1. to evaluate the measurement uncertainty
2. specify the requirements for measuring elements
3. explain the principles of operation of analogue and digital measuring instruments
4. measure the electrical parameters using a digital oscilloscope, a suitable measuring instrument or bridge method
5. measure the force in DC, single-phase and three-phase systems
6. applied engineering approach to problem solving using acquired knowledge in physics, mathematics and electrical engineering basics

Lectures are designed as 12 thematic units that are logically continue each other. Following the lectures, students are introduced to the problem of measuring the spectrum of different quantities, in a wide range of their values​​. The lectures dealt with the computational examples.

Laboratory work provides 12 laboratory exercises that build on material from lectures. During the exercise, students have the opportunity to perform real measurements and apply the knowledge acquired in lectures.

1. Definition of metrology terms, SI system and dissemination of units
2. Standards of electric and magnetic quantities, Least-squares theory
3. Arithmetic mean, Uncertainty of measurement, Coverage factor and effective degree of freedom
4. Measuring resistances, capacitors and inductors, Sources; Cables and displays
5. Measuring amplifiers: application and limits
6. Resolution; Accuracy and sources of errors, Applications and limits of analogue instruments
7. A/D converters in measuring instruments
8. Midterm exam
9. Applications and limits of digital instruments, Transducers with standardized output quantities
10. Null, bridge, direct and comparison methods, Measurement of voltage, current and resistance
11. Measurement of power and energy, Measurement of impedance
12. Measurement of non-electrical quantities
13. Unbalanced bridges, Laboratory communication Interfaces
14. Virtual Instruments, Software for metrology
15. Final exam