Understanding the limitations of network online learning

LaRock, Timothy; Sakharov, Timothy; Bhadra, Sahely; Eliassi-Rad, Tina

doi:10.1007/s41109-020-00296-w

Cited by 5 publications

(3 citation statements)

References 27 publications

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“…Our goal is to show the limitations of PI-GNN on some graphs. This analysis is inspired by the results of [25], where the authors study the limitations of the network online learning algorithms by considering different types of graphs.…”

Section: Applications In Scientific Discoverymentioning

confidence: 99%

HypOp: Distributed Constrained Combinatorial Optimization leveraging Hypergraph Neural Networks

Heydaribeni,

Zhan,

Zhang

et al. 2023

Preprint

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Scalable addressing of high dimensional constrained combinatorial optimization problems is a challenge that arises in several science and engineering disciplines. Recent work introduced novel application of graph neural networks for solving polynomial-cost unconstrained combinatorial optimization problems. This paper proposes a new framework, called HypOp, which greatly advances the state of the art for solving combinatorial optimization problems in several aspects: (i) it generalizes the prior results to constrained optimization problems with an arbitrary cost function; (ii) it broadens the application to higher dimensional problems by leveraging a hypergraph neural network structure; (iii) it enables scalability to much larger problems by introducing a new distributed and parallel architecture for hypergraph neural network training; (iv) it demonstrates generalizability to other problem formulations by knowledge transfer from the learned experience of addressing one set of cost/constraints to another set for the same hypergraph; (v) it significantly boosts the solution accuracy compared with the prior art by suggesting a fine-tuning step using simulated annealing; (vi) HypOp shows a remarkable progress on benchmark examples, with run times improved by up to fivefold using a combination of fine-tuning and distributed training techniques. The framework allows addressing a novel set of scientific problems including hypergraph MaxCut problem, satisfiability problems (3SAT), and resource allocation. We showcase the application of HypOp in scientific discovery by solving a hypergraph MaxCut problem on the NDC drug-substance hypergraph. Through extensive experimentation on a variety of combinatorial optimization problems, HypOp demonstrates superiority over existing unsupervised learning-based solvers and generic optimization methods.

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Section: Applications In Scientific Discoverymentioning

confidence: 99%

HypOp: Distributed Constrained Combinatorial Optimization leveraging Hypergraph Neural Networks

Heydaribeni,

Zhan,

Zhang

et al. 2023

Preprint

Self Cite

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“…For the performance testing of each community detection algorithm, it is preferable to run on networks that can be modified regarding the mesoscopic characteristics, including the distribution of degrees, the extent of local clustering, and the modularity of the global structure (LaRock et al, 2020). First, the degree distribution is important in determining whether learning is feasible or beneficial.…”

Section: Introductionmentioning

confidence: 99%

Identifying Communities with Modularity Metric Using Louvain and Leiden Algorithms

Hairol Anuar,

Abal Abas,

Md Yunos

et al. 2024

JST

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Over the past 20 years, there has been a significant increase in publication in complex network analysis research, especially in community detection. Many methods were proposed to identify community structure. Each community identification algorithm has strengths and weaknesses due to the complexity of information. Among them, the optimisation methods are widely focused on. This paper focuses on an empirical study of two community detection algorithms based on agglomerative techniques using modularity metric: Louvain and Leiden. In this regard, the Louvain algorithm has been shown to produce a bad connection in the community and disconnected when executed iteratively. Therefore, the Leiden algorithm is designed to successively resolve the weaknesses. Performance comparisons between the two and their concept were summarised in detail, as well as the step-by-step learning process of the state-of-the-art algorithms. This study is important and beneficial to the future study of interdisciplinary data sciences of network analysis. First, it demonstrates that the Leiden method outperformed the Louvain algorithm in terms of modularity metric and running time. Second, the paper displays the use of these two algorithms on synthetic and real networks. The experiment was successful as it identified better performance, and future work is required to confirm and validate these findings.

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“…For example, PATHATTACK assumes full knowledge of the graph, which in many settings is not realistic. Combining a method like PATHATTACK with a method to explore more of an unseen network, like Network Online Learning* [84] may provide a more apt formulation for such scenarios. There are many interesting theoretical questions raised by this work.…”

Section: Chapter 6 Conclusionmentioning

confidence: 99%

Vulnerability and robustness in artificial intelligence for complex networks

Miller

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forever a conflict of interest when reviewing research papers: I am indebted to her in a way I can't pay back. I'll just have to pay it forward.I also want to thank the other members of my committee: Christoph Riedl, Alina Oprea, and Scott Alfeld. They brought a diverse and thoughtful set of perspectives that encouraged me to think differently about work I had been steeped in for years. In addition, I have been fortunate to have a great set of collaborators during my time at Northeastern, including

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Understanding the limitations of network online learning

Cited by 5 publications

References 27 publications

HypOp: Distributed Constrained Combinatorial Optimization leveraging Hypergraph Neural Networks

HypOp: Distributed Constrained Combinatorial Optimization leveraging Hypergraph Neural Networks

Identifying Communities with Modularity Metric Using Louvain and Leiden Algorithms

Vulnerability and robustness in artificial intelligence for complex networks

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