The scientists and engineers who use OSC find interaction in the research community to be central for the advancement of computational methods within and between disciplines. To ensure a productive environment for research, an active Statewide Users Group (SUG) provides the director with program and policy advice. SUG meets bi-monthly and is headed by a chairperson elected yearly from the SUG membership.
Since 1987, OSC has been providing our clients services in four areas, or functions:
Supercomputing. OSC provides the computational power and storage that scientists need to meet their research goals. Whether researchers need to harness the incredible power of a parallel processor cluster to better understand deep space, a vector processor machine to do weather modeling, or a mid-size shared memory processor system to model the human heart, OSC has the hardware and software solutions to meet their needs.
Research. A staff of high performance computing and networking research experts maintain active research programs in HPC and Networking, Homeland Security and Defense, Environmental Sciences, Engineering and Life Sciences. Our goals are to lead science and engineering research efforts, assist researchers with custom needs and collaborate with regional, national and international researchers in groundbreaking initiatives.
Education. OSC has a national reputation for its training and education programs. Staff teach faculty and student researchers through scientific computing workshops, one-on-one classes, and web-based portal training. Ohio students gain exposure to the world of high performance computing and networking during our annual summer institutes for young women in middle school and for junior and senior high school students. And, the statewide, virtual Ralph Regula School of Computational Science coordinates computational science and engineering education activities for all levels of learning.
Cyberinfrastructure. The Ohio Supercomputer Center’s cyberinfrastructure and software development researchers provide the user community with various high performance computing software options. This variety enables researchers to select parallel computing languages they most prefer, and just as important, it creates a test bed for exploring these systems. By taking a holistic approach to generating efficient supercomputing applications for researchers, the Center’s cyberinfrastructure and software development research capitalizes on all the components within the cycle of innovation — development, experimentation, and analysis - and continuously improves the services provided.
Engineers from the Ohio Supercomputer Center (OSC) have developed an innovative access mechanism that is helping researchers to bridge the chasm between the convenience of a web interface and the complexity of high performance computing systems.
Fifteen middle school girls from around the state will be attending the Ohio Supercomputer Center’s 14th annual Young Women’s Summer Institute at The Ohio State University on July 7-13, 2013.
These academically gifted young women will investigate environmental watershed issues within the state, while exploring career opportunities in science, technology, engineering and mathematics (STEM) fields.
A team of academic and business organizations, mostly from Ohio, won an award for the “Best Application for Advanced Manufacturing” at the Next Generation Application Summit.
Sixteen high school students from around Ohio will be attending the Ohio Supercomputer Center’s 24th annual Summer Institute (SI) on June 16-28, 2013, at The Ohio State University. These academically gifted students, chosen from 50 applicants, will engage in university-level research while working with some of the nation’s best supercomputers.
Ed Note: The AweSim advanced manufacturing application initiative was referred to as IntelSim
during the grant development process, but is being marketed as AweSim as of October 2013.
A once-promising approach for using next-generation, ultra-intense lasers to help deliver commercially viable fusion energy has been brought into serious question by new experimental results and first-of-a-kind simulations of laser-plasma interaction.
Over the course of 4 days, gain a breadth of knowledge of the fundamentals of modern computational methods available for chemical, biological, and materials research. Hear from leading authorities how computational methods are being used to design new materials and learn from hands-on computer exercises how to use major software programs in computational chemistry and molecular simulations. The ACS course is scheduled for the third week of May at the University of Dayton College of Engineering.