Luís C. Lamb scite author profile

Luís C. Lamb

5Publications

160Citation Statements Received

41Citation Statements Given

How they've been cited

324

159

How they cite others

Affiliations

Federal University of Rio Grande do Sul, University of Rio Grande and Rio Grande Community College, Informatica (South Korea)

Publications

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Graph Neural Networks Meet Neural-Symbolic Computing: A Survey and Perspective

Lamb

Garcez

Gori

et al. 2020

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Neural-symbolic computing has now become the subject of interest of both academic and industry research laboratories. Graph Neural Networks (GNNs) have been widely used in relational and symbolic domains, with widespread application of GNNs in combinatorial optimization, constraint satisfaction, relational reasoning and other scientific domains. The need for improved explainability, interpretability and trust of AI systems in general demands principled methodologies, as suggested by neural-symbolic computing. In this paper, we review the state-of-the-art on the use of GNNs as a model of neural-symbolic computing. This includes the application of GNNs in several domains as well as their relationship to current developments in neural-symbolic computing.

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Chapter 1. Neural-Symbolic Learning and Reasoning: A Survey and Interpretation1

Besold

Garcez

Bader

et al. 2021

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The study and understanding of human behaviour is relevant to computer science, artificial intelligence, neural computation, cognitive science, philosophy, psychology, and several other areas. Presupposing cognition as basis of behaviour, among the most prominent tools in the modelling of behaviour are computational-logic systems, connectionist models of cognition, and models of uncertainty. Recent studies in cognitive science, artificial intelligence, and psychology have produced a number of cognitive models of reasoning, learning, and language that are underpinned by computation. In addition, efforts in computer science research have led to the development of cognitive computational systems integrating machine learning and automated reasoning. Such systems have shown promise in a range of applications, including computational biology, fault diagnosis, training and assessment in simulators, and software verification. This joint survey reviews the personal ideas and views of several researchers on neural-symbolic learning and reasoning. The article is organised in three parts: Firstly, we frame the scope and goals of neural-symbolic computation and have a look at the theoretical foundations. We then proceed to describe the realisations of neural-symbolic computation, systems, and applications. Finally we present the challenges facing the area and avenues for further research.

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Graph Colouring Meets Deep Learning: Effective Graph Neural Network Models for Combinatorial Problems

Lemos

Prates

Avelar

et al. 2019

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Deep learning has consistently defied state-of-the-art techniques in many fields over the last decade. However, we are just beginning to understand the capabilities of neural learning in symbolic domains. Deep learning architectures that employ parameter sharing over graphs can produce models which can be trained on complex properties of relational data. These include highly relevant N P-Complete problems, such as SAT and TSP. In this work, we showcase how Graph Neural Networks (GNN) can be engineered -with a very simple architecture -to solve the fundamental combinatorial problem of graph colouring. Our results show that the model, which achieves high accuracy upon training on random instances, is able to generalise to graph distributions different from those seen at training time. Further, it performs better than the Neurosat, Tabucol and greedy baselines for some distributions. In addition, we show how vertex embeddings can be clustered in multidimensional spaces to yield constructive solutions even though our model is only trained as a binary classifier. In summary, our results contribute to shorten the gap in our understanding of the algorithms learned by GNNs, as well as hoarding empirical evidence for their capability on hard combinatorial problems. Our results thus contribute to the standing challenge of integrating robust learning and symbolic reasoning in Deep Learning systems.

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Neurosymbolic AI: the 3rd wave

Garcez

Lamb

2023

Artif Intell Rev

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Superpixel Image Classification with Graph Attention Networks

Avelar

Tavares

Silveira

et al. 2020

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Luís C. Lamb

Graph Neural Networks Meet Neural-Symbolic Computing: A Survey and Perspective

Chapter 1. Neural-Symbolic Learning and Reasoning: A Survey and Interpretation1

Graph Colouring Meets Deep Learning: Effective Graph Neural Network Models for Combinatorial Problems

Neurosymbolic AI: the 3rd wave

Superpixel Image Classification with Graph Attention Networks

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