Eletrónica

Base Knowledge

Electric circuits analysis techniques

Teaching Methodologies

Theoretical classes: given in classic theoretical lecture classes, exposing the contents recurring to audiovisual resources and a blackboard

Theoretical-Practical classes: problem solving

Laboratory classes: experimental work with real components, applying and measuring signals with test equipment in order to assess the correct functioning of circuits and the role of semiconductor components. Implementation and test of circuits designed by students (of small complexity).

Learning Results

Goals

Know and understand the functioning of the various semiconductor devices and its application in simple electronic systems.

Analysis and design of electronic circuits of basic to medium complexity is also a goal to achieve.

 

Skills

Know and understand the operation of semiconductor devices.

Analyze and understand the features and technical specifications of the components used in electronic circuits.

Analyze, Design and Implement analog electronic circuits of basic complexity .

Know and use correctly test and measurement equipment.

Develop the ability to do group work and to write technical reports.

Use simulation tools (Spice).

Program

1. Semiconductor devices and junctions

1.1. Energy bands; mobility and conductivity. Intrinsic and doped semiconductors. Notion of dopant – acceptors (p-type) and donors (n-type).

1.2. The PN junction and its characteristics.

2. Diodes

2.1. The semiconductor diode: operation principle and functioning curves.

2.2. Rectifier circuits: half-wave, full wave and bridge.

2.3. Limiting circuits.

2.4. Zener diodes and their application.

2.5. Fixing and multiplier circuits.

2.6. Other diodes and their application: LED, photodiode, Varicap and Schottky.

3. Bipolar (BJT) and Field Effect (JFET and MOSFET) transistors

3.1. Operation principle.

3.2. Obtaining characteristic curves and operating regions: cutting, active and saturation.

3.3. Logic Gates with BJTs.

3.4. Operation of the junction FET, main characteristics and characteristic curves.

3.5. MOSFETs: enhancement and depletion. Obtaining input and output characteristic curves. Operating zones.

3.6. Use of MOSFETs in digital circuits.

4. Bias circuits for bipolar and field effect transistors

4.1. Study of classic circuits for DC Bias with BJTs. Bias point and its stability.

4.2. Circuits for DC bias with JFET and MOSFETs. Bias point and its stability.

5. Other devices (DIAC, SCR, TRIAC)

6. Small signal analysis of amplifier circuits

6.1. With Bipolar transistors

6.1.1. The hybrid model.

6.1.2. Study of base amplifiers with BJTs (Common Emitter, Common Colector and Common Base).

6.2. Field Effect Transistor (FET)

6.2.1. FET Hybrid model for small signal analysis.

6.2.2. Study of base amplifiers with FETs (JFETs and MOSFETs) in diverse configurations.

6.3. Cascade amplifier analysis.

6.4. Static and dynamic load line.

Curricular Unit Teachers

Internship(s)

NAO

Bibliography

Boylestad, R. and Nashelsky, L. (2013). Dispositivos Electrónicos e Teoria dos Circuitos (11ª Edição), Prentice-Hall do Brasil.
Malvino, A. (2007). Princípios de Electrónica, Vol. 1 e 2, Sétima Edição. McGraw-Hill.
Malvino, A. and Bates, D. (2015). Electronic Principles (8th Edition). McGraw-Hill Education.
Sedra, A. and Smith, K. (2014) Microelectronic Circuits (7th Edition). Oxford University Press.
Marques, L. (2021) Slides used in theoretical classes. Availabe in UC moodle page.
Marques, L. (2021). LTSpice simulador Manual/Tutorial. Availabe in UC moodle page.
Marques, L. (2021). Sheets with electronic circuits problems. Availabe in UC moodle page.