Proceedings of the 2001 ACM/IEEE conference on Supercomputing
Cactus Tools for Grid Applications
Cluster Computing
Deploying Web-Based Visual Exploration Tools on the Grid
IEEE Computer Graphics and Applications
Cactus Grid Computing: Review of Current Development
Euro-Par '01 Proceedings of the 7th International Euro-Par Conference Manchester on Parallel Processing
Cactus Application: Performance Predictions in Grid Environments
Euro-Par '01 Proceedings of the 7th International Euro-Par Conference Manchester on Parallel Processing
Grid programming: some indications where we are headed
Parallel Computing - Special issue: Advanced environments for parallel and distributed computing
Design and Evaluation of a Resource Selection Framework for Grid Applications
HPDC '02 Proceedings of the 11th IEEE International Symposium on High Performance Distributed Computing
Grid resource management
Proceedings of the 2nd international conference on Service oriented computing
Proceedings of the 2003 ACM/IEEE conference on Supercomputing
Evaluation of Cache-based Superscalar and Cacheless Vector Architectures for Scientific Computations
Proceedings of the 2003 ACM/IEEE conference on Supercomputing
The Cactus Worm: Experiments with Dynamic Resource Discovery and Allocation in a Grid Environment
International Journal of High Performance Computing Applications
Performance Predictions for a Numerical Relativity Package in Grid Environments
International Journal of High Performance Computing Applications
An autonomic tool for building self-organizing Grid-enabled applications
Future Generation Computer Systems
Towards an end-user programming environment for the grid
GCC'05 Proceedings of the 4th international conference on Grid and Cooperative Computing
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In 1916, Albert Einstein published his famous general theory of relativity, which contains the rules of gravity and provides the basis for modern theories of astrophysics and cosmology. For many years, physicists, astrophysicists, and mathematicians have striven to develop techniques for unlocking the secrets contained in Einstein's theory of gravity; more recently, computational-science research groups have added their expertise to the endeavor. Because the underlying scientific project provides such a demanding and rich system for computational science, techniques developed to solve Einstein's equations will apply immediately to a large family of scientific and engineering problems. The authors have developed a collaborative computational framework that allows remote monitoring and visualization of simulations, at the center of which lies a community code called Cactus. Many researchers in the general scientific computing community have already adopted Cactus, as have numerical relativists and astrophysicists. This past June, an international team of researchers at various sites ran some of the largest such simulations in numerical relativity yet undertaken, using a 256- processor SGI Origin 2000 supercomputer at NCSA.