Screen LibraryNeuro-inspired Computing Using Resistive Synaptic Devices /
This book summarizes the recent breakthroughs in hardware implementation of neuro-inspired computing using resistive synaptic devices. The authors describe how two-terminal solid-state resistive memories can emulate synaptic weights in a neural network. Readers will benefit from state-of-the-art sum...
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| Published: |
Springer International Publishing : Imprint: Springer,
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| Publisher Address: | Cham : |
| Publication Dates: | 2017. |
| Literature type: | eBook |
| Language: | English |
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| Online Access: |
http://dx.doi.org/10.1007/978-3-319-54313-0 |
| Summary: |
This book summarizes the recent breakthroughs in hardware implementation of neuro-inspired computing using resistive synaptic devices. The authors describe how two-terminal solid-state resistive memories can emulate synaptic weights in a neural network. Readers will benefit from state-of-the-art summaries of resistive synaptic devices, from the individual cell characteristics to the large-scale array integration. This book also discusses peripheral neuron circuits design challenges and design strategies. Finally, the authors describe the impact of device non-ideal properties (e.g. noise, variation, yield) and their impact on the learning performance at the system-level, using a device-algorithm co-design methodology. Provides single-source reference to recent breakthroughs in resistive synaptic devices, not only at individual cell-level, but also at integrated array-level; Includes detailed discussion of the peripheral circuits and array architecture design of the neuro-crossbar system; Focuses on new experimental results that are likely to solve practical, artificial intelligent problems, such as image classification. |
| Carrier Form: | 1 online resource (XI, 269 pages): illustrations |
| ISBN: | 9783319543130 |
| Index Number: | TK7888 |
| CLC: | TP331 |
| Contents: | Chapter1: Introduction to Neuro-Inspired Computing using Resistive Synaptic Devices -- Part I: Device-level Demonstrations of Resistive Synaptic Devices -- Chapter2: Phase Change Memory based Synaptic Devices -- Chapter3: Pr0.7Ca0.3MnO3 (PCMO) based Synaptic Devices -- Chapter4: TaOx/TiO2 based Synaptic Devices -- Part II: Array-level Demonstrations of Resistive Synaptic Devices and Neural Networks -- Chapter5: Training and Inference in Hopfield Network using 10 10 Phase Change Synaptic Array -- Chapter6: Experimental Demonstration of Firing-Rate Neural Networks based on Metal-Oxide Memristive Crossbars -- Chapter7: Weight Tuning of Resistive Synaptic Devices and Convolution Kernel Operation on 12 12 Cross-Point Array -- Chapter8: Spiking Neural Network with 256 256 PCM Array -- Part III: Circuit, Architecture and Algorithm-level Design of Resistive Synaptic Devices based Neuromorphic System -- Chapter9: Peripheral Circuit Design Considerations of Neuro-inspired Architectures -- Chapter10: Processing-in-Memory Architecture Design for Accelerating Neuro-Inspired Algorithms -- Chapter11: Multi-layer Perceptron Algorithm: Impact of Non-Ideal Conductance and Area-Efficient Peripheral Circuits -- Chapter12: Impact of Non-Ideal Resistive Synaptic Device Behaviors on Implementation of Sparse Coding Algorithm -- Chapter13: Binary OxRAM/CBRAM Memories for Efficient Implementations of Embedded Neuromorphic Circuits. |