4,253 research outputs found
Biologically plausible deep learning -- but how far can we go with shallow networks?
Training deep neural networks with the error backpropagation algorithm is
considered implausible from a biological perspective. Numerous recent
publications suggest elaborate models for biologically plausible variants of
deep learning, typically defining success as reaching around 98% test accuracy
on the MNIST data set. Here, we investigate how far we can go on digit (MNIST)
and object (CIFAR10) classification with biologically plausible, local learning
rules in a network with one hidden layer and a single readout layer. The hidden
layer weights are either fixed (random or random Gabor filters) or trained with
unsupervised methods (PCA, ICA or Sparse Coding) that can be implemented by
local learning rules. The readout layer is trained with a supervised, local
learning rule. We first implement these models with rate neurons. This
comparison reveals, first, that unsupervised learning does not lead to better
performance than fixed random projections or Gabor filters for large hidden
layers. Second, networks with localized receptive fields perform significantly
better than networks with all-to-all connectivity and can reach backpropagation
performance on MNIST. We then implement two of the networks - fixed, localized,
random & random Gabor filters in the hidden layer - with spiking leaky
integrate-and-fire neurons and spike timing dependent plasticity to train the
readout layer. These spiking models achieve > 98.2% test accuracy on MNIST,
which is close to the performance of rate networks with one hidden layer
trained with backpropagation. The performance of our shallow network models is
comparable to most current biologically plausible models of deep learning.
Furthermore, our results with a shallow spiking network provide an important
reference and suggest the use of datasets other than MNIST for testing the
performance of future models of biologically plausible deep learning.Comment: 14 pages, 4 figure
Empirical learning aided by weak domain knowledge in the form of feature importance
Standard hybrid learners that use domain knowledge require stronger knowledge that is hard and expensive to acquire. However, weaker domain knowledge can benefit from prior knowledge while being cost effective. Weak knowledge in the form of feature relative importance (FRI) is presented and explained. Feature relative importance is a real valued approximation of a feature’s importance provided by experts. Advantage of using this knowledge is demonstrated by IANN, a modified multilayer neural network algorithm. IANN is a very simple modification of standard neural network algorithm but attains significant performance gains. Experimental results in the field of molecular biology show higher performance over other empirical learning algorithms including standard backpropagation and support vector machines. IANN performance is even comparable to a theory refinement system KBANN that uses stronger domain knowledge. This shows Feature relative importance can improve performance of existing empirical learning algorithms significantly with minimal effort
Exact solutions to the nonlinear dynamics of learning in deep linear neural networks
Despite the widespread practical success of deep learning methods, our
theoretical understanding of the dynamics of learning in deep neural networks
remains quite sparse. We attempt to bridge the gap between the theory and
practice of deep learning by systematically analyzing learning dynamics for the
restricted case of deep linear neural networks. Despite the linearity of their
input-output map, such networks have nonlinear gradient descent dynamics on
weights that change with the addition of each new hidden layer. We show that
deep linear networks exhibit nonlinear learning phenomena similar to those seen
in simulations of nonlinear networks, including long plateaus followed by rapid
transitions to lower error solutions, and faster convergence from greedy
unsupervised pretraining initial conditions than from random initial
conditions. We provide an analytical description of these phenomena by finding
new exact solutions to the nonlinear dynamics of deep learning. Our theoretical
analysis also reveals the surprising finding that as the depth of a network
approaches infinity, learning speed can nevertheless remain finite: for a
special class of initial conditions on the weights, very deep networks incur
only a finite, depth independent, delay in learning speed relative to shallow
networks. We show that, under certain conditions on the training data,
unsupervised pretraining can find this special class of initial conditions,
while scaled random Gaussian initializations cannot. We further exhibit a new
class of random orthogonal initial conditions on weights that, like
unsupervised pre-training, enjoys depth independent learning times. We further
show that these initial conditions also lead to faithful propagation of
gradients even in deep nonlinear networks, as long as they operate in a special
regime known as the edge of chaos.Comment: Submission to ICLR2014. Revised based on reviewer feedbac
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