Tutorial 3: SOFA, an Open-Source Framework for Physics Simulation in Augmented Reality

The latest Augmented Reality (AR) and Mixed Reality (MR) systems are able to provide innovative methods for user interaction, but their full potential can only be achieved when they are able to exchange bidirectional information with the physical world that surround them, including the objects that belong to the Internet of Things (IoT). The problem is that elements like AR display devices or IoT sensors/actuators often use heterogeneous technologies that make it difficult to intercommunicate them in an easy way, thus requiring a high degree of specialization to carry out such a task. This paper presents an open-source framework that eases the integration of AR and IoT devices as well as the transfer of information among them, both in real time and in a dynamic way. The proposed framework makes use of widely used standard protocols and open-source tools like MQTT, HTTPS or Node-RED. In order to illustrate the operation of the framework, this paper presents the implementation of a practical home automation example: an AR/MR application for energy consumption monitoring that allows for using a pair of Microsoft HoloLens smart glasses to interact with smart power outlets.

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PRISMS-Fatigue computational framework for fatigue analysis in polycrystalline metals and alloys

npj Computational Materials ◽

10.1038/s41524-021-00506-8 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Mohammadreza Yaghoobi ◽

Krzysztof S. Stopka ◽

Aaditya Lakshmanan ◽

Veera Sundararaghavan ◽

John E. Allison ◽

...

Keyword(s):

Open Source ◽

Open Source Software ◽

Large Scale ◽

Metals And Alloys ◽

Analysis Tool ◽

Computational Framework ◽

Crystal Plasticity Finite Element ◽

Polycrystalline Metals ◽

Simulation Based ◽

Open Source Framework

AbstractThe PRISMS-Fatigue open-source framework for simulation-based analysis of microstructural influences on fatigue resistance for polycrystalline metals and alloys is presented here. The framework uses the crystal plasticity finite element method as its microstructure analysis tool and provides a highly efficient, scalable, flexible, and easy-to-use ICME community platform. The PRISMS-Fatigue framework is linked to different open-source software to instantiate microstructures, compute the material response, and assess fatigue indicator parameters. The performance of PRISMS-Fatigue is benchmarked against a similar framework implemented using ABAQUS. Results indicate that the multilevel parallelism scheme of PRISMS-Fatigue is more efficient and scalable than ABAQUS for large-scale fatigue simulations. The performance and flexibility of this framework is demonstrated with various examples that assess the driving force for fatigue crack formation of microstructures with different crystallographic textures, grain morphologies, and grain numbers, and under different multiaxial strain states, strain magnitudes, and boundary conditions.

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Virtual Prototyping of Open Source Heterogeneous Systems with an Open Source Framework Featuring SystemC MDVP Extensions

2020 Forum for Specification and Design Languages (FDL) ◽

10.1109/fdl50818.2020.9232947 ◽

2020 ◽

Author(s):

Francois Pecheux ◽

Liliana Andrade ◽

Marie-Minerve Louerat ◽

Ilias Bournias ◽

Roselyne Chotin ◽

...

Keyword(s):

Open Source ◽

Virtual Prototyping ◽

Heterogeneous Systems ◽

Open Source Framework

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PoreAnalyzer—An Open-Source Framework for the Analysis and Classification of Defects in Additive Manufacturing

Applied Sciences ◽

10.3390/app11136086 ◽

2021 ◽

Vol 11 (13) ◽

pp. 6086

Author(s):

Nils Ellendt ◽

Fabian Fabricius ◽

Anastasiya Toenjes

Keyword(s):

Additive Manufacturing ◽

Open Source ◽

Total Porosity ◽

Shape Accuracy ◽

Process Maps ◽

Defect Type ◽

Open Source Framework ◽

New Material ◽

High Cooling Rates

Additive manufacturing processes offer high geometric flexibility and allow the use of new alloy concepts due to high cooling rates. For each new material, parameter studies have to be performed to find process parameters that minimize microstructural defects such as pores or cracks. In this paper, we present a system developed in Python for accelerated image analysis of optical microscopy images. Batch processing can be used to quickly analyze large image sets with respect to pore size distribution, defect type, contribution of defect type to total porosity, and shape accuracy of printed samples. The open-source software is independent of the microscope used and is freely available for use. This framework allows us to perform such an analysis on a circular area with a diameter of 5 mm within 10 s, allowing detailed process maps to be obtained for new materials within minutes after preparation.

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