The doctor study programme is devoted to the preparation of the high quality scientific and research specialists in various branches of microelectronics and electrotechnology, namely in theory, design and test of integrated circuits and systems, in semiconductor devices and structures, in smart sensors, in optoelectronics in materials and fabrication processes for electrical engineering, and in sources of electric energy.
The aim is to provide the doctor education in all these particular branches to students educated in university magister study, to make deeper their theoretical knowledge, to give them also requisite special knowledge and practical skills and to teach them methods of scientific work.

The doctors are able to solve scientific and complex engineering tasks from the area of microelectronics and electrical technology
Wide fundamentals and deep theoretical basis of the study program bring high adaptability and high qualification of doctors for the most of requirements of their future creative practice in all areas of
microelectronics and electrotechnology.
The doctors are competent to work as scientists and researchers in many areas of basic research or research and development, as high-specialists in the development, design, construction, and application areas in many institutions, companies, and organisations of the electrical and electronics research, development, and industry as in the areas of electrical services and systems, inclusively in the special institutions of the state administration. In all of these branches they are able to work also as the leading scientific-, research-, development- or technical managers.

The graduate of the doctoral study programme is able to solve scientific and complex engineering tasks in the field of microelectronics and technology for electrical engineering. The graduate has reached a high level of general theoretical knowledge in the branch and is further specialized in the area of his/her dissertation thesis.
Having broad theoretical knowledge, the PhD graduate is capable of meeting work requirements of both fundamental and applied research. The PhD graduates are sought out as specialists in all branches of microelectronics and technology. They are able to work as research workers, as members of management staff in fundamental or applied research, as design, construction or operation specialists in various research and development institutions, electronics manufacturing firms, and to work for various users of electronic systems and devices. They will be able to employ advanced technology everywhere in a creative way.

prof. Ing. Vladislav Musil, CSc.

1. Effective deployment and interconnection eCAx system in the design and implementation of low-voltage switchboards.

   - Analyze the current state of the design process of the cabinet. - Analyze the current state of the manufacturing process of the cabinet. - Design optimization of both process using eCAx system (EPLAN). - Propose connection with the company's ERP system (SAP). - Propose improvements in automatic processing schemes for documentation of LV switchboards. - Design and implement eCAx connection with the machine for manufacturing conductors KOMAX. - Design and implement the integration of other tools that support production (printing labels, stencils drilling, wiring harnesses, 2D, 3D spatial drawings). - Create a controlled documentation and training for individual employees in the design and implementation phase low voltage switchboards. - Create control documentation for RFF units as template workflows for the design and implementation of low-voltage switchboards.

   Tutor: Maxa Jiří, doc. Ing., Ph.D.

2. Influence of temperature on the scattering of the electron beam of the electron microscope.

   Influence of temperature on the scattering of the electron beam of the electron microscope.

   Tutor: Maxa Jiří, doc. Ing., Ph.D.

3. Methods for determine reliability of solder joint in electronic

   Theoretical study failure phenomenas of solder joint using in electronic. Measuring and simulation (ANSYS) reliability of real solder joints. Determine of diagnostic methodology and define reliability. Determine of fatique coefficients. Core of disertability: Original calculating methodology for determine of fatique coefficients for specific application.

   Tutor: Šandera Josef, doc. Ing., Ph.D.

4. Modeling and simulating processes in the areas of electrical equipment.

   CAE method of use in developing new devices to the company presently crucial for economic and efficient development. Work will deal with deployment methodology and problem solving in the areas of: - Warming the air flow inside the enclosure for different degrees of protection (IP) - Mechanical strength cabinet vibration resistance. - Mechanical testing copper deposit passports - EMC

   Tutor: Maxa Jiří, doc. Ing., Ph.D.

5. Nanoparticles for properties modification of solder pastes using in electronic

   To understand mechanism which influence in behaviour of soder paste. Experiments with various types of nanoparticles added into solder paste. The properties of solder paste will observe. It will be mainly stability, wetability, reliability and melting point. Disertability core: Results of work would be determine of ingredient or technological procedure, which rapidly increase god properties.

   Tutor: Šandera Josef, doc. Ing., Ph.D.

6. New circuit principles for low-voltage low-power analog circuits design.

   Utilizing new circuit principles for low-voltage low-power analog circuit design. These circuits serve mainly in biomedical area. Theoretical design and experimental evaluations using program Cadence with technology 0.35 um from Amis.

   Tutor: Khateb Fabian, prof. Ing. et Ing., Ph.D. et Ph.D.

7. Progressive light sources.

   Research in the field of advanced light sources based on LEDs.

   Tutor: Maxa Jiří, doc. Ing., Ph.D.

8. Residue Number System for using in digital systems

   Residue Number System Based Building Blocks for Applications in Digital Signal Processing

   Tutor: Šteffan Pavel, doc. Ing., Ph.D.

9. SMART microsystems

   SMART microsystems for using in Internet of Things

   Tutor: Šteffan Pavel, doc. Ing., Ph.D.

10. Techology for printed electronics

    Printed electronics is developing rapidly and reaches into all areas of use of electronics, because it allows to produce electronic equipment in an unusual way, in large volumes and usually at very low cost. It is based on the use of new, organic, materials and new or adapted methods of printing. Currently there are already well-developed methods of mass production and development focuses on the design of the equipment. Further extension of application possibilities is expected after the introduction of 3D printing methods.

    Tutor: Boušek Jaroslav, prof. Ing., CSc.