Join us and fellow engineers from your region online for COMSOL Day Austria. Listen to experts in the field of simulation, engage in product demonstrations, and ask questions to COMSOL technical staff. There will be interactive Tech Cafés run in parallel with the main sessions.
This schedule will be completed in the coming days. Register for free today!
Learn the fundamental workflow of COMSOL Multiphysics®. This introductory demonstration will show you all of the key modeling steps, including geometry creation, setting up physics, meshing, solving, and postprocessing.
Multiphysics Simulation for Optimization of Piezoelectric Transducers and Micro-/Nanoimprint Processes
I will give you insight into how COMSOL Multiphysics® helps us optimize the design and properties of piezoelectric transducers for sensing and energy harvesting in different use cases. You will also learn how we apply microfluidic simulations to improve roll-to-roll micro- and nanoimprint processes for functional surfaces.
Get a brief overview of the COMSOL Multiphysics® software, with a focus on the field of microelectromechanical systems (MEMS).
Learn how to model linear and nonlinear material behaviors; fluid-, acoustic-, and thermal-structural interactions; MEMS applications; and more.
Learn about the modeling tools available in COMSOL Multiphysics® to simulate piezoelectric devices such as transducers, actuators, and harvesters. We will go over the modeling steps required for piezoelectric simulations and multiphysics couplings such as coupling with pressure acoustics as well as coupling with fluid flow and electrical circuits.
Learn about the capabilities of the AC/DC Module for modeling Maxwell's equations in the low-frequency regime. Use cases include resistive and capacitive devices, inductors and coils, as well as motors and magnets.
Learn about using the Ray Optics Module and Wave Optics Module for optics and photonics applications.
Sensitivity analysis can be used to identify important parameters that can then be changed manually or automatically using optimization. Optimization of these parameters enhances the performance of your product. In the case of manufacturing uncertainties, it is possible to compute several objectives and optimize for the worst of them. You will see several examples of how optimization can be set up in the COMSOL® user interface.
Design of Metasurfaces
One can design optical components by engineering features with the same order of magnitude as the light wavelength. In this talk, we want to present strategies for how to design and simulate such structures. We will show examples of implementable structures and how to estimate and evaluate their optical performance.
Get an introduction to the capabilities of the COMSOL Multiphysics® software for modeling the interactions between acoustic waves and structural vibrations, including techniques for improving both model accuracy and runtime. Plus, learn about advanced postprocessing for acoustic waves.
Learn the fundamental workflow of the COMSOL Multiphysics® modeling environment. This introductory demonstration will show you the process of transforming models into specialized simulation applications and distributing them with COMSOL Compiler™ and COMSOL Server™, application deployment products.
Get a brief overview of using the Heat Transfer Module within the COMSOL® software environment. We will discuss conjugate heat transfer with the combination of heat transfer in solids and heat transfer in fluids, including thermal radiation effects. These phenomena could also be coupled with structural mechanics, chemical reactions, and particle tracing.
Learn about the capabilities of the RF Module, Wave Optics Module, and Ray Optics Module for simulating high-frequency electromagnetic waves and rays. Topics include the analysis of microwave, photonics, and optical components including waveguides, antennas, lenses, and high-power laser systems. We will also address the coupling of electromagnetics simulations to other physics, such as heat transfer, including RF heating and STOP analysis.
Get an overview of using the Batteries & Fuel Cells Module within the COMSOL® software environment for modeling batteries and fuel cells. Aspects related to the transport of ions and current, porous electrodes, and electrode reactions relevant to both applications will be covered. We will address the simulation of lithium-ion battery power and capacity using realistic vehicle drive cycles, modeling of thermal effects on both cell and pack levels, safety aspects, and modeling of capacity fade. In addition, you will get an introduction to different types of models, from low cost to high fidelity. We will discuss aspects related to parameters and parameterization for models, including the simulation of electrochemical impedance spectroscopy (EIS) data.
Learn how to model electromagnetic heating for low- and high-frequency electromagnetics applications. Important electromagnetic heating phenomena covered include Joule heating, induction heating, RF heating, and laser heating.