prof. Ing. Miroslav Husák, CSc.

The dissertation will address the design of a system for wireless charging (mobile phones). The work will address: Modulation principles, intersymbol crosstalk, equalization filters and spectrum access techniques, interference mitigation, design and simulation of digital communication for bit-accurate implementation of ASIC using Matlab and Python tools, code optimization for the selected processor and subsequent design verification on FPGA / PCB processor using LMS, RLS algorithms.

The goal of the Ph.D. thesis is to create a model of GaN structure usable for electronic, sensor and other possible applications. The methodology used for the solution of the work will be based on modeling, simulation, measurement of physical and electrical parameters and possible implementation of the proposed model of GaN structure. Ansys, Coventorware, TCAD and other software will be used. The work will be connected to the European project GaN4AP from the call H2020. The project will be solved in the years 2021-2023.

MEMS DC / DC converter - design and implementation, MEMS structure, actuator and a sensor part, electrostatic control, use of silicon microsystem technology, design of structure, evaluation of parameters, design of management methodology for sensing activities, output voltage, evaluation of losses in system, verification of properties, creating of models, simulations of properties, model realization, evaluating of the activities of the structure, properties compared to standard DC / DC converter. Other information are on the www.micro.feld.cvut.cz

Microgenerators of electrical energy - design and implementation, use of basic physical principles (piezoelectric, electromagnetic, thermal), use of appropriate advanced materials, design of structures, design of material layers, use of polymer layers, use of piezoelectric ceramics, use of integrated components of the electromagnetic system, evaluation electronics - design and implementation, verification of properties, model creation, simulation properties, model realization. Other information on the www.micro.feld.cvut.cz

Design and realization of microaction elements for linear and rotational displacements, utilization of piezoelectric and electrostatic physical principles, design of electronic circuits for stepper control of micro-shifts, design of microsystem structures, design of electronic blocks, use of suitable materials and integrated components, verification of properties, creation of model, simulation of properties, implementation of a model using perspective microstructures. http://www.micro.feld.cvut.cz/

Design and realization of microsensors (physical or chemical variables), use basic sensing principles, modern materials, design of evaluation electronics, verification of properties, model creation, simulation properties, implementation (on-chip). Other information on the www.micro.feld.cvut.cz