Eric Herbelin scite author profile

The tunability of conductance states of various emerging non-volatile memristive devices emulates the plasticity of biological synapses, making it promising in the hardware realization of large-scale neuromorphic systems. The inference of the neural network can be greatly accelerated by the vector-matrix multiplication (VMM) performed within a crossbar array of memristive devices in one step. Nevertheless, the implementation of the VMM needs complex peripheral circuits and the complexity further increases since non-idealities of memristive devices prevent precise conductance tuning (especially for the online training) and largely degrade the performance of the deep neural networks (DNNs). Here, we present an efficient online training method of the memristive deep belief net (DBN). The proposed memristive DBN uses stochastically binarized activations, reducing the complexity of peripheral circuits, and uses the contrastive divergence (CD) based gradient descent learning algorithm. The analog VMM and digital CD are performed separately in a mixed-signal hardware arrangement, making the memristive DBN high immune to non-idealities of synaptic devices. The number of write operations on memristive devices is reduced by two orders of magnitude. The recognition accuracy of 95%~97% can be achieved for the MNIST dataset using pulsed synaptic behaviors of various memristive synaptic devices.

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Physical based compact model of Y-Flash memristor for neuromorphic computation

Wang

Danial

Herbelin

et al. 2021

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Y-Flash memristors utilize the mature technology of single polysilicon floating gate non-volatile memories (NVM). It can be operated in a two-terminal configuration similar to the other emerging memristive devices, i.e., resistive random-access memory (RRAM), phase-change memory (PCM), etc. Fabricated in production complementary metal-oxide-semiconductor (CMOS) technology, Y-Flash memristors allow excellent reproducibility reflected in high neuromorphic products yields. Working in the subthreshold region, the device can be programmed to a large number of fine-tuned intermediate states in an analog fashion and allows low readout currents (1 nA ∼ 5 µA). However, currently, there are no accurate models to describe the dynamic switching in this type of memristive device and account for multiple operational configurations. In this paper, we provide a physical-based compact model that describes Y-Flash memristor performance both in DC and AC regimes, and consistently describes the dynamic program and erase operations. The model is integrated into the commercial circuit design tools and is ready to be used in applications related to neuromorphic computation.

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Supporting Information for "Efficient Training of the Memristive Deep Belief Net Immune to Non-Idealities of the Synaptic Devices"

Wang¹,

Hoffer²,

Greenberg-Toledo³

et al. 2022

Preprint

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Eric Herbelin

Two-terminal floating-gate transistors with a low-power memristive operation mode for analogue neuromorphic computing

A memristive deep belief neural network based on silicon synapses

Efficient Training of the Memristive Deep Belief Net Immune to Non‐Idealities of the Synaptic Devices

Physical based compact model of Y-Flash memristor for neuromorphic computation

Supporting Information for "Efficient Training of the Memristive Deep Belief Net Immune to Non-Idealities of the Synaptic Devices"

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