(in Polish) Elektronika 390-FM1-3ELE

Lecture:
Basic Principles of Electronics.
Analog signal, Digital signal. DC and AC voltage; Ohm Law, Kirchhoff’s Laws: KCL, KVL; Gain (Transmittance) of circuits.
Passive electronics elements: resistors, capacitors, inductors; parameters.
RC and LR circuits (filters)
Low-pass filter; High-pass filter;
Frequency response of simple RC circuits.
Amplification of step voltages and pulses.
Semiconductor materials, crystal structures, basic of quantum theory and band theory.
Introduction to p-n junction theory: electrostatics; ideal p-n diode equation. Non-ideal diode description. DC voltage-current characteristics, temperature effects. Reverse bias transition capacitance.
Charge storage and transient behavior. Real diode small- and large- signal models. Junction breakdown;
The Zener, Capacitance, LED, Photodiode and other special types of diodes.
Metal-semiconductor junctions: Schottky diodes, non-rectifying contacts, tunneling.
Bipolar Junction Transistors (BJT); principles of operation; derivation of voltage-current and current gain expressions.
BJT amplifiers configurations – OE, OB and emitter follower. (OC) Benchmark parameters for different configurations.
Theory of Junction Field Effect Transistor (JFET); dc characteristics and ac performance.
Two-terminal MOS structure, MOS capacitors, flat-band and threshold voltages.
Static MOS transistor (MOSFET), principle of working, its equivalent circuit.
MOSFET biasing and amplifier configurations – CS, CG and CD.
Comparison transistors: BJT and MOSFET.
OpAmp as a Black Box. Negative voltage feedback Analysis of linear applications with OpAmps – inverting and non-inverting, voltage follower, adder and subtracter.
Behavioral description of open loop OpAmp’s gain. Gain-bandwidth exchange in OpAmp circuits. Other OpAmp non-idealities and their impact on application performance.
Analysis of linear applications: OpAmp Integrator, OpAmp Differentiators for integration and differentiation configuration, converter current- voltage
OpAmp RC Active filters. Types of filters. Parameters.
Comparators, principle, parameters. Real comparators, with hysteresis loop, without hysteresis loop; Circuits with positive feedback; The RC oscillator
Power supplies
Basic rectifying circuits, - full wave rectifying circuits.
Smoothing circuits: π- sections filters
Other forms of power supply
Electronic regulation of power supplies
Digital Logic Elements:
Boolean Logic, Basic Logic function and selected complex functions.
The Basic of Digital circuits:
Logic gates
Flip-flops
Counters - using Flip-flops (binary and BCD counters)
Logic gates; Parameters of logic gate design: e.g. TTL, CMOS
Analysis of selected logic gate design.
Converters DA and AD
Principles of working of selected converters; parameters.

Term 2022:

Lecture:
Basic Principles of Electronics.
Analog signal, Digital signal. DC and AC voltage; Ohm Law, Kirchhoff’s Laws: KCL, KVL; Gain (Transmittance) of circuits.
Passive electronics elements: resistors, capacitors, inductors; parameters.
RC and LR circuits (filters)
Low-pass filter; High-pass filter;
Frequency response of simple RC circuits.
Amplification of step voltages and pulses.
Semiconductor materials, crystal structures, basic of quantum theory and band theory.
Introduction to p-n junction theory: electrostatics; ideal p-n diode equation. Non-ideal diode description. DC voltage-current characteristics, temperature effects. Reverse bias transition capacitance.
Charge storage and transient behavior. Real diode small- and large- signal models. Junction breakdown;
The Zener, Capacitance, LED, Photodiode and other special types of diodes.
Metal-semiconductor junctions: Schottky diodes, non-rectifying contacts, tunneling.
Bipolar Junction Transistors (BJT); principles of operation; derivation of voltage-current and current gain expressions.
BJT amplifiers configurations – OE, OB and emitter follower. (OC) Benchmark parameters for different configurations.
Theory of Junction Field Effect Transistor (JFET); dc characteristics and ac performance.
Two-terminal MOS structure, MOS capacitors, flat-band and threshold voltages.
Static MOS transistor (MOSFET), principle of working, its equivalent circuit.
MOSFET biasing and amplifier configurations – CS, CG and CD.
Comparison transistors: BJT and MOSFET.
Basic classes of amplifiers. Input and output impedance.
OpAmp as a Black Box. Negative voltage feedback Analysis of linear applications with OpAmps – inverting and non-inverting, voltage follower, adder and subtracter.
Behavioral description of open loop OpAmp’s gain. Gain-bandwidth exchange in OpAmp circuits. Other OpAmp non-idealities and their impact on application performance.
Analysis of linear applications: OpAmp Integrator, OpAmp Differentiators for integration and differentiation configuration, converter current- voltage
OpAmp RC Active filters. Types of filters. Parameters.
Comparators, principle, parameters. Real comparators, with hysteresis loop, without hysteresis loop; Circuits with positive feedback; The RC oscillator
Power supplies
Basic rectifying circuits, - full wave rectifying circuits.
Smoothing circuits: π- sections filters
Other forms of power supply
Electronic regulation of power supplies
Digital Logic Elements:
Boolean Logic, Basic Logic function and selected complex functions.
The Basic of Digital circuits:
Logic gates
Flip-flops;
Counters - using Flip-flops (binary and BCD counters)
Logic gates; Parameters of logic gate design: e.g. TTL, CMOS
Analysis of selected logic gate design.
Converters DA and AD
Principles of working of selected converters; parameters.

Term 2023:

Lecture:
Basic Principles of Electronics.
Analog signal, Digital signal. DC and AC voltage; Ohm Law, Kirchhoff’s Laws: KCL, KVL; Gain (Transmittance) of circuits.
Passive electronics elements: resistors, capacitors, inductors; parameters.
RC and LR circuits (filters)
Low-pass filter; High-pass filter;
Frequency response of simple RC circuits.
Amplification of step voltages and pulses.
Semiconductor materials, crystal structures, basic of quantum theory and band theory.
Introduction to p-n junction theory: electrostatics; ideal p-n diode equation. Non-ideal diode description. DC voltage-current characteristics, temperature effects. Reverse bias transition capacitance.
Charge storage and transient behavior. Real diode small- and large- signal models. Junction breakdown;
The Zener, Capacitance, LED, Photodiode and other special types of diodes.
Metal-semiconductor junctions: Schottky diodes, non-rectifying contacts, tunneling.
Bipolar Junction Transistors (BJT); principles of operation; derivation of voltage-current and current gain expressions.
BJT amplifiers configurations – OE, OB and emitter follower. (OC) Benchmark parameters for different configurations.
Theory of Junction Field Effect Transistor (JFET); dc characteristics and ac performance.
Two-terminal MOS structure, MOS capacitors, flat-band and threshold voltages.
Static MOS transistor (MOSFET), principle of working, its equivalent circuit.
MOSFET biasing and amplifier configurations – CS, CG and CD.
Comparison transistors: BJT and MOSFET.
Basic classes of amplifiers. Input and output impedance.
OpAmp as a Black Box. Negative voltage feedback Analysis of linear applications with OpAmps – inverting and non-inverting, voltage follower, adder and subtracter.
Behavioral description of open loop OpAmp’s gain. Gain-bandwidth exchange in OpAmp circuits. Other OpAmp non-idealities and their impact on application performance.
Analysis of linear applications: OpAmp Integrator, OpAmp Differentiators for integration and differentiation configuration, converter current- voltage
OpAmp RC Active filters. Types of filters. Parameters.
Comparators, principle, parameters. Real comparators, with hysteresis loop, without hysteresis loop; Circuits with positive feedback; The RC oscillator
Power supplies
Basic rectifying circuits, - full wave rectifying circuits.
Smoothing circuits: π- sections filters
Other forms of power supply
Electronic regulation of power supplies
Digital Logic Elements:
Boolean Logic, Basic Logic function and selected complex functions.
The Basic of Digital circuits:
Logic gates
Flip-flops;
Counters - using Flip-flops (binary and BCD counters)
Logic gates; Parameters of logic gate design: e.g. TTL, CMOS
Analysis of selected logic gate design.
Converters DA and AD
Principles of working of selected converters; parameters.

Type of course

obligatory courses

Mode

(in Polish) w sali

Prerequisites (description)

Lecture: Students get acquainted with the basic electrical engineering principles and abstractions on which the design of electronic systems is based. These include lumped circuit models, digital circuits, and operational amplifiers, as well as the physical bases of solid state electronics; Laboratory: Appreciate the practical significance of the systems developed in the course. Build circuits and take measurements of circuit variables using tools such as oscilloscopes, multimeters, and signal generators. Compare the measurements with the behavior predicted by mathematic models and explain the discrepancies;

Course coordinators

Krystyna Perzyńska

Requirements

Electricity and Magnetism
Optics and Waves
Introductory Physics

Prerequisites

Structure of Matter

Learning outcomes

After successfully studying course of Electronics students will be able to: K_W25; X1P_W01; X1P_W05; K_W26; K_W27; K_W30; X1P_W06; K_U16; X1P_U01, K1P_U02; K_U17; X1P_U07; K_U26; X1P_U03; K_K02; X1P_K02; X1P_K03
1. Understand the basic electrical engineering principles and abstractions on which the design of electronic systems is based. These include lumped circuit models, digital circuits, and operational amplifiers;
2. Understand the physical bases of solid state electronics;
3. Build circuits and take measurements of circuit variables using tools such as oscilloscopes, multimeters, and signal generators. Compare the measurements with the behavior predicted by mathematic models and explain the discrepancies;
4. Analyze problems in the field of basic electronics and find their solutions, analyze and formulate conclusions;
5. Use literature and Internet resources to understanding and solving the problems of electronics;
6. Use teamwork skills laboratory, assuming the role of the leader or the coordinator of the experiment;
7. Organize a work and take responsibility for results of his work;
8. Appreciate the practical significance of the systems developed in the course.

Assessment criteria

Weekly consultation.
To gets assessment of laboratory necessary is to execute all of labs, to prepare reports and oral presentation of results. The absence of 50% of the laboratory makes it impossible to obtain credit from the laboratory.
The assessment of labs is necessary condition to exams.

Evaluation of student work:
• assessment of labs ;
• oral exams

Bibliography

1. Agarwal, Anant, and Jeffrey H. Lang. Foundations of Analog and Digital Electronic Circuits. San Mateo, CA: Morgan Kaufmann Publishers, Elsevier, July 2005. ISBN: 9781558607354.
2. Yang E.S. – Microelectronic devices – McGraw Hill 1988
3. Neamen D.A. – Semiconductor Physic and Devices 3rd ed. – Mc Graw Hill 2002
4. Sze S.M. – Semiconductor Devices: physics and technology, 2nd Edition – Wiley 2002
5. B. Razavi Fundamentals of Microelectronics, Willey, 2008
6. A. Sedra, K.C. Smith, Microelectronic Circuits, Oxford UP 2010
7. R. Jaeger, T. Blalock, Microelectronic Circuit Design,McGraw Hill 2003

Additional information

Additional information (registration calendar, class conductors, localization and schedules of classes), might be available in the USOSweb system:

Description of 390-FM1-3ELE in USOSweb