Supercomputer Fugaku is a Japanese supercomputer that was developed by RIKEN Center for Computational Science and Fujitsu. It was officially ranked as the world's fastest supercomputer in June 2020, according to the Top500 list of supercomputers.
Fugaku was designed to tackle a variety of computational challenges and has a wide range of applications, including climate modeling, disaster prevention and response, and materials science. One of its key features is its ability to perform simulation and modeling of complex systems at a scale that was previously not possible. This is due to its high-performance computing capabilities and large memory capacity, making it an ideal tool for tackling the world's most complex problems.
Fugaku was developed using the latest technologies in hardware and software. Its hardware architecture consists of Arm-based processors and an interconnected network that enables efficient communication between nodes. The system uses Fujitsu's A64FX SoC (System on a Chip), which includes 48 cores per processor and is optimized for high-performance computing. The supercomputer also features a large memory capacity, with each node having 384 GB of memory, providing a total of 192 TB of memory for the entire system.
One of the key advantages of Fugaku is its ability to perform simulations and models of real-world phenomena with high accuracy. The system is able to perform high-resolution simulations of large and complex systems, such as weather patterns and natural disasters, with a level of accuracy that was previously not possible. This enables researchers to better understand the underlying physical processes that drive these phenomena and make more informed predictions about their behavior.
Another major application of Fugaku is in the field of materials science. The supercomputer has the ability to perform large-scale molecular dynamics simulations, which can be used to study the properties of materials at the atomic level. This can lead to the discovery of new materials with improved properties and can also help researchers to better understand the underlying physical and chemical processes that govern a material's behavior.
Fugaku also has a range of applications in the fields of life sciences and medicine. The supercomputer can be used to simulate biological processes and help researchers to better understand the underlying mechanisms of diseases, such as cancer and Alzheimer's. This can lead to the development of new drugs and treatments, as well as a better understanding of the human body and its functions.
In addition to its scientific applications, Fugaku also has a range of industrial applications. The supercomputer can be used to optimize complex industrial processes, such as supply chain management and logistics, enabling companies to improve their efficiency and reduce costs.
The development of Fugaku is a major milestone in the history of supercomputing. It represents a significant step forward in our ability to tackle some of the world's most complex problems and has the potential to revolutionize a wide range of fields, from science and engineering to medicine and industry.
In conclusion, Fugaku is a remarkable achievement in the field of supercomputing. Its combination of high-performance computing capabilities, large memory capacity, and versatility make it an ideal tool for tackling the world's most complex problems. With its ability to perform high-resolution simulations and models of real-world phenomena, Fugaku has the potential to revolutionize a wide range of fields.Supercomputer Fugaku holds ahead of all comers overall in HPCG and Graph500 rankings
Fujitsu’s Commitment to the Sustainable Development Goals (SDGs)
The Sustainable Development Goals (SDGs) adopted by the United Nations in 2015 represent a set of common goals to be achieved worldwide by 2030.
Fujitsu’s purpose — “to make the world more sustainable by building trust in society through innovation” — is a promise to contribute to the vision of a better future empowered by the SDGs.