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Hauptverfasser: Lubana, Ekdeep Singh, Kawaguchi, Kyogo, Dick, Robert P., Tanaka, Hidenori
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2408.12578
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author Lubana, Ekdeep Singh
Kawaguchi, Kyogo
Dick, Robert P.
Tanaka, Hidenori
author_facet Lubana, Ekdeep Singh
Kawaguchi, Kyogo
Dick, Robert P.
Tanaka, Hidenori
contents Increase in data, size, or compute can lead to sudden learning of specific capabilities by a neural network -- a phenomenon often called "emergence''. Beyond scientific understanding, establishing the causal factors underlying such emergent capabilities is crucial to enable risk regulation frameworks for AI. In this work, we seek inspiration from study of emergent properties in other fields and propose a phenomenological definition for the concept in the context of neural networks. Our definition implicates the acquisition of general structures underlying the data-generating process as a cause of sudden performance growth for specific, narrower tasks. We empirically investigate this definition by proposing an experimental system grounded in a context-sensitive formal language and find that Transformers trained to perform tasks on top of strings from this language indeed exhibit emergent capabilities. Specifically, we show that once the language's underlying grammar and context-sensitivity inducing structures are learned by the model, performance on narrower tasks suddenly begins to improve. We then analogize our network's learning dynamics with the process of percolation on a bipartite graph, establishing a formal phase transition model that predicts the shift in the point of emergence observed in our experiments when changing the data structure. Overall, our experimental and theoretical frameworks yield a step towards better defining, characterizing, and predicting emergence in neural networks.
format Preprint
id arxiv_https___arxiv_org_abs_2408_12578
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Percolation Model of Emergence: Analyzing Transformers Trained on a Formal Language
Lubana, Ekdeep Singh
Kawaguchi, Kyogo
Dick, Robert P.
Tanaka, Hidenori
Machine Learning
Artificial Intelligence
Increase in data, size, or compute can lead to sudden learning of specific capabilities by a neural network -- a phenomenon often called "emergence''. Beyond scientific understanding, establishing the causal factors underlying such emergent capabilities is crucial to enable risk regulation frameworks for AI. In this work, we seek inspiration from study of emergent properties in other fields and propose a phenomenological definition for the concept in the context of neural networks. Our definition implicates the acquisition of general structures underlying the data-generating process as a cause of sudden performance growth for specific, narrower tasks. We empirically investigate this definition by proposing an experimental system grounded in a context-sensitive formal language and find that Transformers trained to perform tasks on top of strings from this language indeed exhibit emergent capabilities. Specifically, we show that once the language's underlying grammar and context-sensitivity inducing structures are learned by the model, performance on narrower tasks suddenly begins to improve. We then analogize our network's learning dynamics with the process of percolation on a bipartite graph, establishing a formal phase transition model that predicts the shift in the point of emergence observed in our experiments when changing the data structure. Overall, our experimental and theoretical frameworks yield a step towards better defining, characterizing, and predicting emergence in neural networks.
title A Percolation Model of Emergence: Analyzing Transformers Trained on a Formal Language
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2408.12578