FPF:UFPA208 Digital Technology - Course Information
UFPA208 Digital Technology
Faculty of Philosophy and Science in OpavaSummer 2017
- Extent and Intensity
- 2/0/0. 4 credit(s). Type of Completion: zk (examination).
- Teacher(s)
- Ing. Miroslav Vala, CSc. (lecturer)
- Guaranteed by
- Ing. Miroslav Vala, CSc.
Centrum interdisciplinárních studií – Faculty of Philosophy and Science in Opava - Prerequisites (in Czech)
- UFPA120 Physical Foundations of Electr && UFPA121 Physical Foundations Electroni
Znalosti z předchozího studia předmětu Elektronika I na úrovni zápočtu. - Course Enrolment Limitations
- The course is also offered to the students of the fields other than those the course is directly associated with.
- fields of study / plans the course is directly associated with
- Multimedia Technologies (programme FPF, B1702 AplF)
- Course objectives
- The aim of the course is to provide students with basic knowledge of digital technology. The course is designed as a preparatory subject for articles bázujících on knowledge of digital techniques, including: Converters analog and digital signals, measurement systems, PC applications measuring system with a PC etc.
- Syllabus
- Introduction to digital technology. Display numbers in the general numeric base (2, 8, 10 , 16), Boolean algebra and its basic laws. The basic logical operators. The definition of a complete system of logical functions, minimization of complete systems of logic functions. The relationship between the physical structure and logical operators. Symbolic representation of basic operators. Implementation of logic functions by members of NAND and NOR. Definition of logic functions and their description logic equation and truth table, write a logical simplification of algebraic function minimization and Karnaugh method.
The physical realization of logic gates. Basic characteristics of the logic gates . Logical construction technology-based TTL, CMOS : electrical, static and dynamic properties of the members, assembling the product of a three-state outputs. The physical realization of logic gates into the sleeves and engagement. Modification of TTL and CMOS technologies. Application rules.
Combinational logic circuits. Definition of combinational circuits. Implementation sum and součinových functions with a large number of inputs, union and intersection of two binary variables, control of even or odd parity, decoders, multiplexers and demultiplexers, multiplexer as a function generator.
Flip-flops and registers. The principle of RS flip-flop, truth table MS analysis of static and dynamic parameters of the RS flip-flop, flip-flops RS, several entries. Features flip-flops, JK and D. General properties of flip-flops for counting and shifting, memory registers implemented in flip-flops RS, JK and D, the use of synchronous and asynchronous inputs. Implementation of shift registers and their types.
Counters. The principle of synchronous and asynchronous counting. Implementation of synchronous counters in a straight binary code, the equations and diagrams implementation of asynchronous counters in straight binary code. Integrated counter, synchronous counter with synchronous and asynchronous code.
Logic circuits for arithmetic operations. Basic operations on binary arithmetic. Construction adders for positive numbers, truth table, equation scheme. Adder for fast transmission. Using adders in the Subtractor. Comparative circuit, an arithmetic unit.
Memory. Definition of memory, memory technology, the basic parameters. Organization memory bushings, connecting sleeves for greater capacity. Memory with sequential selection and random access. Memory types and their use: RAM, LIFO and FIFO, SRAM and DRAM, PROM, EPROM and EEPROM. Programming memory.
Special circuits. Circuits to enlarge capacity ( driver ), Schmitt trigger, monostable flip-flops and their applications, optoelectronic components, analog multiplexers.
Microprocessor systems. Block diagram of a general microprocessor system, characteristics of individual functional blocks, address, control and data bus. Computer with Harvard architecture and von Neumann computer type. Special microchip with integrated functional blocks.
- Introduction to digital technology. Display numbers in the general numeric base (2, 8, 10 , 16), Boolean algebra and its basic laws. The basic logical operators. The definition of a complete system of logical functions, minimization of complete systems of logic functions. The relationship between the physical structure and logical operators. Symbolic representation of basic operators. Implementation of logic functions by members of NAND and NOR. Definition of logic functions and their description logic equation and truth table, write a logical simplification of algebraic function minimization and Karnaugh method.
- Literature
- recommended literature
- Antošová, Marcela; Davídek, Vratislav. Číslicová technika - učebnice pro SOŠ. KOPP. ISBN 80-723-2206-0. info
- Pinker, Jiří. Mikroprocesory a mikropočítače. BEN, 2004. ISBN 80-730-0110-1. info
- Kesl Jan. Elektronika 3 číslicová technika. BEN, 2003. ISBN 80-7300-076-8. info
- Matoušek David. Číslicová technika základy konstruktérské praxe. BEN, 2002. ISBN 80-7300-025-3. info
- M. Frištacky, M. Kolesár a kol. Logické systémy. ALFA, 1990. ISBN 80-05-00414-1. info
- Bernard J. Od logických obvodů k mikroprocesorům. SNTL, Praha, 1986. info
- Boris Dědina, Pavle Valášek. Mikroprocesory a mikropočítače. SNTL, 1983. info
- J. Z. Sobotka. Přehled číslicových systémů. SNTL, 1981. info
- Teaching methods
- Interactive lecture
One-to-One tutorial - Assessment methods
- Credit
- Language of instruction
- Czech
- Further comments (probably available only in Czech)
- The course can also be completed outside the examination period.
- Teacher's information
- Attendance at seminars min. 75%
Preparation of seminar work (theoretical part to the practices) of digital technology
- Enrolment Statistics (Summer 2017, recent)
- Permalink: https://is.slu.cz/course/fpf/summer2017/UFPA208