• Semester 6, position 4

Introducing with number systems, Boolean algebra and binary logic, logical functions, as well as mastering their use and manipulation. Mastering methods of analysis and synthesis of combinational logic circuits (LC) as well as synchronous and asynchronous sequential logic circuits. Mastering work with integrated digital circuits, oscilloscope, registers, counters.

Proper understanding of the nature of digital computers and the processes inside them. Manipulating digital computers in hardware and software sense as a part of a digital control system (DCS). Using the methods of analysis and synthesis of LC. Solving computational nature problems related to the analysis and synthesis of LC, in "offline" mode, utilizing digital computers. Analysis and design of real physical LC.

Number systems: conversion, arithmetic, complements, codes. Basic theorems and properties of Boolean algebra and binary logic. Logic functions: forms, logic diagrams, minimization. Combinational logic circuits: analysis, design, arithmetic LC, code converters. Combinational logic circuits with integrated logic circuits: design, adders, magnitude comparator, decoder and demultiplexer, coder and multiplexer, ROM and programmable logic array. Synchronous sequential logic circuits: concept, flip flops, analysis, design. Asynchronous sequential logic circuits: analysis and design. Registers, counters and memory units. Algorithmic sequential logic circuits: flow chart, synchronization, design of control block. A/D and D/А converters: conversion procedures.

PA Examples: Number systems, arithmetic operations. Boolean algebra theorems. Minimizing by map and tabulation methods. Design and analysis of combinational LC. Analysis and design of synchronous sequential LC. Analysis and design of asynchronous sequential LC. Design of counters, algorithmic sequential LC. Various types of A/D and D/А converters. PL: Simulation of binary numbers and BCD code. Physical interpretation of logical operations. Logic gates. Combinational LC, code converters. Design with digital multiplexers. Flip flops, synchronous and asynchronous sequential LC. Counters, registers, memory unit, algorithmic sequential LC. А/D and D/А converters. Application of software. PZ: Logic functions and gates, conventional and integrated combinational LC.

Basic knowledge of higher education mathematics and computer use.

Practicum for laboratory exercises in Digital Systems (in Serbian). Script with lectures and examples (in Serbian). Siemens Simatic PLC, power supply, oscilloscope, breadboard, PCs, software.

Total assigned hours: 75

New material: 20
Elaboration and examples (recapitulation): 10

Auditory exercises: 12
Laboratory exercises: 10
Calculation tasks: 0
Seminar paper: 0
Project: 8
Consultations: 0
Discussion/workshop: 0
Research study work: 0

Review and grading of calculation tasks: 0
Review and grading of lab reports: 0
Review and grading of seminar papers: 0
Review and grading of the project: 5
Test: 5
Test: 0
Final exam: 5

Activity during lectures: 5
Test/test: 50
Laboratory practice: 5
Calculation tasks: 0
Seminar paper: 0
Project: 10
Final exam: 30
Requirement for taking the exam (required number of points): 21

M. Mano, C. Kime, T. Martin, Logic and Computer Design Fundamentals, ISBN: 0-13-376063-4, Pearson, Hoboken, 2015.; T. L. Floyd, Digital Fundamentals, ISBN: 1-292-07598-8, Pearson, London, 2015.; D. P. Leach, A. P. Malvino, G. Saha, Digital principles and applications, ISBN: 0-07-014170-3, McGraw-Hill, New Delhi, 2011.; Z. Bučevac, Laboratory exercises fор discrete digital automatic control systems (in Serbian), ISBN: 86-82271-54-0, Faculty of Mechanical Engineering, Belgrade, 2011.; B. Holdsworth, C. Woods, Digital Logic Design, ISBN: 9780750645829, Newnes, 2002.