Fakultät für Mathematik und Naturwissenschaften

MS08: Modelling Simulation and Optimization in Electrical Engineering

  1. Idoia Cortes Garcia / Caren Tischendorf, Modelling, Simulation and Optimization in High Frequency Electromagnetics (MS08/1)
    Electrical engineering is an important technology for many recent social and industrial developments. It includes the investigation and application of electrical engineering, electronics and semiconductors. Therein, scientific challenges are often driven by industrial needs and are related to classical and new emerging topics of applied mathematics and scientific computing, i.e., modeling, simulation, optimization, uncertainty quantification, stochastics and data analysis. This minisymposium deals with simulation and optimization techniques for high frequency electromagnetics.

    Tuesday, April 13, 10:20-12:00
    1. 10:20 Adrian Sandu, Michael Günther, Steven Roberts, Linearly Implicit GARK Schemes
    2. 10:45 Alvaro Martin-Cortinas, Valentin De La Rubia, Physics-based model order reduction for CAD in electromagnetics
    3. 11:10 Anna Ziegler, Niklas Georg, Sebastian Schöps, Eigenvalue Tracking based on Shape Morphing and Isogeometric Analysis for Automatic Mode Classification of Accelerator Cavities
    4. 11:35 Mona Fuhrländer, Sebastian Schöps, Efficient yield optimization with limited gradient information
  2. Idoia Cortes Garcia / Oliver Rain, Modelling, Simulation and Optimization in Low Frequency Electromagnetics (MS08/2)
    Electrical engineering is an important technology for many recent social and industrial developments. It includes the investigation and application of electrical engineering, electronics and semiconductors. Therein, scientific challenges are often driven by industrial needs and are related to classical and new emerging topics of applied mathematics and scientific computing, i.e., modeling, simulation, optimization,uncertainty quantification, stochastics and data analysis. This minisymposium deals with simulation and optimization techniques for low frequency electromagnetics.

    Tuesday, April 13, 14:00-15:40
    1. 14:00 Jonas Pade, Idoia Cortes Garcia, Sebastian Schöps, Caren Tischendorf, Waveform relaxation for low frequency coupled field/circuit DAEs: Topological convergence criteria
    2. 14:25 Mads Fromreide, Dolores Gómez, Svenn Anton Halvorsen, Pilar Salgado, An Analytical Model of Inductive effects inside Three-phase Submerged Arc Furnaces
    3. 14:50 Laura D’Angelo, Herbert De Gersem, Quasi-3D Magnetic Field Simulation of Superconducting Devices with Translational Symmetry
    4. 15:15 Dietmar Hömberg, Prerana Das, Modelling and Simulation of High-Frequency Induction Welding
  3. Stephanie Friedhoff / Sebastian Schöps, Modelling, Parallel Simulation and Optimization of Electrical Machines (MS08/3)
    Electrical engineering is an important technology for many recent social and industrial developments. It includes the investigation and application of electrical engineering, electronics and semiconductors. Therein, scientific challenges are often driven by industrial needs and are related to classical and new emerging topics of applied mathematics and scientific computing, i.e., modeling, simulation, optimization, uncertainty quantification, stochastics and data analysis. This minisymposium deals with (efficient) simulation techniques and optimization techniques for electrical machines.

    Tuesday, April 13, 16:00-17:40
    1. 16:00 Jens Hahne, Stephanie Friedhoff, Iryna Kulchytska-Ruchka, Björn Polenz, Sebastian Schöps, Using Time-parallel Simulations in the Design Optimization of Induction Machines
    2. 16:25 Björn Polenz,Stefan Ulbrich, Robust Shape Optimization using Quadratic Models and Model Order Reduction for Electric Motors
    3. 16:50 Denis Korolev, Michael Hinze, A Space-Time Certified Reduced Basis Method for Nonlinear 2-D Magnetoquasistatics Equation
    4. 17:15 Oliver Rain, Daniel Klis, Benjamin Northe, Singular and Nearly Singular Galerkin Integration in Industrial Applications
  4. Luis Bonilla / Vittorio Romano / Giovanni Mascali, Mathematical modeling of charge transport in graphene and low dimensional structures (MS08/4)
    The minisymposium will be concerned with the mathematical modeling and simulation of charge transport in graphene and other 2D materials and in structures, like double gate MOSFETs, nanoribbons and nano-wires, where the presence of confinement effects allows for the formal description of the carrier flow as that of a two dimensional or one dimensional electron gas. Graphene, thanks to its peculiar electrical properties and mechanical properties, is considered as one of the most promising materials for future electron devices. Lately, it has also been realized that, by increasing the miniaturization of devices, hot-spots are observed, that is zones with very high crystal temperature due to the release of energy by high energetic electrons. The effect is particularly relevant in materials with reduced dimensionality and confined structures.

    For these reasons, the minisymposium will foresee the discussion of the following arguments: ab initio calculations to furnish the correct band structures for the materials, e.g. doped graphene or graphene nanoribbons; thermal effects in the crystal lattice; rippling in suspended graphene as result of coupling between elasticity and Dirac fermions; in analytical properties of the Schrödinger equation; Monte Carlo simulations; Wigner transport equation; nonlinear dynamics in charge transport; numerical schemes for the charge carrier transport equation; fluid models deduced from the kinetic transport equations.

    Wednesday, April 14, 10:20-12:00 (Chair: Vittorio Romano)
    1. 10:20 Luis L. Bonilla, Manuel Carretero, Emanuel Mompó, Designing chaotic attractors with semiconductor superlattices for fast generation of true random number sequences
    2. 10:45 Nella Rotundo, On the Existence Results of Solutions of a Drift Diffusion System Modeling the Lateral Photovoltage Scanning Method
    3. 11:10 Patricio Farrell, Stefan Kayser, Nella Rotundo, Modeling and simulation of the lateral photovoltage scanning method
    4. 11:35 Paolo Bordone, Laura Bellentani, Andrea Bertoni, Two-Electron Selective Coupling in an Edge-State Based Conditional Phase Shifter
    Wednesday, April 14, 14:00-15:40 (Chair: Luis Bonilla)
    1. 14:00 Giovanni Mascali, Some Thermal Properties of Graphene
    2. 14:25 Giuseppe Alì, Giovanni Mascali, Carmelo Scuro, Charge Transport in 2D Transition Metal Dichalcogenides
    3. 14:50 Vito Dario Camiola, A Hydrodynamical Model for Charge Transport in Graphene Nanoribbons
    4. 15:15 Marco Coco, Paolo Bordone, Lucio Demeio, Vittorio Romano, The Pauli Principle and the Free Flight Step Analysis in the Monte Carlo Method for Charge Transport in Graphene
    Wednesday, April 14, 16:00-17:40 (Chair: Giovanni Mascali)
    1. 16:00 Vittorio Romano, Giovanni Nastasi, Simulation of Double Gate Graphene Field Effect Transistors
    2. 16:25 Giovanni Nastasi, Vito Dario Camiola, Vittorio Romano, Direct simulation of charge transport in graphene nanoribbons
    3. 16:50 Luigi Barletti, Giovanni Nastasi, Claudia Negulescu, Vittorio Romano, Mathematical modeling of graphene heterojunction devices
    Thursday, April 15, 10:20-12:00 (Chair: Luigi Barletti)
    1. 10:20 Orazio Muscato, Wigner Monte Carlo Simulation of a GaAs Resonant Tunneling Diode
    2. 10:45 Omar Morandi, Quantum Interference of Traveling Waves: Study of the Singularities of Bohm Trajectories around the Nodes of the Quantum Wave Function
    3. 11:10 Francesco Vecil, Jose Miguel Mantas, GPU Implementation of a Schrödinger-Poisson Solver for a Nanoscaled DG MOSFET
  5. Markus Clemens, Quasistatic Field Formulations (MS08/5)

    Thursday, April 15, 14:30-16:10
    1. 14:30 Fotios Kasolis, Marvin-Lucas Henkel, Markus Clemens, Low-Frequency Stable Electro-Quasistatic Field Formulations Based on Continuous Extensions
    2. 14:55 Zsolt Badics, Jozsef Pavo, Sandor Bilicz, Szabolcs Gyimothy, Low-Frequency-Stable Finite-Element Formulation for Electromagnetic Quasistatic (EMQS) Models
    3. 15:20 Hiroyuki Kaimori, Takeshi Mifune, Akihisa Kameari, Darwin Model with Coulomb Gauge in Frequency-Domain Electromagnetic FEM Computation
    4. 15:45 Marvin-Lucas Henkel, Fotios Kasolis, Markus Clemens, A Two-Step Darwin Model in Frequency-Domain for Quasistatic Electromagnetic Field Simulations

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