The idea is considered that architectures for massively parallel computers must be designed to go beyond supporting a particular class of algorithms to supporting the underlying physical processes being modelled. Physical processes modelled by partial differential equations (PDEs) are discussed. Also discussed is the idea that an efficient architecture must go beyond nearest neighbor mesh interconnections and support global and hierarchical communications
The evolution of parallel processing over the past several decades can be viewed as the development ...
This paper describes the use of a parallel computer system in applying a finite difference method to...
The communication and synchronization overhead inherent in parallel processing can lead to situation...
This paper examines the potential of parallel computation methods for partial differential equations...
This paper examines the potential of parallel computation methods for pamal differential equations (...
Ever since computers were first used for scientific and numerical work, there has existed an "arms r...
Highly parallel computing architectures are the only means to achieve the computation rates demanded...
Parallel programming allows the speed of computations to be increased by using multiple processors o...
A great challenge for scientists is to execute their computational applications efficiently. Nowaday...
Many problems in several fields like physics, chemistry, biology and engineering lack an analytical ...
Parallel computers provide great amounts of computing power, but they do so at the cost of increased...
We present an overview of the state of the art and future trends in high performance parallel and di...
The best enterprises have both a compelling need pulling them forward and an innovative technologica...
A parallel program together with the parallel hardware it is running on is not only a vehicle to sol...
Part 1 (Chapters 2,3 and 4) is concerned with the development of hardware for multiprocessor systems...
The evolution of parallel processing over the past several decades can be viewed as the development ...
This paper describes the use of a parallel computer system in applying a finite difference method to...
The communication and synchronization overhead inherent in parallel processing can lead to situation...
This paper examines the potential of parallel computation methods for partial differential equations...
This paper examines the potential of parallel computation methods for pamal differential equations (...
Ever since computers were first used for scientific and numerical work, there has existed an "arms r...
Highly parallel computing architectures are the only means to achieve the computation rates demanded...
Parallel programming allows the speed of computations to be increased by using multiple processors o...
A great challenge for scientists is to execute their computational applications efficiently. Nowaday...
Many problems in several fields like physics, chemistry, biology and engineering lack an analytical ...
Parallel computers provide great amounts of computing power, but they do so at the cost of increased...
We present an overview of the state of the art and future trends in high performance parallel and di...
The best enterprises have both a compelling need pulling them forward and an innovative technologica...
A parallel program together with the parallel hardware it is running on is not only a vehicle to sol...
Part 1 (Chapters 2,3 and 4) is concerned with the development of hardware for multiprocessor systems...
The evolution of parallel processing over the past several decades can be viewed as the development ...
This paper describes the use of a parallel computer system in applying a finite difference method to...
The communication and synchronization overhead inherent in parallel processing can lead to situation...