Mitigating effects of non-ideal synaptic device characteristics for on-chip learning

Chen, Pai-Yu; Lin, Binbin; Wang, I-Ting; Hou, Tuo‐Hung; Ye, Jieping; Vrudhula, Sarma; Seo, Jae-sun; Cao, Yu; Yu, Shimeng

doi:10.1109/iccad.2015.7372570

Cited by 217 publications

(223 citation statements)

References 17 publications

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“…When scaling up the array size, the non-ideal device properties and array parasitics may potentially degrade the learning accuracy [8]. The non-ideal properties of the realistic devices today include a finite weight precision, a nonlinearity in weight update (conductance vs. #pulse), limited on/off ratio and device variations, see device examples ( Fig.…”

Section: Non-ideal Device Properties and Array Parasiticsmentioning

confidence: 98%

Scaling-up resistive synaptic arrays for neuro-inspired architecture: Challenges and prospect

Chen

Cao

et al. 2015

2015 IEEE International Electron Devices Meeting (IEDM)

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The crossbar array architecture with resistive synaptic devices is attractive for on-chip implementation of weighted sum and weight update in the neuro-inspired learning algorithms. This paper discusses the design challenges on scaling up the array size due to non-ideal device properties and array parasitics. Circuit-level mitigation strategies have been proposed to minimize the learning accuracy loss in a large array. This paper also discusses the peripheral circuits design considerations for the neuro-inspired architecture. Finally, a circuit-level macro simulator is developed to explore the design trade-offs and evaluate the overhead of the proposed mitigation strategies as well as project the scaling trend of the neuroinspired architecture.

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Section: Non-ideal Device Properties and Array Parasiticsmentioning

confidence: 98%

Scaling-up resistive synaptic arrays for neuro-inspired architecture: Challenges and prospect

Chen

Cao

et al. 2015

2015 IEEE International Electron Devices Meeting (IEDM)

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113

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“…

Despite the possibility of tremendous gains in energy efficiency and numerous reports of resistance switching behavior in a range of materials systems, to date no memristor-based crossbar architecture has emerged as a clear competitor to CMOS or reached the energy efficiency of the brain. However, both device types currently suffer from several performance limitations that reduce their accuracy, scalability, and energy efficiency: excessive "write" noise, [16][17][18] "write" nonlinearities, [12,[19][20][21][22] and high switching voltages and currents. However, both device types currently suffer from several performance limitations that reduce their accuracy, scalability, and energy efficiency: excessive "write" noise, [16][17][18] "write" nonlinearities, [12,[19][20][21][22] and high switching voltages and currents.

…”

mentioning

confidence: 99%

“…For Figure 2b,e, G 0 spans the range of 150-250 µS for −4.1 < OCP < −3.0 V. Here, we have plotted 40 counts (black) at every starting conductance point G 0 in order to measure the probability distribution about the mean change in conductance ΔG M . [22] An ideal resistive memory device should have a narrow distribution that is centered about single value of ΔG M over the entire range in G 0 . [22] An ideal resistive memory device should have a narrow distribution that is centered about single value of ΔG M over the entire range in G 0 .…”

mentioning

confidence: 99%

Li‐Ion Synaptic Transistor for Low Power Analog Computing

et al. 2016

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Nonvolatile redox transistors (NVRTs) based upon Li-ion battery materials are demonstrated as memory elements for neuromorphic computer architectures with multi-level analog states, "write" linearity, low-voltage switching, and low power dissipation. Simulations of backpropagation using the device properties reach ideal classification accuracy. Physics-based simulations predict energy costs per "write" operation of <10 aJ when scaled to 200 nm × 200 nm.

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“…However, the RRAM device uniformity and the large overhead of training circuits remain major challenges. [72,77] Some theoretical memristor models reason that nonlinearity is natural and derivable; however, the nonideal linear update can be mitigated by relaxing the strong requirements of training. Here, the symmetric weight update (Figure 3a) denotes the scenario where identical electrical excites result in the same amount change in weight Δw, during both SET and RESET programming.…”

Section: Rram-based Designs In Trainingmentioning

confidence: 99%

“…[29,71] Considering the implementation complexity of training circuitry, the devices featuring linear and symmetric synaptic weight updates are more preferred. [72] For example, Chen et al presented the self-rectifying TaO x /TiO 2 RRAM, which is only %3% away from linearity during programming. The linear weight update means that the weight change Δw has linear dependency on the electrical excites, regardless of the current resistance state.…”

Section: Rram-based Designs In Trainingmentioning

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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Mitigating effects of non-ideal synaptic device characteristics for on-chip learning

Cited by 217 publications

References 17 publications

Scaling-up resistive synaptic arrays for neuro-inspired architecture: Challenges and prospect

Scaling-up resistive synaptic arrays for neuro-inspired architecture: Challenges and prospect

Li‐Ion Synaptic Transistor for Low Power Analog Computing

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

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