The ultimate computers in our long-term future will deliver exaflops-scale performance (or greater) and will look very different from today’s micro-processors and massively parallel computers. Ironically, however, their alien structures and operational behavior can be inferred from the same technology trends driving development of today’s conventional computing systems
This report investigates the transition of applications from multi-petascale to exascale performance...
A rapid convergence of computer technologies from two historically disparate markets may dramaticall...
In this article we review the evolution of supercomputers from vector supercomputers to massively pa...
The ultimate computers in our long-term future will deliver exaflops-scale performance (or greater) ...
The end of Moore's Law is a cliche that none the less is a hard barrier to future scaling of high pe...
Developement of computer architecture is discussed in terms of the proliferation of the microprocess...
The evolution of supercomputing architectures and technologies towardsexascale is dictated by constr...
Computer architectures have now moved into the multi-core era, with projections pointing to commodit...
already exist and run on Petascale class Supercomputers [1]. Modelers, programmers, and computer arc...
The anticipated advent of practical nanoscale technology sometime in the next decade with likely exp...
From the Foreword: “The authors of the chapters in this book are the pioneers who will explore the e...
Developing a computer system that can deliver sustained Exaflop performance is an extremely difficul...
The US, Europe, Japan and China are racing to develop the next generation of supercomputers – exasca...
Continuum computer architecture (CCA) is a non-von Neumann architecture that offers an alternative t...
David Keyes, Dean of Mathematical and Computer Sciences and Engineering and a Professor of Applied M...
This report investigates the transition of applications from multi-petascale to exascale performance...
A rapid convergence of computer technologies from two historically disparate markets may dramaticall...
In this article we review the evolution of supercomputers from vector supercomputers to massively pa...
The ultimate computers in our long-term future will deliver exaflops-scale performance (or greater) ...
The end of Moore's Law is a cliche that none the less is a hard barrier to future scaling of high pe...
Developement of computer architecture is discussed in terms of the proliferation of the microprocess...
The evolution of supercomputing architectures and technologies towardsexascale is dictated by constr...
Computer architectures have now moved into the multi-core era, with projections pointing to commodit...
already exist and run on Petascale class Supercomputers [1]. Modelers, programmers, and computer arc...
The anticipated advent of practical nanoscale technology sometime in the next decade with likely exp...
From the Foreword: “The authors of the chapters in this book are the pioneers who will explore the e...
Developing a computer system that can deliver sustained Exaflop performance is an extremely difficul...
The US, Europe, Japan and China are racing to develop the next generation of supercomputers – exasca...
Continuum computer architecture (CCA) is a non-von Neumann architecture that offers an alternative t...
David Keyes, Dean of Mathematical and Computer Sciences and Engineering and a Professor of Applied M...
This report investigates the transition of applications from multi-petascale to exascale performance...
A rapid convergence of computer technologies from two historically disparate markets may dramaticall...
In this article we review the evolution of supercomputers from vector supercomputers to massively pa...