Picture for Christopher H. Bennett

Christopher H. Bennett

Analog fast Fourier transforms for scalable and efficient signal processing

Add code
Sep 27, 2024
Viaarxiv icon

Shape-Dependent Multi-Weight Magnetic Artificial Synapses for Neuromorphic Computing

Add code
Nov 22, 2021
Figure 1 for Shape-Dependent Multi-Weight Magnetic Artificial Synapses for Neuromorphic Computing
Figure 2 for Shape-Dependent Multi-Weight Magnetic Artificial Synapses for Neuromorphic Computing
Figure 3 for Shape-Dependent Multi-Weight Magnetic Artificial Synapses for Neuromorphic Computing
Figure 4 for Shape-Dependent Multi-Weight Magnetic Artificial Synapses for Neuromorphic Computing
Viaarxiv icon

On the Accuracy of Analog Neural Network Inference Accelerators

Add code
Sep 12, 2021
Figure 1 for On the Accuracy of Analog Neural Network Inference Accelerators
Figure 2 for On the Accuracy of Analog Neural Network Inference Accelerators
Figure 3 for On the Accuracy of Analog Neural Network Inference Accelerators
Figure 4 for On the Accuracy of Analog Neural Network Inference Accelerators
Viaarxiv icon

High-Speed CMOS-Free Purely Spintronic Asynchronous Recurrent Neural Network

Add code
Jul 05, 2021
Figure 1 for High-Speed CMOS-Free Purely Spintronic Asynchronous Recurrent Neural Network
Figure 2 for High-Speed CMOS-Free Purely Spintronic Asynchronous Recurrent Neural Network
Figure 3 for High-Speed CMOS-Free Purely Spintronic Asynchronous Recurrent Neural Network
Figure 4 for High-Speed CMOS-Free Purely Spintronic Asynchronous Recurrent Neural Network
Viaarxiv icon

Controllable reset behavior in domain wall-magnetic tunnel junction artificial neurons for task-adaptable computation

Add code
Jan 08, 2021
Figure 1 for Controllable reset behavior in domain wall-magnetic tunnel junction artificial neurons for task-adaptable computation
Figure 2 for Controllable reset behavior in domain wall-magnetic tunnel junction artificial neurons for task-adaptable computation
Figure 3 for Controllable reset behavior in domain wall-magnetic tunnel junction artificial neurons for task-adaptable computation
Figure 4 for Controllable reset behavior in domain wall-magnetic tunnel junction artificial neurons for task-adaptable computation
Viaarxiv icon

Domain Wall Leaky Integrate-and-Fire Neurons with Shape-Based Configurable Activation Functions

Add code
Nov 11, 2020
Figure 1 for Domain Wall Leaky Integrate-and-Fire Neurons with Shape-Based Configurable Activation Functions
Figure 2 for Domain Wall Leaky Integrate-and-Fire Neurons with Shape-Based Configurable Activation Functions
Figure 3 for Domain Wall Leaky Integrate-and-Fire Neurons with Shape-Based Configurable Activation Functions
Figure 4 for Domain Wall Leaky Integrate-and-Fire Neurons with Shape-Based Configurable Activation Functions
Viaarxiv icon

Device-aware inference operations in SONOS nonvolatile memory arrays

Add code
Apr 02, 2020
Figure 1 for Device-aware inference operations in SONOS nonvolatile memory arrays
Figure 2 for Device-aware inference operations in SONOS nonvolatile memory arrays
Figure 3 for Device-aware inference operations in SONOS nonvolatile memory arrays
Figure 4 for Device-aware inference operations in SONOS nonvolatile memory arrays
Viaarxiv icon

Unsupervised Competitive Hardware Learning Rule for Spintronic Clustering Architecture

Add code
Mar 24, 2020
Figure 1 for Unsupervised Competitive Hardware Learning Rule for Spintronic Clustering Architecture
Figure 2 for Unsupervised Competitive Hardware Learning Rule for Spintronic Clustering Architecture
Figure 3 for Unsupervised Competitive Hardware Learning Rule for Spintronic Clustering Architecture
Figure 4 for Unsupervised Competitive Hardware Learning Rule for Spintronic Clustering Architecture
Viaarxiv icon

Plasticity-Enhanced Domain-Wall MTJ Neural Networks for Energy-Efficient Online Learning

Add code
Mar 04, 2020
Figure 1 for Plasticity-Enhanced Domain-Wall MTJ Neural Networks for Energy-Efficient Online Learning
Figure 2 for Plasticity-Enhanced Domain-Wall MTJ Neural Networks for Energy-Efficient Online Learning
Figure 3 for Plasticity-Enhanced Domain-Wall MTJ Neural Networks for Energy-Efficient Online Learning
Figure 4 for Plasticity-Enhanced Domain-Wall MTJ Neural Networks for Energy-Efficient Online Learning
Viaarxiv icon

Evaluating complexity and resilience trade-offs in emerging memory inference machines

Add code
Feb 25, 2020
Figure 1 for Evaluating complexity and resilience trade-offs in emerging memory inference machines
Figure 2 for Evaluating complexity and resilience trade-offs in emerging memory inference machines
Figure 3 for Evaluating complexity and resilience trade-offs in emerging memory inference machines
Figure 4 for Evaluating complexity and resilience trade-offs in emerging memory inference machines
Viaarxiv icon