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Computational Chemistry and NanoMaterial GRID

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Department of Chemistry, KAIST. Grid Forum Korea 2003 ... to study OGSA structure and its practicality of application to chemistry ... – PowerPoint PPT presentation

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Title: Computational Chemistry and NanoMaterial GRID


1
Computational Chemistry and Nano-Material GRID
Grid Forum Korea 2003 2003/12/02
  • Y.S.Lee, J.Kwak, Quantum Chemistry Laboratory
  • Department of Chemistry, KAIST

2
Table of Contents
  • Objective
  • Activities
  • Plan Result
  • Scope
  • Request
  • Future work

3
Objective
  • Practical GRID system for computational chemists
  • Scalability of problem
  • Extensibility of system
  • Feedback to GRID infra-structure developers

4
Objective
  • Practical GRID system for computational chemists
  • Scalability of problem
  • Extensibility of system
  • Feedback to GRID infra-structure developers
  • Providing computational resources to
    collaborating research groups _at_ Hardware
    resources _at_ Software resources (various
    computational chemistry packages)
  • Educational purpose

5
Objective
  • Practical GRID system for computational chemists
  • Scalability of problem
  • Extensibility of system
  • Feedback to GRID infra-structure developers
  • Finding computational chemistry problems which
    are scalable to GRID system

6
Objective
  • Practical GRID system for computational chemists
  • Scalability of problem
  • Extensibility of system
  • Feedback to GRID infra-structure developers
  • GRID infra-structure functionalities
  • User interface
  • Standardization

7
Activities
  • Practical GRID system for computational
    chemists- Development of WWW portal, which is
    easy to use- GRID system applets for easy
    installation- Field test with real world
    computational chemistry problems

8
Activities
  • Scalability of problem- High Throughput
    Computing problems rather than HPC/parallel
    processing.- Field test with the developed GRID
    system

9
Activities
  • Extensibility of problem
  • Study on OGSA/Globus 3.0
  • Study on DB connection
  • Study on ECCE connection to get more precise user
    interface
  • Study on more GRID infrastructure functionalities
    and Gridsphere

10
Activities
  • Extensibility of problem
  • Study on OGSA/Globus 3.0
  • Study on DB connection
  • Study on ECCE connection to get more precise user
    interface
  • Study on more GRID infrastructure functionalities
    and Gridsphere

Database
11
Activities
  • Extensibility of problem
  • Study on OGSA/Globus 3.0
  • Study on DB connection
  • Study on ECCE connection to get more precise user
    interface
  • Study on more GRID infrastructure functionalities
    and Gridsphere

Database
12
Activities
  • Extensibility of problem
  • Study on OGSA/Globus 3.0
  • Study on DB connection
  • Study on ECCE connection to get more precise user
    interface
  • Study on more GRID infrastructure functionalities
    and Gridsphere

Database
13
Activities
  • Feedback- Open web site- Documentation

14
Plan and Result
  • Development and set-up
  • AAOGS2 GRID system
  • AAOGS2 WWW console
  • Field study
  • AAOGS2 GRID system Ge surface cluster model
  • AAOGS2 WWW consoleC60 cage with N atom
  • HIO CCSD calculation with ECP etc.
  • Extensibility
  • OGSA/Globus 3.0 test
  • ECCE 3.1 set-up and architecture design
  • Architecture design of Gridsphere and DB
    connection
  • Documentation
  • Documentation http//aaogs.kaist.ac.kr/grid
    Wikiwiki website
  • Problems and solution models of computational
    chemistry applications for GRID computing
    environment
  • Introduction of OGSA and Globus 3.0 and its
    reality to computational chemistry
  • Etc.

15
Scope ScalabilityGRID vs.Chemistry
  • Characteristics of computational chemistry
    calculation
  • Different software packages for various molecular
    systems
  • Various scales of calculations on research groups
    with different conditions
  • Repeated calculation with gradual progress in
    many cases
  • Computational resource collaboration and
    High-Throughput-Computing

16
Scope AAOGS2 GRID system
  • Focus on easy installation and easy usage
  • Direct job launcher/Multiple input generator/FTP
    input catcher
  • JAVA molecular structure viewer and Network map
    viewer
  • Simple WWW output analyzer/MS Excel connectivity

Input Generator
End user
Select resources (program and arguments)
Submit a job
View result
17
AAOGS2 GRID system
  • Designed for a organization of 36 academic
    research groups
  • 16 testbed nodes, 40 cluster CPUs, 6 workstation
    in KISTI, KAIST and WKU currently connected.
  • Applied for
  • Scanning along various geometries
  • Discovery among a large number of candidate
    molecules
  • Sharing computational resources
  • Sharing computational chemistry software package
  • Educational usage

18
Field study with AAOGS2
  • Ge surface cluster model
  • Study on top dimer structure and dangling bonds
  • Getting potential energy curve along various bond
    length
  • Trying on various sizes of models
  • PM3 method
  • Presented KCS Meeting (2003)

19
Field study with AAOGS2
  • Fullerene with N atom
  • Study on N atom capturing pathway
  • Potential energy calculation along selected
    entering pat way
  • PM3 calculation completed
  • DFT calculation proceeding
  • Dynamic view
  • http//aaogs.kaist.ac.kr/grid/c60withn_ani.htm

20
Field study with AAOGS2
  • Other routine calculations with collaborating
    resources
  • Ex) HIO molecule spin--orbit correction term
    calculation with effective core potential
  • Proceeding
  • Now, at the stage of getting optimized geometry
    without spin--orbit effect
  • Iodine atom with ECP

21
Extensibility - NTGP GRID system
  • Test GRID system for studying extensibility of
    CCNM GRID
  • Tested with OLED material candidates

22
Extensibility OGSA/Globus3 test
  • IBM/KISTI OGSA Workshop and Group seminar
  • to study OGSA structure and its practicality of
    application to chemistry
  • Globus 3.0 Gridsphere OLED material discovery
    problem tested on NTGP
  • Globus 3.0 instability, Heavy overhead,
    Difficulties of debugging

System Management Services
Grid Services
ResourceManagement
Cluster Management
Policy
ProblemDetermination
Logging
Service Collections
JobScheduling
FileTransfer
DataReplication
Provisioning
OGSI Open Grid Services Infrastructure
Management
Registry
Lifecycle
Discovery
HandleMap
Notification
Factory
Web Services
23
Extensibility ECCE
  • ECCE 3.1 set up / install know-how
  • GSISSH remote shell processing structure

24
Extensibility ECCE
  • To be connected to GRID system for advanced user
    interface

25
Extensibility More Globus functions
  • Design of system to adopt advanced features of
    Globus
  • Finding optimal resources with MDS/GRIS/GIIS
  • Studied on NTGP

26
Extensibility More Globus functions
  • Design of Database connectivity
  • Studied on NTGP

WebServer (GridsphereandECCEsupport)
Portal Service
Users
???
Qury Generator
Resource 1
MDS
Resource 2
HTTP
Input Generator
GSI
GRAM
Job Manager
Resource N
Users
???
GridFTP
Remote Storage
Monitoring
Grid Portal
Globus Toolkit
CCNM GRID
27
Feedback
  • CCNM GRID project Website
  • Project/research reports
  • GRID introduction
  • Document archive
  • http//aaogs.kaist.ac.kr/grid

28
Request
  • Standardized and convenient resource information
    service tool
  • By-passing message-passing-tool support
  • Intentional job migration tool rather than
    accidental job migration service

29
Request Bypassing message-passing
  • Based on study on network load of computational
    chemistry calculation parallel processing
  • Adoption of NetPIPE or MP_Lite giving efficient
    High Performance Computing application

30
Request Intentional job migration
  • Computational chemistry systems are very various.

31
Request Intentional job migration
32
Request Intentional job migration
33
Presentation and Publication
  • Presentation
  • 2003.4.KCS(WWW Based Distributed Computing
    System For Computational Chemistry)
  • 2003.6. The 3rd Symposium of material design and
    development with computer modeling(Quantum
    Chemistry Study on Acetylene Adsorption on Ge
    Surface Study and Fullerene Metal Complex)
  • 2003.6. KAIST-Princeton Joint Symposium(Developme
    nt of Fault Tolerant Distributed Computing System
    For Computational Chemistry)
  • 2003.10. KCS(Parallel Processing and Distributed
    Computing for Computational Chemistry on GRID
    environment)
  • 4th International Conference on
    Electroluminescence of Molecular Materials and
    Related Phenomena(Theoretical Study for the
    Structural and Optical Properties of
    Metalloporphyrin Complexes)
  • Publication
  • Spin-Orbit Density Functional Theory Calculations
    for TlAt with Relativistic Effective Core
    Potentials, Bulletin of the Korean Chemical
    Society Vol.24, No.6

34
Future Work
  • System packaging
  • Application researches with GRID system
  • Education support
  • Extended features implementation

35
Collaborating groups
KAIST Yoon Sup Lee
KNU Sang Yeon Lee KNU Cheol-ho Choi SSU See-year
Seong SSU Myung-ho Kim WKU Ki-hak
Lee http//aaogs.kaist.ac.kr/grid
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