Abstract
A spiking neural network model inspired by synaptic pruning is developed and trained to extract features of hand-written digits. The network is composed of three spiking neural layers and one output neuron whose firing rate is used for classification. The model detects and collects the geometric features of the images from the Modified National Institute of Standards and Technology database (MNIST). In this work, a novel learning rule is developed to train the network to detect features of different digit classes. For this purpose, randomly initialized synaptic weights between the first and second layers are updated using average firing rates of pre- and postsynaptic neurons. Then, using a neuroscience-inspired mechanism named, “synaptic pruning” and its predefined threshold values, some of the synapses are deleted. Hence, these sparse matrices named, “information channels” are constructed so that they show highly specific patterns for each digit class as connection matrices between the first and second layers. The “information channels” are used in the test phase to assign a digit class to each test image. In addition, the role of feed-back inhibition as well as the connectivity rates of the second and third neural layers are studied. Similar to the abilities of the humans to learn from small training trials, the developed spiking neural network needs a very small dataset for training, compared to the conventional deep learning methods that have shown a very good performance on the MNIST dataset. This work introduces a new class of brain-inspired spiking neural networks to extract the features of complex data images.
Highlights
The human brain has demonstrated amazing cognitive capabilities to learn and recognize complex visual patterns in noisy contexts (Kasabov, 2019; Langner et al, 2019)
Information processing in the human brain is performed via the activation of sensory neurons and subsequently sending the inputs into cortical neurons that lead to complex spiking patterns of neuronal populations to either make a decision or to store the information (Arce-McShane et al, 2018)
Biological neurons are composed of dendrites that take up the signals from other neurons, the soma that is involved in information processing, and the axon that passes on the generated action potential (AP) into the terminal synapses of the axon (Figure 1A)
Summary
The human brain has demonstrated amazing cognitive capabilities to learn and recognize complex visual patterns in noisy contexts (Kasabov, 2019; Langner et al, 2019). Cortical neurons are sparsely connected via dynamical synapses that can be weakened or strengthened (Waters and Helmchen, 2006; Seeman et al, 2018) by some mechanisms, such as activity-dependent or retrograde signaling from other neurons. Biological neurons are composed of dendrites that take up the signals from other neurons, the soma that is involved in information processing, and the axon that passes on the generated action potential (AP) into the terminal synapses of the axon (Figure 1A). Activityinduced retrograde messengers, as simple molecules or short peptides, are crucial for the formation of some synapses in some regions of the brain through learning and memory (Suvarna et al, 2016)
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