DIET: Conditional independence testing with marginal dependence measures of residual information.

Mukund Sudarshan, Aahlad Puli, Wesley Tansey, Rajesh Ranganath
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Abstract

Conditional randomization tests (CRTs) assess whether a variable x is predictive of another variable y, having observed covariates z. CRTs require fitting a large number of predictive models, which is often computationally intractable. Existing solutions to reduce the cost of CRTs typically split the dataset into a train and test portion, or rely on heuristics for interactions, both of which lead to a loss in power. We propose the decoupled independence test (DIET), an algorithm that avoids both of these issues by leveraging marginal independence statistics to test conditional independence relationships. DIET tests the marginal independence of two random variables: Fxz(xz) and Fyz(yz) where Fz(z) is a conditional cumulative distribution function (CDF) for the distribution p(z). These variables are termed "information residuals." We give sufficient conditions for DIET to achieve finite sample type-1 error control and power greater than the type-1 error rate. We then prove that when using the mutual information between the information residuals as a test statistic, DIET yields the most powerful conditionally valid test. Finally, we show DIET achieves higher power than other tractable CRTs on several synthetic and real benchmarks.

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DIET:利用残差信息的边际依赖性测量进行条件独立性检验。
条件随机化检验(CRTs)评估的是一个变量 x 是否能预测另一个变量 y 以及观察到的协变量 z。CRT 需要拟合大量的预测模型,这在计算上往往难以实现。现有的降低 CRT 成本的解决方案通常是将数据集分成训练和测试两部分,或依赖启发式方法进行交互,这两种方法都会导致预测能力下降。我们提出的解耦独立性测试(DIET)算法利用边际独立性统计来测试条件独立性关系,从而避免了上述两个问题。DIET 测试两个随机变量的边际独立性:Fx∣z(x∣z)和 Fy∣z(y∣z),其中 F∣z(⋅∣z)是分布 p(⋅∣z)的条件累积分布函数(CDF)。这些变量被称为 "信息残差"。我们给出了 DIET 实现有限样本类型-1 错误控制和功率大于类型-1 错误率的充分条件。然后,我们证明了当使用信息残差之间的互信息作为检验统计量时,DIET 会产生最强大的条件有效检验。最后,我们展示了 DIET 在几个合成和真实基准上比其他可行的 CRT 获得了更高的功率。
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