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Autores principales: Javurek, Emil, Frauen, Dennis, Brockschmidt, Marie, Schweisthal, Jonas, Feuerriegel, Stefan
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2605.10590
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author Javurek, Emil
Frauen, Dennis
Brockschmidt, Marie
Schweisthal, Jonas
Feuerriegel, Stefan
author_facet Javurek, Emil
Frauen, Dennis
Brockschmidt, Marie
Schweisthal, Jonas
Feuerriegel, Stefan
contents Causal sensitivity analysis aims to provide bounds for causal effect estimates in the presence of unobserved confounding. However, existing methods for causal sensitivity analysis are per-instance procedures, meaning that changes to the dataset, causal query, sensitivity level, or treatment require new computation. Here, we instead present an in-context learning approach. Specifically, we propose an amortized approach to causal sensitivity analysis based on prior-data fitted networks. A key challenge is that the sensitivity bounds are not directly available when sampling training data. To address this, we develop a general prior-data construction that is applicable across the class of generalized treatment sensitivity models. Our construction involves a Lagrangian scalarization of the objective to generate training labels for the bounds through a tradeoff between causal effect min/max-imization and sensitivity model violation, which avoids model-specific analytical derivations. We further show that, under standard convexity and linearity conditions, our objective recovers the full Pareto frontier of solutions. Empirically, we demonstrate our amortized approach across various datasets, causal queries, and sensitivity levels, where our approach achieves a test-time computation that is orders of magnitude faster than per-instance methods. To the best of our knowledge, ours is the first foundation model for in-context learning for causal sensitivity analysis.
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publishDate 2026
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spellingShingle Amortizing Causal Sensitivity Analysis via Prior Data-Fitted Networks
Javurek, Emil
Frauen, Dennis
Brockschmidt, Marie
Schweisthal, Jonas
Feuerriegel, Stefan
Machine Learning
Causal sensitivity analysis aims to provide bounds for causal effect estimates in the presence of unobserved confounding. However, existing methods for causal sensitivity analysis are per-instance procedures, meaning that changes to the dataset, causal query, sensitivity level, or treatment require new computation. Here, we instead present an in-context learning approach. Specifically, we propose an amortized approach to causal sensitivity analysis based on prior-data fitted networks. A key challenge is that the sensitivity bounds are not directly available when sampling training data. To address this, we develop a general prior-data construction that is applicable across the class of generalized treatment sensitivity models. Our construction involves a Lagrangian scalarization of the objective to generate training labels for the bounds through a tradeoff between causal effect min/max-imization and sensitivity model violation, which avoids model-specific analytical derivations. We further show that, under standard convexity and linearity conditions, our objective recovers the full Pareto frontier of solutions. Empirically, we demonstrate our amortized approach across various datasets, causal queries, and sensitivity levels, where our approach achieves a test-time computation that is orders of magnitude faster than per-instance methods. To the best of our knowledge, ours is the first foundation model for in-context learning for causal sensitivity analysis.
title Amortizing Causal Sensitivity Analysis via Prior Data-Fitted Networks
topic Machine Learning
url https://arxiv.org/abs/2605.10590