In 1967 Amdahl expressed doubts about the ultimate utility of multiprocessors. The formulation, now called Amdahl's law, became part of the computing folklore and has inspired much skepticism about the ability of the current generation of massively parallel processors to efficiently deliver all their computing power to programs. The widely publicized recent results of a group at Sandia National Laboratory, which showed speedup on a 1024 node hypercube of over 500 for three fixed size problems and over 1000 for three scalable problems, have convincingly challenged this bit of folklore and have given new impetus to parallel scientific computing
A popular argument, generally attributed to Amdahl [1], is that vector and parallel architectures sh...
Goodyear Aerospace delivered the Massively Parallel Processor (MPP) to NASA/Goddard in May 1983, ove...
The best enterprises have both a compelling need pulling them forward and an innovative technologica...
At Sandia National Laboratories, we are currently en-gaged in research involving massively parallel ...
An important issue in the effective use of parallel processing is the estimation of the speed-up one...
Amdahl\u27s Law states that speedup in moving from one processor to N identical processors can never...
Amdahl's Law states that speedup in moving from one processor to N identical processors can nev...
Using Amdahl’s law as a metric, the authors illustrate a technique for developing efficient code on ...
In this paper three models of parallel speedup are studied. They are fixed-size speedup, fixed-time ...
The problem of learning parallel computer performance is investigated in the context of multicore pr...
Highly parallel computing architectures are the only means to achieve the computation rates demanded...
We apply Amdahl's Law to multicore chips using symmetric cores, asymmetric cores, and dynamic techni...
To run a software application on a large number of parallel processors, N, and expect to obtain spee...
This paper studies the speedup for multi-level parallel computing. Two models of parallel speedup ar...
In this article we review the evolution of supercomputers from vector supercomputers to massively pa...
A popular argument, generally attributed to Amdahl [1], is that vector and parallel architectures sh...
Goodyear Aerospace delivered the Massively Parallel Processor (MPP) to NASA/Goddard in May 1983, ove...
The best enterprises have both a compelling need pulling them forward and an innovative technologica...
At Sandia National Laboratories, we are currently en-gaged in research involving massively parallel ...
An important issue in the effective use of parallel processing is the estimation of the speed-up one...
Amdahl\u27s Law states that speedup in moving from one processor to N identical processors can never...
Amdahl's Law states that speedup in moving from one processor to N identical processors can nev...
Using Amdahl’s law as a metric, the authors illustrate a technique for developing efficient code on ...
In this paper three models of parallel speedup are studied. They are fixed-size speedup, fixed-time ...
The problem of learning parallel computer performance is investigated in the context of multicore pr...
Highly parallel computing architectures are the only means to achieve the computation rates demanded...
We apply Amdahl's Law to multicore chips using symmetric cores, asymmetric cores, and dynamic techni...
To run a software application on a large number of parallel processors, N, and expect to obtain spee...
This paper studies the speedup for multi-level parallel computing. Two models of parallel speedup ar...
In this article we review the evolution of supercomputers from vector supercomputers to massively pa...
A popular argument, generally attributed to Amdahl [1], is that vector and parallel architectures sh...
Goodyear Aerospace delivered the Massively Parallel Processor (MPP) to NASA/Goddard in May 1983, ove...
The best enterprises have both a compelling need pulling them forward and an innovative technologica...