The research was led by Dirk Van Essendelft, Ph.D., machine learning and data science engineer at NETL, and Michael James, Cerebras chief architect of advanced technologies and a cofounder of the company.
“The CS-1 is a very interesting hardware platform because it eliminates key bottlenecks that strangle performance in conventional HPC applications,” Van Essendelft said. “Current HPCs are fighting physics. There are two big problems — wire volume and wire length. The smaller and shorter the wires are that connect memory to compute, the faster and more energy efficient things can run. On traditional HPCs, the memory is located further away, so the wire lengths can be several inches (or feet between computational nodes) and have quite a large volume.”
The CS-1 overcomes this issue because all system memory is located on the device as close to compute as current manufacturing methods will allow and is connected by nanowires. Additionally, the Cerebras CS-1 features the Cerebras Wafer Scale Engine, which is the largest chip ever built. It contains 1.2 trillion transistors, covers more than 46,225 square millimeters of silicon and contains 400,000 general purpose compute cores.
The workload under test was to solve a large, sparse, structured system of linear equations. These calculations underpin the modeling of physical phenomena, including the CFD codes of the Lab’s Multiphase Flow with Interphase eXchanges (MFiX), which is designed to model reacting multiphase systems found in advanced energy systems like chemical looping reactors and fluidized bed reactors.
“Cerebras is proud to extend its work with NETL and produce extraordinary results on one of the foundational workloads in scientific compute,” said Andrew Feldman, co-founder and CEO, Cerebras Systems. “This work opens the door to major breakthroughs in scientific computing performance, as the CS-1, with its wafer-scale engine, overcomes traditional barriers to highly achieved performance, enabling real-time and other use cases precluded by the failure of strong scaling. Because of the radical memory and communication acceleration that wafer scale integration creates, we have been able to go far beyond what is possible in a discrete, single chip processor, be it a CPU or a GPU.”
NETL is a U.S. Department of Energy national laboratory that produces technological solutions for America’s energy challenges. From developing creative innovations and efficient energy systems that make coal more competitive, to advancing technologies that enhance oil and natural gas extraction and transmission processes, NETL research is providing breakthroughs and discoveries that support domestic energy initiatives, stimulate a growing economy, and improve the health, safety, and security of all Americans. Highly skilled men and women at NETL’s sites in Albany, Oregon; Anchorage, Alaska; Houston, Texas; Morgantown, West Virginia; and Pittsburgh, Pennsylvania conduct a broad range of research activities that support DOE’s mission to advance the national, economic, and energy security of the United States.