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Recursive Causal Discovery: Unveiling the Concept of Removable Variables in Causal Graphs


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Removable variables enable efficient causal discovery by reducing problem size and improving statistical reliability.
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The content discusses the concept of removable variables in causal graphs, introducing MARVEL, L-MARVEL, RSL, and ROL methods for recursive causal discovery. Removable variables are crucial for reducing computational complexity and improving statistical efficiency in causal discovery tasks. The algorithms presented focus on identifying removable variables and their neighbors to streamline the causal discovery process.

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O(n2 + n∆2in2∆in) O(n2 + n(∆+in)22∆+in) O(n2 + n∆m+1in) O(n2 + n∆3in) O(maxIter × n3) O(n22n)
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by Ehsan Mokhta... lúc arxiv.org 03-15-2024

https://arxiv.org/pdf/2403.09300.pdf
Recursive Causal Discovery

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How do these recursive methods compare to traditional score-based approaches in terms of efficiency

The recursive methods presented in the context provided, such as MARVEL, L-MARVEL, RSL, and ROL, offer significant advantages over traditional score-based approaches in terms of efficiency. These recursive methods leverage the concept of removable variables to reduce the problem size successively. By iteratively removing variables based on specific orders or criteria, these methods can significantly decrease the number of required conditional independence tests (CI tests). This reduction in testing leads to improved statistical reliability and computational efficiency compared to score-based methods. Additionally, these recursive causal discovery algorithms strategically identify removable variables that can be removed recursively for causal discovery purposes. This targeted approach allows for a more focused exploration of the causal graph structure while minimizing errors and reducing computational complexity. In contrast, traditional score-based approaches may need to explore a larger search space without this targeted removal strategy. Overall, the recursive methods excel in efficiently navigating through complex causal structures by iteratively identifying and eliminating variables based on their removability status. This targeted approach results in enhanced efficiency compared to traditional score-based methodologies.

What are the implications of assuming or not assuming causal sufficiency in the context of causal discovery

In the context of causal discovery, assuming or not assuming causal sufficiency has significant implications for the methodology and outcomes of the analysis. When assuming causal sufficiency: The focus is typically on learning directed acyclic graphs (DAGs) where all relevant variables are observed. Methods like MARVEL primarily target DAG structures where each variable's parents are known. The assumption simplifies certain aspects of causality inference but limits applicability when unobserved confounders exist. Algorithms like L-MARVEL extend beyond this assumption by considering latent variables but still operate under constraints imposed by observable data. On not assuming causal sufficiency: The scope broadens to include scenarios with hidden or unobserved variables that impact relationships between observed ones. Methods like RSL address situations where latent factors influence observed data without requiring full observability assumptions. These approaches provide more flexibility but often come with increased complexity due to handling additional uncertainty from unobserved factors. Ultimately, choosing whether or not to assume causal sufficiency depends on the specific research question at hand and available data constraints. Each approach offers unique insights into different facets of causality within varying degrees of observational completeness.

How can the concept of removable variables be applied to other fields beyond computer science

The concept of removable variables introduced in computer science for applications like casual discovery can be extended beyond this field into various other domains: Biomedical Research: In genetics studies analyzing gene interactions or pathways could benefit from identifying key genes as "removable" entities affecting biological processes. Economics: When studying economic systems' cause-effect relationships among various factors impacting markets or policies could involve identifying influential parameters as "removable" elements influencing outcomes. Environmental Science: Analyzing environmental phenomena such as climate change impacts might involve isolating critical environmental factors as "removable" components shaping ecological changes. Social Sciences: Understanding societal dynamics involving social networks or behavioral patterns could utilize removable concepts when pinpointing influential individuals or behaviors driving collective actions By applying removable variable principles across diverse fields outside computer science researchers gain valuable insights into underlying mechanisms governing complex systems leading towards more efficient analyses and informed decision-making processes across disciplines."
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