Next-generation structural design software
with realistic simulations for demanding timber and hybrid structures.

About our company

We are preparing to launch VeriSim4D, next-generation structural design software specifically developed for timber and hybrid structures. It requires also research and development of timber constitutive model for discontinuous element modeling.

Our team has over 15 years of experience in the academia, software development, structural engineering and R&D.

VeriSim4D features
  • Web-Based Platform
    VeriSim4D leverages web technologies, enabling embedding of FEM solvers in other web-based systems.
  • Jupyter Notebook Integration
    Offers integration with Jupyter Notebook for straightforward parametric modeling and result post-processing, allowing users to create custom calculation templates and control the process.
  • Discontinuous Finite Elements
    Utilizes both discontinuous and continuous finite elements for modeling material behaviors, emphasizing the importance of discontinuities in realistic structural analysis.
  • Python API
    Provides an accessible, high-level Python API, facilitating efficient communication between the user and the FEM solver through multiple Python class objects.
  • Progressive Collapse Simulation
    Features advanced modeling of structural failure and post-failure behavior with an innovative contact search algorithm for realistic simulation of progressive collapses at extreme displacements.
  • Direct Resistance Checks
    Implements material models that accurately represent structural behavior, eliminating the need for separate stress-strain checks and allowing direct verification from FEM results
  • Statics, Dynamics and Hybrid solver
    Supports calculations for both static and dynamic issues, with a specialized solver for non-linear static problems to achieve equilibrium efficiently.
  • Multiscale Sub-structuring
    Enables detailed analysis of global behavior by integrating fine-scale models of structural joints and critical members, with fine-scale results transferable to the global model.
  • Teamplate-Based Design
    Simplifies the creation of complex hybrid joints with predefined templates, significantly reducing design time.
  • High Performance and Speed
    Achieves high performance through parallelization on multiple CPUs, streamlining computational intensive tasks.
  • Post-Failure Behavior
    Models structures up to complete failure using discrete elements and large displacement theory, crucial for analyzing impacts, explosions, and progressive collapse.
  • Virtual Material and Structural Testing Laboratory
    Simulates physical experiments realistically, potentially reducing the need for physical testing in new material and structure development.
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