Spiking neural networks (SNN) are biologically plausible networks. Compared to formal neural networks, they come with huge benefits related to their asynchronous processing and massively parallel architecture. Recent developments in neuromorphics aim to implement these SNNs in hardware to fully exploit their potential in terms of low energy consumption. In this paper, the plasticity of a multi-state conductance synapse in SNN is shown. The synapse is a compound of multiple Magnetic Tunnel Junction (MTJ) devices connected in parallel. The network performs learning by potentiation and depression of the synapses. In this paper we show how these two mechanisms can be obtained in hardware-implemented SNNs. We present a methodology to achieve the Spike Timing Dependent Plasticity (STDP) learning rule in hardware by carefully engineering the post-and pre-synaptic signals. We demonstrate synaptic plasticity as a function of the relative spiking time of input and output neurons only.
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