Difference between revisions of "Main Page"

From crtc.cs.odu.edu
Jump to: navigation, search
(Extreme-Scale Parallel Mesh Generation)
(Extreme-Scale Parallel Mesh Generation)
Line 13: Line 13:
 
We  have  assembled  a  team  of  established  leaders  that are currently developing state-of-the-art work  that  represents issues  relevant  to NASA’s CFD 2030 Vision and will broadly impact end-user productivity of users throughout DoD and NASA.
 
We  have  assembled  a  team  of  established  leaders  that are currently developing state-of-the-art work  that  represents issues  relevant  to NASA’s CFD 2030 Vision and will broadly impact end-user productivity of users throughout DoD and NASA.
  
'''Objectives''':
+
'''Objectives'''
 
:# Design  a  multi-layered  algorithmic  and  software  framework  for  3D  tetrahedral anisotropic parallel mesh generation methods using state-of-the-art functionality supported by methods implemented in AFLR and CRTC’s telescopic approach for parallel mesh generation.
 
:# Design  a  multi-layered  algorithmic  and  software  framework  for  3D  tetrahedral anisotropic parallel mesh generation methods using state-of-the-art functionality supported by methods implemented in AFLR and CRTC’s telescopic approach for parallel mesh generation.
 
:# Development of error-based metrics to drive an anisotropic adaptive process
 
:# Development of error-based metrics to drive an anisotropic adaptive process

Revision as of 21:36, 5 October 2017


Extreme-Scale Parallel Mesh Generation

  • CDT3D Mesh

  • Overview

    Finite Element Mesh Generation is a critical component for many (bio-) engineering and science applications. The goal of this project is to deliver a novel Telescopic framework for highly scalable and energy efficient codes. Domain-and application-specific knowledge and run-time system support are combined to improve accuracy of FE computations.

  • CRTC Research Sub-Group for Extreme Scale Parallel Mesh Generation, from left to right: Nikos Chrisochoides, Kevin Garner, Dana Hammond (TM from NASA/LaRC), Christos Tsolakis and Polykarpos Thomadakis.

    We have assembled a team of established leaders that are currently developing state-of-the-art work that represents issues relevant to NASA’s CFD 2030 Vision and will broadly impact end-user productivity of users throughout DoD and NASA.

    Objectives

    1. Design a multi-layered algorithmic and software framework for 3D tetrahedral anisotropic parallel mesh generation methods using state-of-the-art functionality supported by methods implemented in AFLR and CRTC’s telescopic approach for parallel mesh generation.
    2. Development of error-based metrics to drive an anisotropic adaptive process
    3. Design a power-aware parallel runtime software system for extreme-scale adaptive CFD computations including: (i) mesh generation & adaptation, and (ii) consistent error-based metrics for adaptation of any CFD discretization with localizable error estimates.
  • Medical Image Computing

    Computer Aided Personalized Education