从许多部分录音中逆向工程神经网络

E. Arani, Sofia Triantafillou, Konrad Paul Kording
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摘要

许多神经科学的目标是对大脑进行逆向工程,但我们一次只能记录一小部分神经元。我们目前还不知道,大脑逆向工程是否需要我们同时记录大多数神经元,还是从较小的子集中进行多次记录就足够了。新技术的发展使这一点变得更加重要,新技术允许从选定的神经元子集中进行记录,例如使用光学技术。为了解决这个问题,我们分析了一个在MNIST数据集上训练的神经网络,只使用部分记录,并描述了我们的逆向工程质量对同时记录的“神经元”数量的依赖关系。我们发现,如果同时记录足够多的神经元,那么非线性神经网络的逆向工程是有意义的,但这个数量可能比神经元的数量要小得多。此外,对小的随机神经元子集进行多次记录会产生令人惊讶的良好性能。在神经科学中的应用表明,为了近似实际神经系统的I/O功能,我们需要记录更多数量的神经元。我们在这里进行的这种规模分析可以,而且可以说应该用于校准可以显着扩大神经科学中记录数据集规模的方法。
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Reverse engineering neural networks from many partial recordings
Much of neuroscience aims at reverse engineering the brain, but we only record a small number of neurons at a time. We do not currently know if reverse engineering the brain requires us to simultaneously record most neurons or if multiple recordings from smaller subsets suffice. This is made even more important by the development of novel techniques that allow recording from selected subsets of neurons, e.g. using optical techniques. To get at this question, we analyze a neural network, trained on the MNIST dataset, using only partial recordings and characterize the dependency of the quality of our reverse engineering on the number of simultaneously recorded "neurons". We find that reverse engineering of the nonlinear neural network is meaningfully possible if a sufficiently large number of neurons is simultaneously recorded but that this number can be considerably smaller than the number of neurons. Moreover, recording many times from small random subsets of neurons yields surprisingly good performance. Application in neuroscience suggests to approximate the I/O function of an actual neural system, we need to record from a much larger number of neurons. The kind of scaling analysis we perform here can, and arguably should be used to calibrate approaches that can dramatically scale up the size of recorded data sets in neuroscience.
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