Digital Systems
Keywords |
Classification |
Keyword |
OFICIAL |
Physics |
Instance: 2020/2021 - 1S
Cycles of Study/Courses
Teaching language
Suitable for English-speaking students
Objectives
This course provides an introduction to electric circuit theory, basic analog electronics and digital systems.
Learning outcomes and competences
Upon successful completion of the course, the students should be capable of:
- applying Boolean algebra to logic problems;
- recognizing some basic relevant digital circuits and understanding their operation;
Training in Boolean logic, together with examples and solved exercises throughout the course, support these objectives.
Working method
Presencial
Pre-requirements (prior knowledge) and co-requirements (common knowledge)
Arithmetic and logic.
Program
1. Introduction to Digital Electronics
1.1. Digital versus analogic
1.2. Advantages of digital systems
2. Number systems
2.1. Decimal, binary, octal and hexadecimal numbers
2.2. Arithmetic operations
2.3. Two’s complement numbers
2.4. Number system conversion
3. Binary codes
3.1. Binary codes
3.2. Alphanumeric codes
4. Boolean algebra and logic gates
4.1. AND, OR and NOT gates
4.2. NAND and NOR gates
4.3. XOR and XNOR gates
4.4. Inverters
4.5. Universality of NAND gate
5. Simplification of logic circuits
5.1. Boolean expressions of sums of products
5.2. Boolean expressions of products of sums
5.3. Application of De Morgan’s laws
5.4. Using NAND and NOR logic gates
5.5. Karnaugh maps
6. TTL and CMOS integrated circuits
6.1. Integrated circuits and integration levels
6.2. TTL family
6.3. CMOS family
6.4. D/A and A/D conversion
7. Code conversion
7.1. Coding
7.2. Decoding from BCD to decimal
7.3. Decoding from BCD to 7-segment display code
8. Binary arithmetic and arithmetic circuits
8.1. Binary addition and subtraction
8.2. Half- and full-adder circuits
8.3. Half- and full-subtractor circuits
8.4. Parallel adders and subtractors
8.5. Using full-adders
8.6. Using adders for subtraction
8.7. Addition and subtraction in two’s complement
9. Sequential logic circuits
9.1. Multivibrators
9.1.1. SR flip-flop
9.1.2. SR flip-flop with clock
9.1.3. Other types of flip-flops
9.1.4. Astable multivibrators
9.1.5. Monostable multivibrators
9.2. Digital counters
9.2.1. Asynchronous counters
9.2.2. Parallel counters
9.2.3. TTL counters
9.2.4. CMOS counters
9.3. Digital clock
9.4. Latches and tri-state buffers
9.5. Shift registers
9.5.1. Basic configurations of shift registers
9.5.2. TTL shift registers
9.5.3. CMOS shift registers
10. Memory
10.1. RAM memory
10.2. ROM memory
10.3. PROM and EPROM memories
11. Other devices and techniques
11.1. Multiplexer
11.2. Demultiplexer
11.3. Gate arrays and programmable logic devices
11.4. Magnitude comparator
11.5. Digital data transmission
Mandatory literature
Malvino Albert Paul;
Digital principles and applications. ISBN: 0-07-039875-5
Complementary Bibliography
Roger L. Tokheim; Schaum's Outline of Digital Principles, McGraw-Hill Education, 1994
Sedra Adel S.;
Microelectronic circuits. ISBN: 0-03-053237-X
Horowitz Paul;
The art of electronics. ISBN: 0-521-23151-5 (hardcover)
Teaching methods and learning activities
Theory classes (presentation of main topics and examples); problem-solving classes.
keywords
Technological sciences > Engineering > Electronic engineering
Evaluation Type
Evaluation with final exam
Assessment Components
designation |
Weight (%) |
Exame |
100,00 |
Total: |
100,00 |
Amount of time allocated to each course unit
designation |
Time (hours) |
Estudo autónomo |
106,00 |
Frequência das aulas |
56,00 |
Total: |
162,00 |
Eligibility for exams
Students must frequent at least 3/4 of the scheduled problem-solving classes.
Calculation formula of final grade
Grade obtained in the final examination.
Special assessment (TE, DA, ...)
According to FCUP's regulations.
Classification improvement
By improving the grade of the final exam only.