Ultrascale computing is a new computing paradigm that comes naturally from the necessity of computing systems that should be able to handle massive data in possibly very large scale distributed systems, enabling new forms of applications that can serve a very large amount of users and in a timely manner that we have never experienced before. However, besides the benefits, ultrascale computing systems do not come without challenges. One of the challenges is the resilience of ultrascale computing systems. Although resilience is already an established field in system science and many methodologies and approaches are available to deal with it, the unprecedented scales of computing, of the massive data to be managed, new network technologi...
Proceedings of: Third International Workshop on Sustainable Ultrascale Computing Systems (NESUS 2016...
High-Performance Computing (HPC) has passed the Petascale mark and is moving forward to Exascale. As...
To enable future scientific breakthroughs and discoveries, the next generation of scientific applica...
Ultrascale computing is a new computing paradigm that comes naturally from the necessity of computin...
Ultrascale Computing Systems (UCSs) are envisioned as large-scale complex systems joining parallel a...
Proceedings of the First PhD Symposium on Sustainable Ultrascale Computing Systems (NESUS PhD 2016)...
This work is based on the seminar titled ‘Resiliency in Numerical Algorithm Design for Extreme Scale...
We present here a report produced by a workshop on ‘Addressing failures in exascale computing’ held ...
Nanoscale technology nodes bring reliability concerns back to the center stage of digital system des...
This book presents important results and methods towards achieving sustainable ultrascale computing ...
Projections and reports about exascale failure modes conclude that we need to protect numerical simu...
Extreme scale parallel computing systems will have tens of thousands of optionally accelerator-equip...
The path to exascale poses several challenges related to power, performance, resilience, productivit...
Projections and reports about exascale failure modes conclude that we need to protect numerical simu...
Proceedings of: Third International Workshop on Sustainable Ultrascale Computing Systems (NESUS 2016...
High-Performance Computing (HPC) has passed the Petascale mark and is moving forward to Exascale. As...
To enable future scientific breakthroughs and discoveries, the next generation of scientific applica...
Ultrascale computing is a new computing paradigm that comes naturally from the necessity of computin...
Ultrascale Computing Systems (UCSs) are envisioned as large-scale complex systems joining parallel a...
Proceedings of the First PhD Symposium on Sustainable Ultrascale Computing Systems (NESUS PhD 2016)...
This work is based on the seminar titled ‘Resiliency in Numerical Algorithm Design for Extreme Scale...
We present here a report produced by a workshop on ‘Addressing failures in exascale computing’ held ...
Nanoscale technology nodes bring reliability concerns back to the center stage of digital system des...
This book presents important results and methods towards achieving sustainable ultrascale computing ...
Projections and reports about exascale failure modes conclude that we need to protect numerical simu...
Extreme scale parallel computing systems will have tens of thousands of optionally accelerator-equip...
The path to exascale poses several challenges related to power, performance, resilience, productivit...
Projections and reports about exascale failure modes conclude that we need to protect numerical simu...
Proceedings of: Third International Workshop on Sustainable Ultrascale Computing Systems (NESUS 2016...
High-Performance Computing (HPC) has passed the Petascale mark and is moving forward to Exascale. As...
To enable future scientific breakthroughs and discoveries, the next generation of scientific applica...