式很快就变得难以解决。我们表明，与现有技术相比，这种LP可以被显著修剪，使我们能够为更大的因果推理问题计算界限。这种修剪过程使我们能够以封闭形式计算一类特殊问题的界，其中包括经过充分研究的一类问题，其中多个混淆处理会影响结果。我们将我们的修剪方法扩展到分数lp，它计算包含关于单元的额外观察的因果查询的界限。我们表明，与实验中的基准测试相比，我们的方法提供了显着的运行时改进，并将我们的结果扩展到有限的数据设置。对于没有额外观察的因果推理，我们提出了一种有效的贪婪启发式方法，它产生高质量的界，并扩展到比修剪LP可以解决的问题大几个数量级的问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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J. Mach. Learn. Res.

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