UT-SIM
  • Home
  • Architecture
    • Communication
    • Integration Modules
    • Substructure Modules
  • Users
    • Get Started with UT-SIM >
      • OpenSees
      • Abaqus
      • S-Frame
      • VecTor Suite
      • NICON-NIO
      • NICON-AIO
    • Download
  • Developers
    • Source Code
    • Communication Examples >
      • C/C++
      • Fortran
      • Matlab
      • Python
    • Download
  • Hybrid Simulation
  • Numerical Simulation
  • Application Examples
  • Workshop
  • News
  • Collaborators
  • Contact
  • References

UT-SIM

An Open Framework for Integrated Multi-platform Simulations for Structural Resilience​

Updates
​(Nov, 2019)
​
  • The 2nd Workshop on Multi-Platform Hybrid Simulation with UT-SIM Framework was completed at the Universtiy of Toronto's St. George Campus, November 23, 2019. (See details)
  • Workshop on Multi-Platform Hybrid Simulation was conducted at University of British Colombia at Okanagan Campus, August 29, 2019 (Link)
  • Prof. Oh-Sung Kwon  presented a real-time wind-tunnel hybrid simulation method for bridge decks and buildings at Structure Congress  2019 (Link)
  • Dr. Jamin Park (Post Doctoral Fellow) performed a hybrid simulation for performance assessment of link beams of multi-story building (Link)
  • Tianyi (Stanley) Cheng (MASc Student) is performing a seismic fragility analysis of the internal and the auxiliary structure of a nuclear power plant (Link)
  • Sayed Mohamed (Ph.D. Candidate) is working on a multi-scale seismic simulation of a city block considering site-city interaction (Link)
  • Dr. Jinha Hwang (University of Seoul) is going to run a hybrid simulation for performance assessment of a structure with post-tensioned precast concrete beam-column connections (Link)
  • Pedram Mortazavi (Ph.D. Candidate) is designing hybrid simulations for a yielding brace system and a eccentrically braced frame. (Link)

UT-SIM

     An Open Framework for Integrated Multi-platform Simulations for Structural Resilience​
Picture

Background

​The performance assessment of civil infrastructure, such as buildings, bridges, subway tunnels, power plants, etc., under extreme loading conditions still represents a formidable challenge for engineers worldwide.
​
With the current levels of modelling technologies and computing power, increasingly complex and realistic models of structures are being developed and refined, primarily in single modelling packages. Yet, the scientific and engineering community has not yet achieved complete models that can capture the entire response of complex structural systems in order to fully assess their performance under extreme loading conditions. Multiple challenges still remain as most complex systems incorporate very different components, each requiring a level of specialized modelling sophistication or even in some cases complete physical testing in order to capture the behaviour of the integrated system to multiple hazards such as earthquakes, tsunamis, tornadoes, blasts, fire, floods and many others.
 
The UT-SIM initiative is aimed at enhancing our ability to understand the performance of civil infrastructure when it is subjected to natural and man-made hazards in order to enhance the resilience of Canadian and worldwide societies.

The UT-SIM Initiative

The University of Toronto has a long standing tradition of developing cutting edge advanced numerical models for reinforced concrete structures, carrying large-scale experiments, developing new high-performance resilient structural systems, and is now one of the leading hubs on advanced hybrid simulation methods. Our group is now trying to integrate all of these capabilities to develop a next generation simulation platform that will achieve new levels of accuracy and reliability for the modelling of complex structural systems. This will contribute to the worldwide research effort of not only better understanding the expected response of critical infrastructure under extreme loading conditions for better disaster planning or disaster mitigation but also to form the basis for accelerating the development and implementation of more resilient structural systems that will better protect our infrastructure.
​
The proposed UT-SIM structural simulation method is an open concept that is available to the entire research community in order to foster collaboration between institutions towards developing the next generation of numerical and hybrid numerical-physical simulation strategies.
 
We invite you to contribute to the framework by adopting the UT-SIM communication library, which will allow seamless integration of your models or laboratory specimens with any other integration modules in the framework and enhancing it with your own research developments and applications. Your contributions will greatly improve the interoperability of specialized computer programs, and improve the accuracy of structural performance assessment.

Mission Statement

The University of Toronto's Simulation (UT-SIM) Framework has been developed to achieve the following objectives;
  • Integration of diverse structural/geotechnical modelling and analysis tools
  • Integration of a numerical models in supercomputers with models on desktop computers
  • Integration of physical specimens with numerical models for pseudo-dynamic and real-time hybrid simulations
  • through the open-source communication protocol, geographically distributed hybrid simulations with partner institutions 
Achieving all of the above objectives through a single integration software is practically very difficult.  The UT-SIM framework is not a single software which can solve all problems; rather it is a framework for a seamless integration of diverse physical/numerical models through standardized communication protocols and data exchange format. 
 
To facilitate the implementation of this approach, the communication library and source code is released to the public domain such that any institution can easily integrate their own software or laboratory to an integrated simulation. Furthermore, we have also developed the Network Interface for Console Application (NICA) and the Network Interface for Controllers (NICON) which are used to integrate various software and actuator controllers.​ 

The open-source approach for integration of diverse numerical models and experimental specimens will greatly improve partnerships among institutions in Canada and abroad.

How to Join...

The UT-SIM framework is intended to foster collaboration in advanced simulation through integration of various numerical models and physical specimens. To this end, our development of the UT-SIM framework are free to download from here. Feel free to contact us if you are interested in collaboration with us or need help and support on using the framework. There are already eleven collaborators worldwide.  Collaborators have open access the current capabilities and are also invited to participate in developing additional capabilities. When possible, we encourage collaborators to share their own methods of model integration using the UT-SIM framework such that other collaborators can benefit from each other. 

Proudly powered by Weebly
  • Home
  • Architecture
    • Communication
    • Integration Modules
    • Substructure Modules
  • Users
    • Get Started with UT-SIM >
      • OpenSees
      • Abaqus
      • S-Frame
      • VecTor Suite
      • NICON-NIO
      • NICON-AIO
    • Download
  • Developers
    • Source Code
    • Communication Examples >
      • C/C++
      • Fortran
      • Matlab
      • Python
    • Download
  • Hybrid Simulation
  • Numerical Simulation
  • Application Examples
  • Workshop
  • News
  • Collaborators
  • Contact
  • References