Data-intensive computing operations, such as training neural networks, are essential for applications in artificial intelligence but are energy intensive. One solution is to develop specialized hardware onto which neural networks can be directly mapped, and arrays of memristive devices can, for example, be trained to enable parallel multiply–accumulate operations. Here we show that memcapacitive devices that exploit the principle of charge shielding can offer a highly energy-efficient approach for implementing parallel multiply–accumulate operations. We fabricate a crossbar array of 156 microscale memcapacitor devices and use it to train a neural network that could distinguish the letters ‘M’, ‘P’ and ‘I’. Modelling these arrays suggests th...
Power density constraint and device reliability issues are driving energy efficient, fault tolerant ...
The ongoing revolution in Deep Learning is redefining the nature of computing that is driven by the ...
Compact online learning architectures can be used to enhance internet of things devices, allowing th...
Data-intensive computing operations, such as training neural networks, are essential but energy-inte...
Memristive crossbar arrays promise substantial improvements in computing throughput and power effici...
Neuromorphic computing has emerged as a promising avenue towards building the next generation of int...
The memristor is a novel nano-scale device discovered in 2008. Memristors are basically nonvolatile ...
Neuromorphic engineering is the research field dedicated to the study and design of brain-inspired h...
Realization of the conventional Von Neumann architecture faces increasing challenges due to growing ...
While the speed-energy efficiency of traditional digital processors approach a plateau because of li...
Abstract The progress of artificial intelligence and the development of large‐scale neural networks ...
The use of interface-based resistive switching devices for neuromorphic computing is investigated. I...
The neural computation field had finally delivered on its promises in 2013 when the University of To...
Analog storage through synaptic weights using conductance in resistive neuromorphic systems and devi...
Deep Neural Networks (DNNs) have demonstrated fascinating performance in many real-world application...
Power density constraint and device reliability issues are driving energy efficient, fault tolerant ...
The ongoing revolution in Deep Learning is redefining the nature of computing that is driven by the ...
Compact online learning architectures can be used to enhance internet of things devices, allowing th...
Data-intensive computing operations, such as training neural networks, are essential but energy-inte...
Memristive crossbar arrays promise substantial improvements in computing throughput and power effici...
Neuromorphic computing has emerged as a promising avenue towards building the next generation of int...
The memristor is a novel nano-scale device discovered in 2008. Memristors are basically nonvolatile ...
Neuromorphic engineering is the research field dedicated to the study and design of brain-inspired h...
Realization of the conventional Von Neumann architecture faces increasing challenges due to growing ...
While the speed-energy efficiency of traditional digital processors approach a plateau because of li...
Abstract The progress of artificial intelligence and the development of large‐scale neural networks ...
The use of interface-based resistive switching devices for neuromorphic computing is investigated. I...
The neural computation field had finally delivered on its promises in 2013 when the University of To...
Analog storage through synaptic weights using conductance in resistive neuromorphic systems and devi...
Deep Neural Networks (DNNs) have demonstrated fascinating performance in many real-world application...
Power density constraint and device reliability issues are driving energy efficient, fault tolerant ...
The ongoing revolution in Deep Learning is redefining the nature of computing that is driven by the ...
Compact online learning architectures can be used to enhance internet of things devices, allowing th...