Identifiability of causal graphs under nonadditive conditionally parametric causal models

Causal discovery from observational data is a rather challenging, often impossible, task. However, an estimation of the causal structure is possible under certain assumptions on the data-generation process. Numerous commonly used methods rely on the additivity of noise in the structural equation models. Additivity implies that the variance or the tail of the effect, given the causes, is invariant; thus, the cause only affects the mean. However, the tail or other characteristics of the random variable can provide different information regarding the causal structure. Such cases have received very little attention in the literature thus far. Previous studies have revealed that the causal graph is identifiable under different models, such as linear non-Gaussian, post-nonlinear, or quadratic variance functional models. In this study, we introduce a new class of models called the conditional parametric causal models (CPCM), where the cause affects different characteristics of the effect. We use sufficient statistics to reveal the identifiability of the CPCM models in the exponential family of conditional distributions. Moreover, we propose an algorithm for estimating the causal structure from a random sample from the CPCM. The empirical properties of the methodology are studied for various datasets, including an application on the expenditure behavior of residents of the Philippines.