Abstract / Description of output
The ability to synthesize realistic patterns of neural activity is crucial for studying neural information processing. Here we used the Generative Adversarial Networks (GANs) framework to simulate the concerted activity of a population of neurons. We adapted the Wasserstein-GAN variant to facilitate the generation of unconstrained neural population activity patterns while still benefiting from parameter sharing in the temporal domain. We demonstrate that our proposed GAN, which we termed Spike-GAN, generates spike trains that match accurately the first- and second-order statistics of datasets of tens of neurons and also approximates well their higher-order statistics. We applied Spike-GAN to a real dataset recorded from salamander retina and showed that it performs as well as state-of-the-art approaches based on the maximum entropy and the dichotomized Gaussian frameworks. Importantly, Spike-GAN does not require to specify a priori the statistics to be matched by the model, and so constitutes a more flexible method than these alternative approaches. Finally, we show how to exploit a trained Spike-GAN to construct 'importance maps' to detect the most relevant statistical structures present in a spike train. Spike-GAN provides a powerful, easy-to-use technique for generating realistic spiking neural activity and for describing the most relevant features of the large-scale neural population recordings studied in modern systems neuroscience.
Original language | English |
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Title of host publication | International Conference on Learning Representations 2018 |
Number of pages | 24 |
Publication status | Published - 3 May 2018 |
Event | 6th International Conference on Learning Representations - Vancouver, Canada Duration: 30 Apr 2018 → 3 May 2018 https://iclr.cc/Conferences/2018 |
Conference
Conference | 6th International Conference on Learning Representations |
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Abbreviated title | ICLR 2018 |
Country/Territory | Canada |
City | Vancouver |
Period | 30/04/18 → 3/05/18 |
Internet address |
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Arno Onken
- School of Informatics - Lecturer in Data Science for Life Sciences
- Institute for Adaptive and Neural Computation
- Edinburgh Neuroscience
- Data Science and Artificial Intelligence
Person: Academic: Research Active