Coverart for item
The Resource Advances in neuromorphic hardware exploiting emerging nanoscale devices, Manan Suri, editor, (electronic book)

Advances in neuromorphic hardware exploiting emerging nanoscale devices, Manan Suri, editor, (electronic book)

Label
Advances in neuromorphic hardware exploiting emerging nanoscale devices
Title
Advances in neuromorphic hardware exploiting emerging nanoscale devices
Statement of responsibility
Manan Suri, editor
Contributor
Editor
Subject
Language
eng
Summary
This book covers all major aspects of cutting-edge research in the field of neuromorphic hardware engineering involving emerging nanoscale devices. Special emphasis is given to leading works in hybrid low-power CMOS-Nanodevice design. The book offers readers a bidirectional (top-down and bottom-up) perspective on designing efficient bio-inspired hardware. At the nanodevice level, it focuses on various flavors of emerging resistive memory (RRAM) technology. At the algorithm level, it addresses optimized implementations of supervised and stochastic learning paradigms such as: spike-time-dependent plasticity (STDP), long-term potentiation (LTP), long-term depression (LTD), extreme learning machines (ELM) and early adoptions of restricted Boltzmann machines (RBM) to name a few. The contributions discuss system-level power/energy/parasitic trade-offs, and complex real-world applications. The book is suited for both advanced researchers and students interested in the field
Member of
Cataloging source
EBLCP
Dewey number
  • 006.3/2
  • 620
Index
no index present
LC call number
  • QA76.87
  • TA1-2040
Literary form
non fiction
Nature of contents
dictionaries
http://library.link/vocab/relatedWorkOrContributorName
Suri, Manan
Series statement
Cognitive Systems Monographs
Series volume
v. 31
http://library.link/vocab/subjectName
  • Neural networks (Computer science)
  • Computer architecture
  • Analog CMOS integrated circuits
Label
Advances in neuromorphic hardware exploiting emerging nanoscale devices, Manan Suri, editor, (electronic book)
Instantiates
Publication
Note
Novel Biomimetic Si Devices for Neuromorphic Computing Architecture
Antecedent source
file reproduced from an electronic resource
Bibliography note
ReferencesReinterpretation of Magnetic Tunnel Junctions as Stochastic Memristive Devices; 1 Introduction; 2 Magnetic Tunnel Junction Basics; 2.1 Basic Structure of Magnetic Tunnel Junctions; 2.2 Integration and Scaling Potential of STT-MTJs; 2.3 Physical Modeling of Magnetization Dynamics; 2.4 Models About the Statistics of MTJs Switching Delay; 3 MTJs as Stochastic Synapses; 3.1 Example of a Feed-Forward Spiking Neural Network Using MTJ-based Synapses; 3.2 Impact of the Device Properties on the System Operation; 4 Conclusion; References
Carrier category
online resource
Carrier category code
cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
txt
Content type MARC source
rdacontent
Contents
  • Preface; Contents; Dr. Manan Suri; Hardware Spiking Artificial Neurons, Their Response Function, and Noises; 1 Introduction; 1.1 Biological Neurons; 1.2 Neuronal Response Function; 1.3 Neuronal Noises; 1.4 Artificial Neuron Models; 2 Hardware Spiking Neurons; 2.1 Silicon Neurons; 2.2 Emerging Spiking Neurons; 3 Summary and Outlook; References; Synaptic Plasticity with Memristive Nanodevices; 1 Introduction; 2 Neuromorphic Systems: Basic Processing and Data Representation; 2.1 Data Encoding in Neuromorphic Systems; 2.2 Spike Computing for Neuromorphic Systems
  • 3 Synaptic Plasticity for Information Computing3.1 Causal Approach: Synaptic Learning Versus Synaptic Adaptation; 3.2 Phenomenological Approach: Short-Term Plasticity Versus Long-Term Plasticity; 4 Synaptic Plasticity Implementation in Neuromorphic Nanodevices; 4.1 Causal Implementation of Synaptic Plasticity; 4.2 Phenomenological Implementation of Synaptic Plasticity; 5 Conclusions; References; Neuromemristive Systems: A Circuit Design Perspective; 1 Introduction: Taking a Cue from Nature; 2 Memristor Overview; 3 Voltage Versus Current-Mode Circuit Designs for NMSs
  • 4 Neuron Circuits: Primary Information Processing Units4.1 Input Stage; 4.2 Activation Function; 5 Synapse Circuits: Communication and Memory; 6 Plasticity Circuits: Adaptation/Learning; 7 Summary and Outlook; References; Memristor-Based Platforms: A Comparison Between Continous-Time and Discrete-Time Cellular Neural Networks; 1 Introduction; 2 Backgorund; 3 New Memristance Restoring Circuit; 4 Simulation Results; 5 Cellular Automata and DTCNNs; 6 Belief Propagation Inspired Algorithm and Cellular Automaton Equivalence for RGB Image Processing; 7 Element Detection in RGB Image; 8 Conclusions
  • Multiple Binary OxRAMs as Synapses for Convolutional Neural Networks1 Multiple Binary OxRAM Devices as Artificial Synapses; 2 Convolutional Neural Network Architecture; 3 Synaptic Weight Resolution and Tolerance to Variability; 4 Conclusions; References; Nonvolatile Memory Crossbar Arrays for Non-von Neumann Computing; 1 Introduction; 2 Considerations for a Crossbar Implementation; 3 Phase-Change Memory (PCM): Results; 3.1 Experimental Results; 4 Non-filamentary RRAM Results; 4.1 Fabrication of PCMO Devices; 4.2 Simulation Results; 5 Discussion; 6 Conclusions; References
Dimensions
unknown
Extent
1 online resource (216 pages).
File format
one file format
Form of item
online
Isbn
9788132237013
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
c
Other control number
10.1007/978-81-322-3703-7
Quality assurance targets
unknown
Reformatting quality
unknown
Specific material designation
remote
System control number
ocn970631429
Label
Advances in neuromorphic hardware exploiting emerging nanoscale devices, Manan Suri, editor, (electronic book)
Publication
Note
Novel Biomimetic Si Devices for Neuromorphic Computing Architecture
Antecedent source
file reproduced from an electronic resource
Bibliography note
ReferencesReinterpretation of Magnetic Tunnel Junctions as Stochastic Memristive Devices; 1 Introduction; 2 Magnetic Tunnel Junction Basics; 2.1 Basic Structure of Magnetic Tunnel Junctions; 2.2 Integration and Scaling Potential of STT-MTJs; 2.3 Physical Modeling of Magnetization Dynamics; 2.4 Models About the Statistics of MTJs Switching Delay; 3 MTJs as Stochastic Synapses; 3.1 Example of a Feed-Forward Spiking Neural Network Using MTJ-based Synapses; 3.2 Impact of the Device Properties on the System Operation; 4 Conclusion; References
Carrier category
online resource
Carrier category code
cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
txt
Content type MARC source
rdacontent
Contents
  • Preface; Contents; Dr. Manan Suri; Hardware Spiking Artificial Neurons, Their Response Function, and Noises; 1 Introduction; 1.1 Biological Neurons; 1.2 Neuronal Response Function; 1.3 Neuronal Noises; 1.4 Artificial Neuron Models; 2 Hardware Spiking Neurons; 2.1 Silicon Neurons; 2.2 Emerging Spiking Neurons; 3 Summary and Outlook; References; Synaptic Plasticity with Memristive Nanodevices; 1 Introduction; 2 Neuromorphic Systems: Basic Processing and Data Representation; 2.1 Data Encoding in Neuromorphic Systems; 2.2 Spike Computing for Neuromorphic Systems
  • 3 Synaptic Plasticity for Information Computing3.1 Causal Approach: Synaptic Learning Versus Synaptic Adaptation; 3.2 Phenomenological Approach: Short-Term Plasticity Versus Long-Term Plasticity; 4 Synaptic Plasticity Implementation in Neuromorphic Nanodevices; 4.1 Causal Implementation of Synaptic Plasticity; 4.2 Phenomenological Implementation of Synaptic Plasticity; 5 Conclusions; References; Neuromemristive Systems: A Circuit Design Perspective; 1 Introduction: Taking a Cue from Nature; 2 Memristor Overview; 3 Voltage Versus Current-Mode Circuit Designs for NMSs
  • 4 Neuron Circuits: Primary Information Processing Units4.1 Input Stage; 4.2 Activation Function; 5 Synapse Circuits: Communication and Memory; 6 Plasticity Circuits: Adaptation/Learning; 7 Summary and Outlook; References; Memristor-Based Platforms: A Comparison Between Continous-Time and Discrete-Time Cellular Neural Networks; 1 Introduction; 2 Backgorund; 3 New Memristance Restoring Circuit; 4 Simulation Results; 5 Cellular Automata and DTCNNs; 6 Belief Propagation Inspired Algorithm and Cellular Automaton Equivalence for RGB Image Processing; 7 Element Detection in RGB Image; 8 Conclusions
  • Multiple Binary OxRAMs as Synapses for Convolutional Neural Networks1 Multiple Binary OxRAM Devices as Artificial Synapses; 2 Convolutional Neural Network Architecture; 3 Synaptic Weight Resolution and Tolerance to Variability; 4 Conclusions; References; Nonvolatile Memory Crossbar Arrays for Non-von Neumann Computing; 1 Introduction; 2 Considerations for a Crossbar Implementation; 3 Phase-Change Memory (PCM): Results; 3.1 Experimental Results; 4 Non-filamentary RRAM Results; 4.1 Fabrication of PCMO Devices; 4.2 Simulation Results; 5 Discussion; 6 Conclusions; References
Dimensions
unknown
Extent
1 online resource (216 pages).
File format
one file format
Form of item
online
Isbn
9788132237013
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
c
Other control number
10.1007/978-81-322-3703-7
Quality assurance targets
unknown
Reformatting quality
unknown
Specific material designation
remote
System control number
ocn970631429

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