Processing systems are in continuous evolution thanks to the constant technological advancement and architectural progress. Over the years, computing systems have become more and more powerful, providing support for applications, such as Machine Learning, that require high computational power. However, the growing complexity of modern computing units and applications has had a strong impact on power consumption. In addition, the memory plays a key role on the overall power consumption of the system, especially when considering data-intensive applications. These applications, in fact, require a lot of data movement between the memory and the computing unit. The consequence is twofold: Memory accesses are expensive in terms of energy and a lo...
In-Memory Acceleration (IMA) promises major efficiency improvements in deep neural network (DNN) inf...
Nowadays, the modern electronic systems are facing an important limitation in terms of performance, ...
The speed of modern digital systems is severely limited by memory latency (the ``Memory Wall'' probl...
The current trend for intensive computational architectures is to adopt massive parallelism, with se...
While the compute part keeping scaling for decades, it becomes more and more difficult for the memor...
Most modern CPU architectures are based on the von Neumann principle, where memory and processing un...
For decades, innovations to surmount the processor versus memory gap and move beyond conventional vo...
Due to the physical separation of their processing elements and storage units, contemporary digital ...
With the rise in artificial intelligence (AI), computing systems are facing new challenges related t...
Many modern workloads, such as neural networks, databases, and graph processing, are fundamentally m...
Today's computing architectures and device technologies are unable to meet the increasingly stringen...
The successful era of CMOS technology is coming to an end. The limit on minimum fabrication dimensio...
Conventional Von Neumann machines inherently separate the processing units from the memory units. Th...
Over the past five decades, exponential advances in device integration in microelectronics for memor...
Developing energy-efficient parallel information processing systems beyond von Neumann architecture ...
In-Memory Acceleration (IMA) promises major efficiency improvements in deep neural network (DNN) inf...
Nowadays, the modern electronic systems are facing an important limitation in terms of performance, ...
The speed of modern digital systems is severely limited by memory latency (the ``Memory Wall'' probl...
The current trend for intensive computational architectures is to adopt massive parallelism, with se...
While the compute part keeping scaling for decades, it becomes more and more difficult for the memor...
Most modern CPU architectures are based on the von Neumann principle, where memory and processing un...
For decades, innovations to surmount the processor versus memory gap and move beyond conventional vo...
Due to the physical separation of their processing elements and storage units, contemporary digital ...
With the rise in artificial intelligence (AI), computing systems are facing new challenges related t...
Many modern workloads, such as neural networks, databases, and graph processing, are fundamentally m...
Today's computing architectures and device technologies are unable to meet the increasingly stringen...
The successful era of CMOS technology is coming to an end. The limit on minimum fabrication dimensio...
Conventional Von Neumann machines inherently separate the processing units from the memory units. Th...
Over the past five decades, exponential advances in device integration in microelectronics for memor...
Developing energy-efficient parallel information processing systems beyond von Neumann architecture ...
In-Memory Acceleration (IMA) promises major efficiency improvements in deep neural network (DNN) inf...
Nowadays, the modern electronic systems are facing an important limitation in terms of performance, ...
The speed of modern digital systems is severely limited by memory latency (the ``Memory Wall'' probl...