Inexact hardware design, which advocates trading the accuracy of computations in exchange for significant savings in area, power and/or performance of computing hardware, has received increasing prominence in several error-tolerant application domains, particularly those involving perceptual or statistical end-users. In this paper, we evaluate inexact hardware for its applicability in weather and climate modelling. We expand previous studies on inexact techniques, in particular probabilistic pruning, to floating point arithmetic units and derive several simulated set-ups of pruned hardware with reasonable levels of error for applications in atmospheric modelling. The set-up is tested on the Lorenz '96 model, a toy model for atmospheric dyna...
Progress towards more reliable weather and climate forecasts is limited by the resolution of numeric...
Enabling Earth System models to run efficiently on future supercomputers is a serious challenge for ...
Motivated by the increasing energy consumption of supercomputing for weather and climate simulations...
Inexact hardware design, which advocates trading the accuracy of computations in exchange for signif...
A reduction of computational cost would allow higher resolution in numerical weather predictions wit...
AbstractThe use of stochastic processing hardware and low precision arithmetic in atmospheric models...
The use of stochastic processing hardware and low precision arithmetic in atmospheric models is inve...
Accurate forecasts of weather and climate will become increasingly important as the world adapts to ...
Increasing the resolution of numerical models has played a large part in improving the accuracy of w...
Reconfigurable architectures are becoming mainstream: Amazon, Microsoft and IBM are supporting such ...
One contribution of 14 to a Theme Issue ‘Stochastic modelling and energy-efficient computing for wea...
The use of reduced numerical precision to reduce computing costs for the cloud resolving model of su...
Better weather and climate forecasts are needed to maximise the ability of societies worldwide to pr...
Programmable hardware, in particular Field Programmable Gate Arrays (FPGAs), promises a significant ...
© 2015 IEEE.The computationally intensive nature of atmospheric modelling is an ideal target for har...
Progress towards more reliable weather and climate forecasts is limited by the resolution of numeric...
Enabling Earth System models to run efficiently on future supercomputers is a serious challenge for ...
Motivated by the increasing energy consumption of supercomputing for weather and climate simulations...
Inexact hardware design, which advocates trading the accuracy of computations in exchange for signif...
A reduction of computational cost would allow higher resolution in numerical weather predictions wit...
AbstractThe use of stochastic processing hardware and low precision arithmetic in atmospheric models...
The use of stochastic processing hardware and low precision arithmetic in atmospheric models is inve...
Accurate forecasts of weather and climate will become increasingly important as the world adapts to ...
Increasing the resolution of numerical models has played a large part in improving the accuracy of w...
Reconfigurable architectures are becoming mainstream: Amazon, Microsoft and IBM are supporting such ...
One contribution of 14 to a Theme Issue ‘Stochastic modelling and energy-efficient computing for wea...
The use of reduced numerical precision to reduce computing costs for the cloud resolving model of su...
Better weather and climate forecasts are needed to maximise the ability of societies worldwide to pr...
Programmable hardware, in particular Field Programmable Gate Arrays (FPGAs), promises a significant ...
© 2015 IEEE.The computationally intensive nature of atmospheric modelling is an ideal target for har...
Progress towards more reliable weather and climate forecasts is limited by the resolution of numeric...
Enabling Earth System models to run efficiently on future supercomputers is a serious challenge for ...
Motivated by the increasing energy consumption of supercomputing for weather and climate simulations...