Kiruthika Ramanathan scite author profile

Kiruthika Ramanathan

3Publications

99Citation Statements Received

84Citation Statements Given

How they've been cited

102

How they cite others

137

Affiliations

Data Storage Institute, Agency for Science, Technology and Research, National University of Singapore

Publications

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Enabling an Integrated Rate-temporal Learning Scheme on Memristor

Huang

Ning

et al. 2014

Sci Rep

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Learning scheme is the key to the utilization of spike-based computation and the emulation of neural/synaptic behaviors toward realization of cognition. The biological observations reveal an integrated spike time- and spike rate-dependent plasticity as a function of presynaptic firing frequency. However, this integrated rate-temporal learning scheme has not been realized on any nano devices. In this paper, such scheme is successfully demonstrated on a memristor. Great robustness against the spiking rate fluctuation is achieved by waveform engineering with the aid of good analog properties exhibited by the iron oxide-based memristor. The spike-time-dependence plasticity (STDP) occurs at moderate presynaptic firing frequencies and spike-rate-dependence plasticity (SRDP) dominates other regions. This demonstration provides a novel approach in neural coding implementation, which facilitates the development of bio-inspired computing systems.

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Presynaptic Learning and Memory With a Persistent Firing Neuron and a Habituating Synapse: A Model of Short Term Persistent Habituation

Ramanathan

Ning

Dhanasekar

et al. 2012

Int. J. Neur. Syst.

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Our paper explores the interaction of persistent firing axonal and presynaptic processes in the generation of short term memory for habituation. We first propose a model of a sensory neuron whose axon is able to switch between passive conduction and persistent firing states, thereby triggering short term retention to the stimulus. Then we propose a model of a habituating synapse and explore all nine of the behavioral characteristics of short term habituation in a two neuron circuit. We couple the persistent firing neuron to the habituation synapse and investigate the behavior of short term retention of habituating response. Simulations show that, depending on the amount of synaptic resources, persistent firing either results in continued habituation or maintains the response, both leading to longer recovery times. The effectiveness of the model as an element in a bio-inspired memory system is discussed.

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Behind the Magical Numbers: Hierarchical Chunking and the Human Working Memory Capacity

Ning

Ramanathan

et al. 2013

Int. J. Neur. Syst.

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To explore the influence of chunking on the capacity limits of working memory, a model for chunking in sequential working memory is proposed, using hierarchical bidirectional inhibition-connected neural networks with winnerless competition. With the assumption of the existence of an upper bound to the inhibitory weights in neurobiological networks, it is shown that chunking increases the number of memorized items in working memory from the "magical number 7" to 16 items. The optimal number of chunks and the number of the memorized items in each chunk are the "magical number 4".

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