Differences

This shows you the differences between two versions of the page.

--- start [2024/12/12 20:26] – [Projects using MuPIF] bp
+++ start [2025/09/27 00:11] (current) – [Documentation & Resources] bp
@@ Line 1: / Line 1: @@
 {{ :wiki:images:mupif-logo.png?100|}}
 {{keywords> Open Simulation Platform, Digital twin, Interoperability, Modelling, Simulations, Workflows}}
-====== MuPIF ======
+====== MuPIF.org - Empowering Complex Multiphysics Simulations with Open-Source, Modular Integration and Digital Twin Technology. ======
-MuPIF platform is an open-source, modular, and object-oriented simulation platform designed to create complex, distributed, multiphysics simulation workflows. It integrates existing simulation tools to handle various scales and processing chains.
+MuPIF is an open-source, modular, and object-oriented simulation platform designed to create complex, distributed, multiphysics simulation workflows with integrated Digital Twin technology.
 **Key features of MuPIF include:**
   * Distributed Design: Allows execution of simulation scenarios involving remote applications and data.
-  * Data Management System (DMS): Builds digital twin representations of physical systems, enhancing predictive simulations.
+  * Data Management System (DMS): Builds digital twin representations of physical systems, enhancing predictive simulations. Provides full traceability.
   * Interoperability: Standardizes application and data component interfaces, enabling seamless integration of different simulation models and data types.
   * Graphical Workflow Editor: Facilitates low-code workflow development and makes implementation more accessible.
   * Security: Supports SSL or VPN-based secure communication and data exchange.
   * Portability: Written in Python supporting various operating systems, making it a versatile tool for various applications.
+  * Performance: HPC integration to address high computational needs
   * Open Source: Available under LGPL Open source license
+{{ :wiki:videos:mupif_introduction.mp4| MuPIF Introduction}}
 MuPIF utilizes an object-oriented approach, with abstract classes defining standardized interfaces introduced to represent simulation models and data types.
@@ Line 19: / Line 23: @@
 MuPIF achieves interoperability with standardization of application and data component interfaces and it is not reliant on standardized data structures or protocols. Any existing data representation or simulation model can be plugged in and used transparently, provided the corresponding data interface is implemented.
-{{ :wiki:images:mupif-distributed-v2-cropped.png?nolink&400|}}
 Even though the platform can be used locally on a single computer orchestrating installed applications, the real strength of the MuPIF platform is its distributed design, allowing to execute simulation scenarios involving remote applications and data. MuPIF provides a transparent distributed object system, which takes care of the network communication between the objects when they are distributed over different machines on the network.
@@ Line 29: / Line 31: @@
 ====== Documentation & Resources ======
+  * [[tutorials|MuPIF platform video tutorials]]
   * The Musicode project MuPIF training video recording is available on YouTube: [[https://youtu.be/oaN78pB8vxw | Musicode MuPIF training]].
   * The mupif/jupyter-demos repository on GitHub contains
@@ Line 78: / Line 81: @@
 ===== Related Publications =====
   * <wrap hi>New, Open Access:</wrap> **B. Patzák, S. Šulc and V. Šmilauer. Towards digital twins: Design of an entity data model in the MuPIF simulation platform, Advances in Engineering Software, Volume 197, 2024 (https://www.sciencedirect.com/science/article/pii/S0965997824001406).**
+  * <wrap hi>New</wrap> D. Campagna, A. Del Piccolo, K. Kaklamanis, S. Šulc, M. De Bernardi, F. Ellero, S. Kalourazi, K. Reimann, M. Andrea, K. Kordos, M. Selzer, B. Nestler, D. Papageorgiou, A. Kneer, D. Di Stefano, B. Patzák, and E Lidorikis. Streamlining multi-scale materials modeling: The musicode low-code approach for simulation workflows and executable modas. Integrating Materials and Manufacturing Innovation, April 2025 (https://link.springer.com/article/10.1007/s40192-025-00395-5).
   * B. Patzák , S. Šulc , V. Šmilauer. MuPIF: Framework for Digital Twins and Interoperable Simulation Platform for Advanced Material Design. 9th European Congress on Computational Methods in Applied Sciences and Engineering (ECCOMAS 2024), 3-7 June 2024, Lisboa, Portugal.
   * S. Belouettar, C. Kavka, B. Patzák, H. Koelman, G. Rauchs, G. Giunta, A. Madeo, S. Pricl, S. et al. Integration of material and process modelling in a business decision support system: Case of COMPOSELECTOR H2020 project. Composite Structures, 204, 778-790, 2018.
@@ Line 91: / Line 95: @@
 ===== Projects using MuPIF=====
+  * MuPIF used in INODIN project (Innovative methods for materials diagnostics and monitoring of engineering infrastructure to improve its durability and service life) to provide digital twin platform, MŠMT project CZ.02.01.01/00/23_020/0008487
   * **MuPIF spotted by EU Innovation Radar as innovation exploring value creation opportunities** [[https://www.innoradar.eu/innovation/35416]]
   * MuPIF used as modeling platform in EU H2020 [[http://composelector.net|Composelector]] and [[http://musicode.eu|Musicode]] projects
   * MuPIF has been used to simulate CIGS selenization and Light conversion in LEDs in EU FP7 [[http://mmp-project.eu|MMP]] project
   * SUMO: Sustainable design empowered by materials modelling, semantic interoperability and multi-criteria optimization, Czech Science Foundation,  project no. 22-35755K, 2022-2024.
+  * DeeMa project (Deep-Learning and Optimisation Enabled Material Microstructure Design), funded by Technology Agency of the Czech Republic, grant agreement no. TH75020002.
   * Platform has facilitated simulations of the effect of fire on structural response, project GACR 16-18448S
   * Platform has been used to model moisture condensation in tunnels, project [[http://cesti.cz|CESTI]]
@@ Line 117: / Line 123: @@
 ===== Acknowledgements=====
   * The original development of MuPIF has been funded by Grant Agency of the Czech Republic - Project No. P105/10/1402.
-  * The development has been supported by several EU project:
+  * The development has been supported by several EU/Natinal project:
      * MMP - Multiscale Modelling Platform: Smart design of nano-enabled products in green technologies (FP7 project number 604279),
      * [[http://composelector.net|COMPOSELECTOR: Multi-scale Composite Material Selection Platform with a Seamless Integration of Materials Models and Multidisciplinary Design Framework]], Project no 721105, 2017-2020.
+     * [[http://musicode.eu|H2020 MuSICODE project: An experimentally-validated multi-scale materials, process and device modeling & design platform enabling non-expert access to open innovation in the organic and large area electronics industry]], Grant agreement no. 953187, 2021-2024.
-At present, the MuPIF development is supported by following projects
+    * DeeMa project (Deep-Learning and Optimisation Enabled Material Microstructure Design), funded by Technology Agency of the Czech Republic, grant agreement no. TH75020002.
-  * [[http://musicode.eu|H2020 MuSICODE project: An experimentally-validated multi-scale materials, process and device modeling & design platform enabling non-expert access to open innovation in the organic and large area electronics industry]], Grant agreement no. 953187, 2021-2024.
+    * INODIN project (Innovative methods for materials diagnostics and monitoring of engineering infrastructure to improve its durability and service life), funded by MŠMT, grant agreement CZ.02.01.01/00/23_020/0008487.
-  * DeeMa project (Deep-Learning and Optimisation Enabled Material Microstructure Design), funded by Technology Agency of the Czech Republic, grant agreement no. TH75020002.