2024

• Moritz Schauer, Marcel Wienöbst:
  Causal structure learning with momentum: Sampling distributions over Markov Equivalence Classes of DAGs.
  In Proceedings of the 12th International Conference on Probabilistic Graphical Models, Band 246 von Proceedings of Machine Learning Research, S. 382-400. PMLR, 2024.
  Website anzeigen
• Marcel Wienöbst, Benito van der Zander, Maciej Liskiewicz:
  Linear-Time Algorithms for Front-Door Adjustment in Causal Graphs.
  In AAAI Conference on Artificial Intelligence (AAAI 2024), S. 20577-20584. , 2024.
  Website anzeigen

2023

• Malte Luttermann, Marcel Wienöbst, Maciej Liskiewicz:
  Practical Algorithms for Orientations of Partially Directed Graphical Models.
  In Conference on Causal Learning and Reasoning (CLeaR 2023), S. 1-20. PLRM, 2023.
  Website anzeigen
• Marcel Wienöbst, Malte Luttermann, Max Bannach, Maciej Liskiewicz:
  Efficient enumeration of Markov equivalent DAGs.
  In AAAI Conference on Artificial Intelligence (AAAI 2023), S. 12313-12320. , 2023.
  Website anzeigen
• Marcel Wienöbst, Max Bannach, Maciej Liskiewicz:
  Polynomial-Time Algorithms for Counting and Sampling Markov Equivalent DAGs with Applications.
  Journal of Machine Learning Research, (24.213):1-45, 2023.
  Website anzeigen

2022

• Marcel Wienöbst, Max Bannach, Maciej Liskiewicz:
  A New Constructive Criterion for Markov Equivalence of MAGs.
  In Proc. of the Thirty-Eighth Conference on Uncertainty in Artificial Intelligence (UAI 2022), S. 2107-2116. PMLR, 2022.
  Website anzeigen
• Benito van der Zander, Marcel Wienöbst, Markus Bläser, Maciej Liskiewicz:
  Identification in Tree-shaped Linear Structural Causal Models.
  In Proceedings of The 25th International Conference on Artificial Intelligence and Statistics, S. 6770-6792. PLMR, 2022.
  Website anzeigen

2021

• Marcel Wienöbst, Maciej Liskiewicz:
  An Approach to Reduce the Number of Conditional Independence Tests in the PC Algorithm.
  In Proceeding of 44th German Conference on AI (KI 2021), Band 12873 von Lecture Notes in Computer Science, S. 276-288. Springer, 2021.
  Website anzeigen
• Marcel Wienöbst, Max Bannach, Maciej Liskiewicz:
  Extendability of Causal Graphical Models: Algorithms and Computational Complexity.
  In Proc. of the Thirty-Seventh Conference on Uncertainty in Artificial Intelligence (UAI 2021), S. 1248-1257. PMLR, 2021.
  Website anzeigen
• Marcel Wienöbst, Max Bannach, Maciej Liskiewicz:
  Polynomial-Time Algorithms for Counting and Sampling Markov Equivalent DAGs.
  In Proceedings of the Thirty-Fifth AAAI Conference on Artificial Intelligence (AAAI'21), S. 12198-12206. AAAI Press, 2021.
  Website anzeigen | PDF anzeigen | Zusammenfassung anzeigen
  
  Counting and sampling directed acyclic graphs from a Markov equivalence class are fundamental tasks in graphical causal analysis. In this paper, we show that these tasks can be performed in polynomial time, solving a long-standing open problem in this area. Our algorithms are effective and easily implementable. Experimental results show that the algorithms significantly outperform state-of-the-art methods.
• Marcel Wienöbst, Max Bannach, Maciej Liskiewicz:
  Recent Advances in Counting and Sampling Markov Equivalent DAGs.
  In Proceeding of 44th German Conference on AI (KI 2021), Band 12873 von Lecture Notes in Computer Science, S. 271-275. Springer, 2021.
  Website anzeigen | Zusammenfassung anzeigen
  
  Counting and sampling directed acyclic graphs (DAGs) from a Markov equivalence class are fundamental tasks in graphical causal analysis. In this paper, we discuss recently proposed polynomial-time algorithms for these tasks. The presented result solves a long-standing open problem in graphical modelling. Experiments show that the proposed algorithms are implementable and effective in practice. Our paper is an extended abstract of the work [24], honored as an AAAI-21 Distinguished Paper at the 35th AAAI Conference on Artificial Intelligence.

2020

• Max Bannach, Sebastian Berndt, Martin Schuster, Marcel Wienöbst:
  PACE Solver Description: PID*.
  In Proceedings of the 15th International Symposium on Parameterized and Exact Computation (IPEC 2020), LIPIcs, 2020.
  Website anzeigen | Zusammenfassung anzeigen
  
  This document provides a short overview of our treedepth solver PID^{?} in the version that we submitted to the exact track of the PACE challenge 2020. The solver relies on the positive-instance driven dynamic programming (PID) paradigm that was discovered in the light of earlier iterations of the PACE in the context of treewidth. It was recently shown that PID can be used to solve a general class of vertex pursuit-evasion games - which include the game theoretic characterization of treedepth. Our solver PID^{?} is build on top of this characterization.
• Max Bannach, Sebastian Berndt, Martin Schuster, Marcel Wienöbst:
  PACE Solver Description: Fluid.
  In Proceedings of the 15th International Symposium on Parameterized and Exact Computation (IPEC 2020), LIPIcs, 2020.
  Website anzeigen | Zusammenfassung anzeigen
  
  This document describes the heuristic for computing treedepth decompositions of undirected graphs used by our solve fluid. The heuristic runs four different strategies to find a solution and finally outputs the best solution obtained by any of them. Two strategies are score-based and iteratively remove the vertex with the best score. The other two strategies iteratively search for vertex separators and remove them. We also present implementation strategies and data structures that significantly improve the run time complexity and might be interesting on their own.
• Marcel Wienöbst, Maciej Liskiewicz:
  Recovering Causal Structures from Low-Order Conditional Independencies.
  In Proceedings of the Thirty-Fourth AAAI Conference on Artificial Intelligence (AAAI'20), New York, New York USA, S. 10302-10309. AAAI Press, 2020.
  Website anzeigen | PDF anzeigen | Zusammenfassung anzeigen
  
  One of the common obstacles for learning causal models from data is that high-order conditional independence (CI) relationships between random variables are difficult to estimate. Since CI tests with conditioning sets of low order can be performed accurately even for a small number of observations, a reasonable approach to determine casual structures is to base merely on the low-order CIs. Recent research has confirmed that, e.g. in the case of sparse true causal models, structures learned even from zero- and first-order conditional independencies yield good approximations of the models. However, a challenging task here is to provide methods that faithfully explain a given set of low-order CIs. In this paper we propose an algorithm which, for a given set of conditional independencies of order less or equal to $k$, where $k$ is a small fixed number, computes a faithful graphical representation of the given set. Our results complete and generalize the previous work on learning from pairwise marginal independencies. Moreover, they enable to improve upon the 0-1 graph model which, e.g. is heavily used in the estimation of genome networks.

2019

• Marcel Wienöbst:
  Constraint-based causal structure learning exploiting low-order conditional independences.
  Universität zu Lübeck, Institut für Theoretische Informatik, 2019.
  Gutachter: Maciej Liskiewicz, Ralf Möller.
  PDF anzeigen