Building fast, reliable, and adaptive software is a constant challenge for computational science, especially given recent developments in computer architecture. This paper outlines some of our efforts to address these three issues in the context of computational chemistry. First, a simple linear performance that can be used to model and predict the performance of Hartree-Fock calculations is discussed. Second, the use of interval arithmetic to assess the numerical reliability of the sort of integrals used in electronic structure methods is presented. Third, use of dynamic code modification as part of a framework to support adaptive software is outlined
In this and a preceding paper, we provide an introduction to the Fujitsu VPP range of vector–paralle...
The field of high performance scientific computing lies at the crossroads of a number of disciplines...
Traditional CMOS computers are Turing complete information processing systems. They can compute any ...
The challenges specific to the development of computational chemistry software are discussed. Select...
Recently the computer graphics systems and memory capabilities necessary to perform detailed chemica...
Applications augmented with adaptive capabilities are becoming common in parallel computing environm...
This paper explores the use of a simple linear performance model, that determines execution time bas...
Parallel hardware has become readily available to the computational chemistry research community. Th...
AbstractThis paper explores the use of a simple linear performance model, that determines execution ...
. A general and unified framework for adaptive computation using the finite element method, finite v...
This text evolved from a new curriculum in scientific computing that was developed to teach undergra...
Abstract: The influence of mathematics techniques to the progress in architecture and perf...
The accuracy of electronic structure calculations are affected to some degree by numerical errors. A...
Convergence rates of iterative algorithms for solving non-linear fixed-point (or root-finding) probl...
Since the beginning of the field of high performance computing (HPC) after World War II, there has b...
In this and a preceding paper, we provide an introduction to the Fujitsu VPP range of vector–paralle...
The field of high performance scientific computing lies at the crossroads of a number of disciplines...
Traditional CMOS computers are Turing complete information processing systems. They can compute any ...
The challenges specific to the development of computational chemistry software are discussed. Select...
Recently the computer graphics systems and memory capabilities necessary to perform detailed chemica...
Applications augmented with adaptive capabilities are becoming common in parallel computing environm...
This paper explores the use of a simple linear performance model, that determines execution time bas...
Parallel hardware has become readily available to the computational chemistry research community. Th...
AbstractThis paper explores the use of a simple linear performance model, that determines execution ...
. A general and unified framework for adaptive computation using the finite element method, finite v...
This text evolved from a new curriculum in scientific computing that was developed to teach undergra...
Abstract: The influence of mathematics techniques to the progress in architecture and perf...
The accuracy of electronic structure calculations are affected to some degree by numerical errors. A...
Convergence rates of iterative algorithms for solving non-linear fixed-point (or root-finding) probl...
Since the beginning of the field of high performance computing (HPC) after World War II, there has b...
In this and a preceding paper, we provide an introduction to the Fujitsu VPP range of vector–paralle...
The field of high performance scientific computing lies at the crossroads of a number of disciplines...
Traditional CMOS computers are Turing complete information processing systems. They can compute any ...