2018 — 2020 |
Garavan, Hugh Chen, Yolanda Vanegas, Juan Bongard, Joshua Delmaestro, Adrian |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Mri: Acquisition of a Gpu Accelerated Vermont Advanced Computing Core @ University of Vermont & State Agricultural College
This project will enable interdisciplinary science through the acquisition of a high-performance computer cluster, named DeepGreen. Based on cutting-edge massively parallel graphics processing unit (GPU) technologies, DeepGreen will be utilized by the over 300 users from six Colleges at the University of Vermont, and throughout the Northeast. The unique hybrid architecture was designed to optimize artificial intelligence (AI) applications and will allow for rapid progress on problems of great societal importance. They include: quantum computing, drug discovery and design, safe robotics, control of adaptive crop pests, and new computer vision tools for use in the health care and transportation industries. As an example, DeepGreen will allow the training of neural networks on the world's largest brain imaging datasets of illicit drug users, yielding novel health and policy strategies to combat the opioid epidemic. A focus of the scientific and technical team is to broaden the number of personnel able to exploit GPU hardware for problem solving, producing the highly trained and diverse technical workforce required for the current and future AI economy.
DeepGreen was designed by a team of experts from the physical, medical, biological, computational, and agricultural sciences, partnered with an experienced group of information technology professionals. It will be capable of over 8 petaflops of mixed precision calculations based on the latest NVIDIA Tesla V100 architecture with a hybrid design allowing high bandwidth message passing across heterogeneous compute nodes. Its extreme parallelism will facilitate research in three interconnected areas: quantum many-body systems, molecular simulation and modeling, and deep learning, artificial intelligence and evolutionary algorithms. DeepGreen will forge transformative research pipelines. It will enable the study of thousands of quantum entangled atoms, and millions of interacting components in biological systems providing insights into structure-function mechanisms. Machine learning and deep neural networks will exploit DeepGreen's Tensor Cores to solve diverse problems. These problems include: the development of coarse grained potentials for use in molecular dynamics simulations, real time dynamic processing of crowd sourced decision making for robotics, genomic sequencing of invasive pests, and feature recognition in medical imaging to distinguish cancerous tumors from benign nodules. Software designed for use on DeepGreen will be released to the public as open source, with other scientists and researchers being able to immediately use and extend it. This project will also support the next generation of data scientists. Training workshops focused on GPU computing and machine learning frameworks, new university courses, and partnerships with existing local NSF-funded graduate training initiatives, will drive broad utilization of DeepGreen.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
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0.922 |
2021 — 2023 |
Danforth, Christopher O'neil-Dunne, Jarlath Li, Jianing Niles, Meredith Garavan, Hugh |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Mri: Acquisition of a Massive Database to Accelerate Data Science Discovery @ University of Vermont & State Agricultural College
This project is jointly funded by the Major Research Instrumentation and the Established Program to Stimulate Competitive Research (EPSCoR) programs. The project funds construction of DataMountain, a massive database cluster for high performance computing at the University of Vermont (UVM). The large-memory machine will enhance the Vermont Advanced Computing Core, a virtual laboratory supporting the research of over 500 scientists in the state of Vermont. With so many fields transitioning from data-scarce to data-rich environments, many important research areas will benefit from this new machine including research into addiction, mental illness, climate change, drug discovery, food systems, and the spread of online misinformation. DataMountain will allow for fast access to enormous datasets, supporting several projects that require computational power and speed to effectively analyze, describe, and explain rapidly growing datasets.
DataMountain will increase by nearly two orders of magnitude the largest random access memory machine available for computational research at UVM, accelerating large-scale data-driven research requiring rapid reading and writing, and facilitating a broad and diverse set of important scientific investigations not currently possible given the existing hardware. It will also enhance the functionality of the high performance computing clusters BlueMoon and DeepGreen, which are dedicated to parallel processing and machine learning respectively. For example, the machine will allow for interactive access to over 50 terabytes of social media data through http://storywrangling.org and http://hedonometer.org for timely analysis of changes related to the COVID-19 pandemic in population-scale physical and mental health data. In addition, DataMountain will allow for massive increases in the spatial and temporal resolution of computational chemistry simulations being performed for data-driven design of next-generation antimicrobial peptides to combat antibiotic resistance. DataMountain will also enable exploration of petabytes of fMRI, genetic, task performance, and survey data associated with 10,000 adolescents across the United States over the next decade. In addition, the machine will accelerate research using unmanned aerial surveillance imaging for tree canopy assessments, facilitate network science modeling of agricultural diversity of crops and nutritional outcomes globally, and help quantify the impacts of the COVID-19 pandemic on food insecurity.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
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0.922 |