Vincent C. H. Leung scite author profile

The brain is a hugely diverse, heterogeneous structure. Whether or not heterogeneity at the neural level plays a functional role remains unclear, and has been relatively little explored in models which are often highly homogeneous. We compared the performance of spiking neural networks trained to carry out tasks of real-world difficulty, with varying degrees of heterogeneity, and found that heterogeneity substantially improved task performance. Learning with heterogeneity was more stable and robust, particularly for tasks with a rich temporal structure. In addition, the distribution of neuronal parameters in the trained networks is similar to those observed experimentally. We suggest that the heterogeneity observed in the brain may be more than just the byproduct of noisy processes, but rather may serve an active and important role in allowing animals to learn in changing environments.

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Neural heterogeneity promotes robust learning

Perez-Nieves

Leung

Dragotti

et al. 2020

Preprint

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The brain has a hugely diverse, heterogeneous structure. By contrast, many functional neural models are homogeneous. We compared the performance of spiking neural networks trained to carry out difficult tasks, with varying degrees of heterogeneity. Introducing heterogeneity in membrane and synapse time constants substantially improved task performance, and made learning more stable and robust across multiple training methods, particularly for tasks with a rich temporal structure. In addition, the distribution of time constants in the trained networks closely matches those observed experimentally. We suggest that the heterogeneity observed in the brain may be more than just the byproduct of noisy processes, but rather may serve an active and important role in allowing animals to learn in changing environments.SummaryNeural heterogeneity is metabolically efficient for learning, and optimal parameter distribution matches experimental data.

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Advantages of heterogeneity of parameters in spiking neural network training

Perez-Nieves

Leung

Dragotti

et al. 2019

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Learning-based Reconstruction of FRI Signals

Leung¹,

Huang²,

Eldar³

et al. 2022

Preprint

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Reconstruction of FRI Signals using Autoencoders with Fixed Decoders

Leung

Huang

Eldar

et al. 2021

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Vincent C. H. Leung

Neural heterogeneity promotes robust learning

Neural heterogeneity promotes robust learning

Advantages of heterogeneity of parameters in spiking neural network training

Learning-based Reconstruction of FRI Signals

Reconstruction of FRI Signals using Autoencoders with Fixed Decoders

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