Abstract
One of the biggest struggles while working with artificial neural networks is being able to come up with models which closely match biological observations. Biological neural networks seem to capable of creating and pruning dendritic spines, leading to synapses being changed, which results in higher learning capability. The latter forms the basis of the present study in which a new ionic model for reservoir-like networks, consisting of spiking neurons, is introduced. High plasticity of this model makes learning possible with a fewer number of neurons. In order to study the effect of the applied stimulus in an ionic liquid space through time, a diffusion operator is used which somehow compensates for the separation between spatial and temporal coding in spiking neural networks and therefore, makes the mentioned model suitable for spatiotemporal patterns. Inspired by partial structural changes in the human brain over the years, the proposed model evolves during the learning process. The effect of topological evolution on the proposed model's performance for some classification problems is studied in this paper. Several datasets have been used to evaluate the performance of the proposed model compared to the original LSM. Classification results via separation and accuracy values have shown that the proposed ionic liquid outperforms the original LSM.
Highlights
IntroductionAn area of computer science, AI is one of the most developed scientific fields which has brought so much attention to itself over the past few years
Artificial Intelligence, known as AI, is intelligence demonstrated by machines
Optimized ionic liquid is compared to the original Liquid State Machines (LSM) via separation and classification accuracy considering the same readout learning rule
Summary
An area of computer science, AI is one of the most developed scientific fields which has brought so much attention to itself over the past few years. Despite the remarkable development of AI systems over the past few years, designing a system which holds the capabilities of the human brain seems rather hard to achieve. Many AI-based computational systems have been developed so far; yet, none of them can compare to the processing mechanism of the human brain. Designing intelligent systems with the ability to carry out computations similar to the way the human brain does, is studied in the fields of neural networks and fuzzy systems. Despite the development of precise brain models (Markram, 2006; Toga et al, 2006; Izhikevich and Edelman, 2008), the available models cannot be used for machine learning and or recognizing
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