A multiply-add engine with monolithically integrated 3D memristor crossbar/CMOS hybrid circuit

Chakrabarti, Bhaswar; Lastras-Montaño, Miguel Angel; Adam, Gina C.; Prezioso, M.; Hoskins, Brian D.; Payvand, Melika; Madhavan, Advait; Ghofrani, Amirali; Theogarajan, Luke; Cheng, Kwang-Ting; Strukov, Dmitri B.

doi:10.1038/srep42429

Cited by 73 publications

(60 citation statements)

References 32 publications

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“…Recently, pulse width, instead of amplitude, was used to represent the analogue input signals [27][28][29][30] , but this scheme requires more readout time and more complicated integrated circuits. Previous experimental demonstrations of an analogue-voltage-amplitude-vector by analogue-conductancematrix product, to the best of our knowledge, have been limited to a 1 × 3 system [24][25][26] , which is not strictly a VMM implementation. Here, we report completely analogue VMMs with adequate accuracy and high speed-energy efficiency that are based on up to 128 × 64 crossbars of hafnium oxide (HfO 2 ) memristors 36 , and experimentally demonstrate the important IoT and network edge applications of signal spectrum analysis, image compression and convolutional filtering.…”

mentioning

confidence: 99%

Analogue signal and image processing with large memristor crossbars

et al. 2017

Nat Electron

1,037

753

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mentioning

confidence: 99%

Analogue signal and image processing with large memristor crossbars

et al. 2017

Nat Electron

1,037

753

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“…Micromachines 2020, 11, 427 2 of 10 memristor-based in-memory computation was comparable to that of the complementary metaloxide-semiconductor (CMOS) platforms [22,23]. Shrinking the dimension of the conductive filaments (CFs) into the atomic scale of quantum point contact allows memristor ballistic electron transport without scattering and quantized conductance (QC) characteristics in analog domains [24][25][26]. It not only significantly increases the data storage capacity of the devices, but also allows stronger information processing ability in neuromorphic systems.…”

Section: Methodsmentioning

confidence: 99%

Improving the Recognition Accuracy of Memristive Neural Networks via Homogenized Analog Type Conductance Quantization

et al. 2020

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Conductance quantization (QC) phenomena occurring in metal oxide based memristors demonstrate great potential for high-density data storage through multilevel switching, and analog synaptic weight update for effective training of the artificial neural networks. Continuous, linear and symmetrical modulation of the device conductance is a critical issue in QC behavior of memristors. In this contribution, we employ the scanning probe microscope (SPM) assisted electrode engineering strategy to control the ion migration process to construct single conductive filaments in Pt/HfOx/Pt devices. Upon deliberate tuning and evolution of the filament, 32 half integer quantized conductance states in the 16 G0 to 0.5 G0 range with enhanced distribution uniformity was achieved. Simulation results revealed that the numbers of the available QC states and fluctuation of the conductance at each state play an important role in determining the overall performance of the neural networks. The 32-state QC behavior of the hafnium oxide device shows improved recognition accuracy approaching 90% for handwritten digits, based on analog type operation of the multilayer perception (MLP) neural network.

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“…[38,89,91] The new concept of the 3D synapse also has emerged, using the multiple layer of 3D RRAM arrays to store the synaptic weights and conduct matrix multiplication. [38,89,91] The new concept of the 3D synapse also has emerged, using the multiple layer of 3D RRAM arrays to store the synaptic weights and conduct matrix multiplication.…”

Section: D Stacking For Scalabilitymentioning

confidence: 99%

Resistive Memory‐Based In‐Memory Computing: From Device and Large‐Scale Integration System Perspectives

Yan

Qiao

et al. 2019

Advanced Intelligent Systems

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In‐memory computing is a computing scheme that integrates data storage and arithmetic computation functions. Resistive random access memory (RRAM) arrays with innovative peripheral circuitry provide the capability of performing vector‐matrix multiplication beyond the basic Boolean logic. With such a memory–computation duality, RRAM‐based in‐memory computing enables an efficient hardware solution for matrix‐multiplication‐dependent neural networks and related applications. Herein, the recent development of RRAM nanoscale devices and the parallel progress on circuit and microarchitecture layers are discussed. Well suited for analog synapse and neuron implementation, RRAM device properties and characteristics are emphasized herein. 3D‐stackable RRAM and on‐chip training are introduced in large‐scale integration. The circuit design and system organization of RRAM‐based in‐memory computing are essential to breaking the von Neumann bottleneck. These outcomes illuminate the way for the large‐scale implementation of ultra‐low‐power and dense neural network accelerators.

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A multiply-add engine with monolithically integrated 3D memristor crossbar/CMOS hybrid circuit

Cited by 73 publications

References 32 publications

Analogue signal and image processing with large memristor crossbars

Analogue signal and image processing with large memristor crossbars

Improving the Recognition Accuracy of Memristive Neural Networks via Homogenized Analog Type Conductance Quantization

Resistive Memory‐Based In‐Memory Computing: From Device and Large‐Scale Integration System Perspectives

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