Learning instance-specific counterfactual models for continuous treatments using hypernetworks

In recent years, non-linear machine learning techniques have attracted increasing attention for estimating treatment effects from observational data. While most existing methods focus on binary treatment scenarios, the estimation of treatment effects for continuous interventions remains a critical challenge in many real-world applications. In this work, we introduce a novel neural network-based approach for estimating continuous treatment effects by leveraging hypernetworks to model counterfactual outcomes across treatment levels. This approach extends the principles of binary treatment effects computation to the continuous domain, addressing the key challenge of treatment relevance. By generating weights for a fixed network that predicts potential outcomes, our architecture ensures that the treatment variable retains its causal significance while maintaining the flexibility of deep learning models. Through extensive experiments on synthetic and semi-synthetic datasets, we demonstrate that our approach outperforms existing methods in terms of precision. The results highlight the advantages of explicitly modeling the relationship between treatment levels and outcomes, particularly in settings where traditional methods struggle with high-dimensional confounders or non-linear treatment-response dynamics.