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Main Authors: Dhawan, Nikita, Paruthi, Arnav, Kim, Andrew, Gondara, Lovedeep, Novikova, Jekaterina, Maddison, Chris J.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.27281
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author Dhawan, Nikita
Paruthi, Arnav
Kim, Andrew
Gondara, Lovedeep
Novikova, Jekaterina
Maddison, Chris J.
author_facet Dhawan, Nikita
Paruthi, Arnav
Kim, Andrew
Gondara, Lovedeep
Novikova, Jekaterina
Maddison, Chris J.
contents Predicting the effect of interventions with many possible variations, e.g., therapeutic content that affects mental health outcomes or an earnings call transcript that drives movement in share price, is useful across several domains. However, classical causal estimators tend to assume that all possible interventions are observed, which is infeasible when interventions vary widely, for instance, in the space of all text strings. We adapt a well-known approach of recasting causal inference as a learning problem, to address high-dimensional treatment spaces. Specifically, under standard assumptions like no unobserved confounding, we show that causal error decomposes into a series of moment-balancing errors of increasing order, and design objectives that directly improve causal estimation. We also show how to project the effect of a high-dimensional treatment onto lower-dimensional treatment attributes, which allows a single model to answer several causal questions without additional attribute-specific training. We empirically evaluate our estimators in settings with high-dimensional continuous, discrete, and text treatments, the last of which used a semi-synthetic dataset of Amazon Reviews. Our experiments demonstrate the benefit of higher-order balance error optimization and competitive performance of projected causal estimates with attribute-specific estimators.
format Preprint
id arxiv_https___arxiv_org_abs_2605_27281
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Causal Risk Minimization for High-Dimensional Treatments
Dhawan, Nikita
Paruthi, Arnav
Kim, Andrew
Gondara, Lovedeep
Novikova, Jekaterina
Maddison, Chris J.
Machine Learning
Predicting the effect of interventions with many possible variations, e.g., therapeutic content that affects mental health outcomes or an earnings call transcript that drives movement in share price, is useful across several domains. However, classical causal estimators tend to assume that all possible interventions are observed, which is infeasible when interventions vary widely, for instance, in the space of all text strings. We adapt a well-known approach of recasting causal inference as a learning problem, to address high-dimensional treatment spaces. Specifically, under standard assumptions like no unobserved confounding, we show that causal error decomposes into a series of moment-balancing errors of increasing order, and design objectives that directly improve causal estimation. We also show how to project the effect of a high-dimensional treatment onto lower-dimensional treatment attributes, which allows a single model to answer several causal questions without additional attribute-specific training. We empirically evaluate our estimators in settings with high-dimensional continuous, discrete, and text treatments, the last of which used a semi-synthetic dataset of Amazon Reviews. Our experiments demonstrate the benefit of higher-order balance error optimization and competitive performance of projected causal estimates with attribute-specific estimators.
title Causal Risk Minimization for High-Dimensional Treatments
topic Machine Learning
url https://arxiv.org/abs/2605.27281