Single pairing spike-timing dependent plasticity in BiFeO3 memristors with a time window of 25 ms to 125 μs

Memristive devices are popular among neuromorphic engineers for their ability to emulate forms of spike-driven synaptic plasticity by applying specific voltage and current waveforms at their two terminals. In this paper, we investigate spike-timing dependent plasticity (STDP) with a single pairing o...

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Bibliographic Details
Published in:Frontiers in neuroscience 2015-06, Vol.9, p.227-227
Main Authors: Du, Nan, Kiani, Mahdi, Mayr, Christian G, You, Tiangui, Bürger, Danilo, Skorupa, Ilona, Schmidt, Oliver G, Schmidt, Heidemarie
Format: Article
Language:English
Subjects:
Electrodes
Energy consumption
Firing pattern
Memory
Neurons
Neuroscience
Presynaptic plasticity
Synaptic plasticity
Thin films
Voltage
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Summary:Memristive devices are popular among neuromorphic engineers for their ability to emulate forms of spike-driven synaptic plasticity by applying specific voltage and current waveforms at their two terminals. In this paper, we investigate spike-timing dependent plasticity (STDP) with a single pairing of one presynaptic voltage spike and one post-synaptic voltage spike in a BiFeO3 memristive device. In most memristive materials the learning window is primarily a function of the material characteristics and not of the applied waveform. In contrast, we show that the analog resistive switching of the developed artificial synapses allows to adjust the learning time constant of the STDP function from 25 ms to 125 μs via the duration of applied voltage spikes. Also, as the induced weight change may degrade, we investigate the remanence of the resistance change for several hours after analog resistive switching, thus emulating the processes expected in biological synapses. As the power consumption is a major constraint in neuromorphic circuits, we show methods to reduce the consumed energy per setting pulse to only 4.5 pJ in the developed artificial synapses.
ISSN:1662-4548
1662-453X
1662-453X
DOI:10.3389/fnins.2015.00227