Code | Completion | Credits | Range | Language |
---|---|---|---|---|
F7ABBEM | Z,ZK | 4 | 2P+2C | English |
Measuring of electric values, principles, using, and parameters. Analogue measuring converters. Electromechanical measuring devices. Current and potential measuring. Frequency and shift phase measuring. Electric work and electric power measuring: direct current, single-phase and three-phase current. Electrical resistance and impedance measuring. Magnetic measuring. Analogue scope. Digitalization, digital signal processing, signal reconstruction. Electronic measuring devices: multimeter, digital scope. Optoelectronic measuring device.
Assessment requirements:
One absence is allowed; in the case of a long-term illness, a replacement exercise must be agreed with the exercise leader.
Keeping a laboratory notebook in A4 format for clear documentation of all laboratory tasks and its approval in the assessment week.
Before the beginning of each laboratory task, each student will have a handwritten preparation for that task in the laboratory notebook. Homework will include a theoretical introduction, wiring diagrams and tables for recording measured data. At the request of the instructor, each student is obliged to submit a laboratory notebook at any time, and the absence of homework in the laboratory diary may be a reason to exclude the student from the laboratory.
Submission of one protocol from laboratory exercises in the required format and its approval. The student will receive up to 15 points for the protocol.
The last 40 minutes of the lecture in the 9th week of the semester will be a semester test, including material included in previous lectures and exercises. The maximum number of points for the semester test is 25 points.
The condition for obtaining the credit is, in addition to the attendance and the notebook, obtaining at least 20 points from the semester.
Exam requirements:
The exam consists of a written part lasting 60 minutes and a voluntary oral part. The content of the exam consists of the content of lectures, including related chapters in the recommended literature, the content of exercises and assigned independent study. It is not allowed to use literature in the exam.
Share of points from exercises and exam in the overall evaluation:
Protocol: maximum 15 points, if submitted in the 13th week, 5 points in case of submission later.
Semester test from the material covered in lectures 1 - 6: 25 points.
The maximum number of points from the written part of the final exam is 60 points. The condition for obtaining the exam is to gain at least 30 points from the written part.
1. Introduction to measurements, metrological properties of measuring insturments. Electromechanical measuring instruments.
2. Measurement error and uncertianity.
3. Measurement of direct current and voltage - standards, selection of measuring instrument and connection into circuits, selection of measuring ranges.
4. Measurements of alternating currents and voltages - standards, selection of measuring instrument and connection into circuits, selection of measuring ranges.
5. Power and energy measurements of direct current, single-phase and three-phase alternating current - measuring techniques and instruments.
6. Measurements of electric resistance using direct current.
7. Frequency and phase shift measurements.
8. Magnetic measurements.
9. Measurements of electric impedances, theory of bridge circuits.
10. Analog measuring converters - operational amplifiers, measuring amplifiers, measuring rectifiers.
11. Basic electronic measuring instruments - digital multimeters, connections of operational amplifiers.
12. Digitalization, digital signal processing and reconstruction of measured signal - signal sampling and samplers, A/D and D/A converters.
13. Multimeters. Analog and digital osciloscopes.
14. Measurement systems - categories, structures, standardized busses. LabVIEW. Exam topics and exampels.
1. Introduction, safety regulations for work in the electro laboratory, laboratory regulations, introduction of measuring devices e.g. power sources, multimeters, oscilloscopes, generators.
2. Simple connections and settings of measuring instruments for practical illustration of Kirchhoff's laws, Ohm's law and linearity of resistances and nonlinearity of diodes.
3. Measurement uncertainties - examples with respect to available measuring instruments.
4. Measurement of direct and alternating currents and voltages, digital multimeter.
5. Measurement of resistances: substitution method, ohm method for small and large resistances.
6. Power measurement for DC and AC quantities.
7. Digital Oscilloscopes: frequency and phase shift measurement.
8. Measurement of resistance and impedances. Measuring bridges, LC meter, equivalent circuit models.
9. Impedance measurement. Serial RLC circuit.
10. Sampling circuit: measuring the influence of the main capacitance on the parameters of the sampled signal.
11. Automated measurements, measuring systems, LabView: applications in biomedical tasks.
12. Measurement of electrical characteristics of multi-ports.
13. Measurement of VA characteristics of semiconductors.
14. RC cells, measurement of frequency amplitude and phase characteristics.
The aim of teaching the subject of electrical measurements at FBMI is to acquire the necessary knowledge and skills of measuring electrical quantities and to understand the principles and properties of the most used measuring instruments. The course is aimed at acquiring practical skills for users of measuring instruments and systems, not for their designers. Therefore, the theoretical part devoted to measuring instruments is limited to the most necessary passages needed to understand the principle and function that are necessary for the correct choice of measuring instruments with respect to the required measurement accuracy.
[1] Haasz, Sedláček: Electrical Measurements. 1. vydání. Praha: ČVUT,
2006.
[2] Sedláček, Haasz: Uncertainties in Electrical Measurement. 1. vydání. Praha: ČVUT, 2004.
[3] VRBA, J. Specific guidelines for the development of laboratory protocols for electrical engineering subjects [online]. Czech Republic, Kladno, CTU in Prague [cit. 2019-02-05] Last modification[18-02-2019]. Available at: https://predmety.fbmi.cvut.cz/cs/F7abbem
[4] VRBA, J. Sample protocol for the subject Electrical Measurements 17ABBEM [online]. Czech Republic, Kladno, CTU in Prague [cit. 2019-02-05] Last modification[18-02-2019].. Available at: https://predmety.fbmi.cvut.cz/cs/F7abbem
Attachment | Size |
---|---|
EM_01_Introduction to Electrical Measurements | 1.88 MB |
EM_02_Measurement Uncertainties | 166.86 KB |
EM_03_Measuring Convertors | 1.67 MB |
EM_04 Measurement of DC current and voltages | 1.59 MB |
EM_05 Measurement of AC current and voltages | 1.66 MB |
EM_06 Measurement of Resistances | 1.69 MB |
EM_08 Measurement of Impedances | 1.7 MB |
EM_09_Measurement of time, frequency and phase shift | 162.42 KB |
EM_10 Convertors and Generators | 1.8 MB |
EM_11_Magnetic measurements | 6.44 MB |
EM_12 Digitalization and Osciloscopes | 1.6 MB |
EM_13 Power and energy measurements | 1.67 MB |
Attachment | Size |
---|---|
1_Resistance and power measurement (2020/2021) | 479.66 KB |
2. Measurement Volt-Ampere Characteristics of Diods | 1.73 MB |
3. Digital Oscilloscopes | 738.72 KB |
4_RC circuits (2020/2021) | 704.53 KB |
5. Verification of Measuring Devices (2020/2021) | 1.19 MB |
6. Measuring Bridges | 70.42 KB |
7. Design, implementation, and verification of multimeter properties (Arduino) | 642.16 KB |
8. Sample and Hold Circuit | 551.04 KB |
9. Measurement of electrical characteristics of frequency dependent two-port network | 68.33 KB |
10. Resonant RLC circuit | 487.95 KB |
LTspice simulation: 4_RC circuits (2020/2021) | 976.14 KB |