Your search keyword '"Guo, Xianjie"' showing total 21 results

1. Towards Privacy-Aware Causal Structure Learning in Federated Setting

Author

Huang, Jianli, Guo, Xianjie, Yu, Kui, Cao, Fuyuan, and Liang, Jiye

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Cryptography and Security

Abstract

Causal structure learning has been extensively studied and widely used in machine learning and various applications. To achieve an ideal performance, existing causal structure learning algorithms often need to centralize a large amount of data from multiple data sources. However, in the privacy-preserving setting, it is impossible to centralize data from all sources and put them together as a single dataset. To preserve data privacy, federated learning as a new learning paradigm has attracted much attention in machine learning in recent years. In this paper, we study a privacy-aware causal structure learning problem in the federated setting and propose a novel Federated PC (FedPC) algorithm with two new strategies for preserving data privacy without centralizing data. Specifically, we first propose a novel layer-wise aggregation strategy for a seamless adaptation of the PC algorithm into the federated learning paradigm for federated skeleton learning, then we design an effective strategy for learning consistent separation sets for federated edge orientation. The extensive experiments validate that FedPC is effective for causal structure learning in a federated learning setting., Comment: This paper has been accepted by the journal IEEE Transactions on Big Data, and it contains 21 pages, 9 figures and 15 tables

Published

2022

2. A novel data enhancement approach to DAG learning with small data samples

Author

Huang, Xiaoling, Guo, Xianjie, Li, Yuling, and Yu, Kui

Published

2023

3. Local causal structure learning with missing data

Author

Sheng, Shaojing, Guo, Xianjie, Yu, Kui, and Wu, Xindong

Published

2024

4. Causality-based Feature Selection: Methods and Evaluations

Author

Yu, Kui, Guo, Xianjie, Liu, Lin, Li, Jiuyong, Wang, Hao, Ling, Zhaolong, and Wu, Xindong

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Statistics - Machine Learning

Abstract

Feature selection is a crucial preprocessing step in data analytics and machine learning. Classical feature selection algorithms select features based on the correlations between predictive features and the class variable and do not attempt to capture causal relationships between them. It has been shown that the knowledge about the causal relationships between features and the class variable has potential benefits for building interpretable and robust prediction models, since causal relationships imply the underlying mechanism of a system. Consequently, causality-based feature selection has gradually attracted greater attentions and many algorithms have been proposed. In this paper, we present a comprehensive review of recent advances in causality-based feature selection. To facilitate the development of new algorithms in the research area and make it easy for the comparisons between new methods and existing ones, we develop the first open-source package, called CausalFS, which consists of most of the representative causality-based feature selection algorithms (available at https://github.com/kuiy/CausalFS). Using CausalFS, we conduct extensive experiments to compare the representative algorithms with both synthetic and real-world data sets. Finally, we discuss some challenging problems to be tackled in future causality-based feature selection research.

Published

2019

5. Error-aware Markov blanket learning for causal feature selection

Author

Guo, Xianjie, Yu, Kui, Cao, Fuyuan, Li, Peipei, and Wang, Hao

Published

2022

6. Towards Privacy-Aware Causal Structure Learning in Federated Setting

Author

Huang, Jianli, primary, Guo, Xianjie, additional, Yu, Kui, additional, Cao, Fuyuan, additional, and Liang, Jiye, additional

Published

2023

7. Progressive Skeleton Learning for Effective Local-to-Global Causal Structure Learning

Author

Guo, Xianjie, Yu, Kui, Liu, Lin, Li, Jiuyong, Liang, Jiye, Cao, Fuyuan, and Wu, Xindong

Abstract

Causal structure learning (CSL) from observational data is a crucial objective in various machine learning applications. Recent advances in CSL have focused on local-to-global learning, which offers improved efficiency and accuracy. The local-to-global CSL algorithms first learn the local skeleton of each variable in a dataset, then construct the global skeleton by combining these local skeletons, and finally orient edges to infer causality. However, data quality issues such as noise and small samples often result in the presence of problematic asymmetric edges during global skeleton construction, hindering the creation of a high-quality global skeleton. To address this challenge, we propose a novel local-to-global CSL algorithm with a progressive enhancement strategy and make the following novel contributions: 1) To construct an accurate global skeleton, we design a novel strategy to iteratively correct asymmetric edges and progressively improve the accuracy of the global skeleton. 2) Based on the learned accurate global skeleton, we design an integrated global skeleton orientation strategy to infer the correct directions of edges for obtaining an accurate and reliable causal structure. Extensive experiments demonstrate that our method achieves better performance than the existing CSL methods.

Published

2024

8. Local causal structure learning with missing data

Author

Sheng, Shaojing, primary, Guo, Xianjie, additional, Yu, Kui, additional, and Wu, Xindong, additional

Published

2023

9. Causal Feature Selection in the Presence of Sample Selection Bias

Author

Yang, Shuai, primary, Guo, Xianjie, additional, Yu, Kui, additional, Huang, Xiaoling, additional, Jiang, Tingting, additional, He, Jin, additional, and Gu, Lichuan, additional

Published

2023

10. Causal Feature Selection With Dual Correction

Author

Guo, Xianjie, Yu, Kui, Liu, Lin, Cao, Fuyuan, and Li, Jiuyong

Abstract

Causal feature selection methods aim to identify a Markov boundary (MB) of a class variable, and almost all the existing causal feature selection algorithms use conditional independence (CI) tests to learn the MB. However, in real-world applications, due to data issues (e.g., noisy or small samples), CI tests can be unreliable; thus, causal feature selection algorithms relying on CI tests encounter two types of errors: false positives (i.e., selecting false MB features) and false negatives (i.e., discarding true MB features). Existing algorithms only tackle either false positives or false negatives, and they cannot deal with both types of errors at the same time, leading to unsatisfactory results. To address this issue, we propose a dual-correction-strategy-based MB learning (DCMB) algorithm to correct the two types of errors simultaneously. Specifically, DCMB selectively removes false positives from the MB features currently selected, while selectively retrieving false negatives from the features currently discarded. To automatically determine the optimal number of selected features for the selective removal and retrieval in the dual correction strategy, we design the simulated-annealing-based DCMB (SA-DCMB) algorithm. Using benchmark Bayesian network (BN) datasets, the experimental results demonstrate that DCMB achieves substantial improvements on the MB learning accuracy compared with the existing MB learning methods. Empirical studies in real-world datasets validate the effectiveness of SA-DCMB for classification against state-of-the-art causal and traditional feature selection algorithms.

Published

2024

11. Causal Feature Selection With Dual Correction

Author

Guo, Xianjie, primary, Yu, Kui, additional, Liu, Lin, additional, Cao, Fuyuan, additional, and Li, Jiuyong, additional

Published

2023

12. Adaptive Skeleton Construction for Accurate DAG Learning

Author

Guo, Xianjie, primary, Yu, Kui, additional, Liu, Lin, additional, Li, Peipei, additional, and Li, Jiuyong, additional

Published

2023

13. Bootstrap-based Causal Structure Learning

Author

Guo, Xianjie, primary, Wang, Yujie, additional, Huang, Xiaoling, additional, Yang, Shuai, additional, and Yu, Kui, additional

Published

2022

14. Hierarchical nanostructured 3D flowerlike BiOX particles with excellent visible-light photocatalytic activity

Author

Song, Jinling, Wang, Baoying, Guo, Xianjie, Wang, Ruifen, and Dong, Zhongping

Published

2016

15. Accelerating Learning Bayesian Network Structures by Reducing Redundant CI Tests

Author

Hu, Wentao, primary, Yang, Shuai, additional, Guo, Xianjie, additional, and Yu, Kui, additional

Published

2021

16. Improving Gradient-based DAG Learning by Structural Asymmetry

Author

Wang, Yujie, primary, Yang, Shuai, additional, Guo, Xianjie, additional, and Yu, Kui, additional

Published

2021

17. Causality-based Feature Selection

Author

Yu, Kui, primary, Guo, Xianjie, additional, Liu, Lin, additional, Li, Jiuyong, additional, Wang, Hao, additional, Ling, Zhaolong, additional, and Wu, Xindong, additional

Published

2020

18. Adaptive Skeleton Construction for Accurate DAG Learning

Author

Xianjie Guo, Kui Yu, Lin Liu, Peipei Li, Jiuyong Li, Guo, Xianjie, Liu, Lin, Yu, Kui, Li, Peipei, and Li, Jiuyong

Subjects

Computational Theory and Mathematics, local skeleton learning, directed acyclic graph, causal discovery, local-to-global structure learning, Computer Science Applications, Information Systems

Abstract

Refereed/Peer-reviewed Directed acyclic graph (DAG) learning plays a key role in causal discovery and many machine learning tasks. Learning a DAG from high-dimensional data always faces scalability problems. A local-to-global DAG learning approach can be scaled to high-dimensional data, however, existing local-to-global DAG learning algorithms employ either the AND-rule or the OR-rule for constructing a DAG skeleton. Simply using either rule, existing local-to-global methods may learn an inaccurate DAG skeleton, leading to unsatisfactory DAG learning performance. To tackle this problem, in this paper, we propose an A daptive D AG L earning (ADL) algorithm. The novel contribution of ADL is that it can simultaneously and adaptively use the AND-rule and the OR-rule to construct an accurate global DAG skeleton. We conduct extensive experiments on both benchmark and real-world datasets, and the experimental results show that ADL is significantly better than some existing local-to-global and global DAG learning algorithms.

Published

2023

19. Causal Feature Selection With Dual Correction

Author

Xianjie Guo, Kui Yu, Lin Liu, Fuyuan Cao, Jiuyong Li, Guo, Xianjie, Yu, Kui, Liu, Lin, Cao, Fuyuan, and Li, Jiuyong

Subjects

feature selection, Artificial Intelligence, Computer Networks and Communications, dual correction, Bayesian network (BN), Markov boundary (MB), Software, Computer Science Applications

Abstract

usc Causal feature selection methods aim to identify a Markov boundary (MB) of a class variable, and almost all the existing causal feature selection algorithms use conditional independence (CI) tests to learn the MB. However, in real-world applications, due to data issues (e.g., noisy or small samples), CI tests can be unreliable; thus, causal feature selection algorithms relying on CI tests encounter two types of errors: false positives (i.e., selecting false MB features) and false negatives (i.e., discarding true MB features). Existing algorithms only tackle either false positives or false negatives, and they cannot deal with both types of errors at the same time, leading to unsatisfactory results. To address this issue, we propose a dual-correction-strategy-based MB learning (DCMB) algorithm to correct the two types of errors simultaneously. Specifically, DCMB selectively removes false positives from the MB features currently selected, while selectively retrieving false negatives from the features currently discarded. To automatically determine the optimal number of selected features for the selective removal and retrieval in the dual correction strategy, we design the simulated-annealing-based DCMB (SA-DCMB) algorithm. Using benchmark Bayesian network (BN) datasets, the experimental results demonstrate that DCMB achieves substantial improvements on the MB learning accuracy compared with the existing MB learning methods. Empirical studies in real-world datasets validate the effectiveness of SA-DCMB for classification against state-of-the-art causal and traditional feature selection algorithms. Refereed/Peer-reviewed

Published

2023

20. Causality-based Feature Selection: Methods and Evaluations

Author

Xianjie Guo, Lin Liu, Kui Yu, Zhaolong Ling, Hao Wang, Xindong Wu, Jiuyong Li, Yu, Kui, Guo, Xianjie, Liu, Lin, Li, Jiuyong, Wang, Hao, Ling, Zhaolong, and Wu, Xindong

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, General Computer Science, Markov boundary, computing methodolgies, Computer science, Computer Science - Artificial Intelligence, Feature selection, Machine Learning (stat.ML), 02 engineering and technology, Machine learning, computer.software_genre, 01 natural sciences, Theoretical Computer Science, Machine Learning (cs.LG), Causality (physics), 010104 statistics & probability, feature selection, Statistics - Machine Learning, 0202 electrical engineering, electronic engineering, information engineering, Preprocessor, 0101 mathematics, Class variable, Mechanism (biology), business.industry, Bayesian network, Artificial Intelligence (cs.AI), Data analysis, 020201 artificial intelligence & image processing, Artificial intelligence, business, computer, Predictive modelling

Abstract

Feature selection is a crucial preprocessing step in data analytics and machine learning. Classical feature selection algorithms select features based on the correlations between predictive features and the class variable and do not attempt to capture causal relationships between them. It has been shown that the knowledge about the causal relationships between features and the class variable has potential benefits for building interpretable and robust prediction models, since causal relationships imply the underlying mechanism of a system. Consequently, causality-based feature selection has gradually attracted greater attentions and many algorithms have been proposed. In this paper, we present a comprehensive review of recent advances in causality-based feature selection. To facilitate the development of new algorithms in the research area and make it easy for the comparisons between new methods and existing ones, we develop the first open-source package, called CausalFS, which consists of most of the representative causality-based feature selection algorithms (available at https://github.com/kuiy/CausalFS). Using CausalFS, we conduct extensive experiments to compare the representative algorithms with both synthetic and real-world data sets. Finally, we discuss some challenging problems to be tackled in future causality-based feature selection research.

Published

2019

21. Causal Feature Selection With Dual Correction.

Author

Guo X, Yu K, Liu L, Cao F, and Li J

Abstract

Causal feature selection methods aim to identify a Markov boundary (MB) of a class variable, and almost all the existing causal feature selection algorithms use conditional independence (CI) tests to learn the MB. However, in real-world applications, due to data issues (e.g., noisy or small samples), CI tests can be unreliable; thus, causal feature selection algorithms relying on CI tests encounter two types of errors: false positives (i.e., selecting false MB features) and false negatives (i.e., discarding true MB features). Existing algorithms only tackle either false positives or false negatives, and they cannot deal with both types of errors at the same time, leading to unsatisfactory results. To address this issue, we propose a dual-correction-strategy-based MB learning (DCMB) algorithm to correct the two types of errors simultaneously. Specifically, DCMB selectively removes false positives from the MB features currently selected, while selectively retrieving false negatives from the features currently discarded. To automatically determine the optimal number of selected features for the selective removal and retrieval in the dual correction strategy, we design the simulated-annealing-based DCMB (SA-DCMB) algorithm. Using benchmark Bayesian network (BN) datasets, the experimental results demonstrate that DCMB achieves substantial improvements on the MB learning accuracy compared with the existing MB learning methods. Empirical studies in real-world datasets validate the effectiveness of SA-DCMB for classification against state-of-the-art causal and traditional feature selection algorithms.

Published

2022