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π βAn investment in knowledge pays the best interest.β β Benjamin Franklin
π»Β Deep Dive: FEA Workflows in Minutes | The Low-Code Revolution
In the first Deep Dive Series, I'm thrilled to invite Akhil Mora from Synera to show you a game-changer in CAE workflows. π
Have you ever wished to redefine speed & efficiency in FEM workflows?
We're demonstrating the secret sauce for FEA enthusiasts - Synera's Templates and libraries. Witness the seamless collaboration between various engineering experts, creating a powerful team collaboration. ππ€
The session is intended to run for around 1 hour with an interactive Q&A session.
πΒ AI Chat Playground | Your MATLAB Coding Assistant
π₯ Smoothed-Particle Hydrodynamics (SPH) coming to Simcenter STAR-CCM+
The biggest CFD splash for me in 2024 so far: https://blogs.sw.siemens.com/simcenter/sph-meshless-method/
A bit more than two years ago, Siemens acquired #Nextflow Software, a French startup that developed a Smooth Particle Hydrodynamics (SPH) CFD code. This move added some cutting-edge mesh-free CFD technology to our portfolio! Great news per se, but it also added another code base for our development teams to evolve and another CFD tool for you, our users, to learn and administrate.
And so, in the CFD community, "To mesh or not to mesh" has always been an a priori decision on which code to go for a classical finite volume (FV) based CFD tool or an SPH code. If you wanted or needed both, the likelihood was high that you had to live with two CFD codes.
π¦ Physics Informed Machine Learning: High Level Overview of AI and ML in Science and Engineering
π¦Β But How DO Fluid Simulations Work?
Fluid simulations. How on is it possible that a computer can recreate the crashing waves, the rolling clouds and the swirling smoke that we see in our daily lives, phenomena which seem characterized by randomness and chaos? This video will attempt to explain exactly how the mathematics behind fluid simulations work.
π£οΈ Upcoming Events
This in-depth webinar will cover the innovative workflow and features of the Analytical Toolbox and Design Explorer, including:
Design Analysis:Β Performing lightning-fast design analysis for single-lap joints
Joint Strength Evaluation:Β Leveraging advanced analytical methods to evaluate design influences on bond line stresses.
Fast Parameter Studies:Β Exploring joint design variations within seconds using the analytical design explorer
Automated Reporting:Β Managing and sharing calculation results through the automatedΒ PDFΒ report
π» Engineering Tool of the Week - OpenLB β Open Source Lattice Boltzmann Code
The OpenLB project provides a C++ package for the implementation of lattice Boltzmann methods that is general enough to address a vast range of transport problems, e.g. in computational fluid dynamics. The source code is publicly available and constructed in a well readable, modular way. This enables for a fast implementation of both simple academic test problems and advanced engineering applications. It is also easily extensible to include new physical content.
πBook of the Week
Data-Driven Fluid Mechanics: Combining First Principles and Machine Learning
Data-driven methods have become an essential part of the methodological portfolio of fluid dynamicists, motivating students and practitioners to gather practical knowledge from a diverse range of disciplines. These fields include computer science, statistics, optimization, signal processing, pattern recognition, nonlinear dynamics, and control.
π Meme of the Week
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For any business-related issues or collaborations, email me atΒ support@jousefmurad.com!
Keep engineering your mind! π§
Jousef