A tutorial on score-based DAG learning methods that jointly estimate sparse structure and heteroscedastic noise for improved robustness.
Exploiting Non-Negativity in DAG Structure Learning
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abstract
This work addresses the problem of learning directed acyclic graphs (DAGs) from nodal observations generated by a linear structural equation model. DAG learning is a central task in signal processing, machine learning, and causal inference, but it remains challenging because acyclicity is a global combinatorial property. Continuous acyclicity constraints have led to important algorithmic advances by replacing the discrete DAG constraint with smooth equality constraints. However, existing formulations still involve difficult non-convex optimization landscapes and may suffer from degenerate first-order optimality conditions. Here, we restrict attention to DAGs with non-negative edge weights and exploit this additional structure to obtain a simpler characterization of acyclicity. Building on this characterization, we formulate a regularized non-negative DAG learning problem and develop an algorithm based on the method of multipliers. We further analyze the benign optimization landscape induced by non-negativity. In the population regime, we show that the true DAG is the unique global minimizer of the proposed augmented-Lagrangian formulation; moreover, the landscape contains no spurious interior stationary points, and the true DAG is the only acyclic KKT point. Numerical experiments on synthetic and real-world data show that the proposed method improves over state-of-the-art continuous DAG-learning alternatives.
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stat.ML 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Concomitant DAG Learning: On the Roles of Noise Adaptivity, Sparsity, and Non-negativity
A tutorial on score-based DAG learning methods that jointly estimate sparse structure and heteroscedastic noise for improved robustness.