- over twenty years of experience with Finite Element Methods (FEM) for structural, thermal, electromagnetic and fluids analyses for MEMS applications;
- numerical methods referred as Reduced Order Modeling (ROM);
- ANSA, ANSYS Multiphysics, ANSYS Maxwell, ANSYS HFSS, ANSYS CFX, and ANSYS LS-DYNA;
- experience with inertial MEMS sensors design like AE sensors, gyroscope, accelerometer, and pressure sensors;
- dimensional design, layouting, simulation and optimization, characterization;
- BAW filters design for mobile applications (LTE-A);
- simulation of complex LPAMiD RF Front-End Modules (containing PAs, LNAs, Switches and Switchplexers) using ADS, AWR, HFSS;
- PSPICE, Simulink, VHDL-AMS (hAMSter, ANSYS/ANSOFT Simplorer; SystemVision/PartQuest)
- development of simulation methods for nonlinear piezoresistance in p-type silicon;
- anisotropic conductivity implementation in FEM for strain gauge optimization;
- multivariate rational fit;
- parameterized sub-structuring technique;
- parameterization using FEM and mesh morphing;
- parameterized mode superposition-based technique;
- development the library of MEMS/NEMS components in VHDL-AMS;
- integration of the MEMS/NEMS models at the system level;
- microsystem design;
- numerical methods with C;
- mathematical physics;
- sensor electronic;
Vladimir Kolchuzhin - Google Scholar
- Kolchuzhin, V., Markert, E., & Wagner, C. (2015, March 9). Piezoresistance of Single Walled Carbon Nanotube in VHDL-AMS. Zenodo. 10.5281/zenodo.15923
- Kolchuzhin, Vladimir and Mehner, Jan (2015, June 30). System level modeling of the micromirror cell. Zenodo. 10.5281/zenodo.19153
- ISBN 978-3941003163
- ISBN 978-3867764414
- ISBN 978-5778231382