Title:

Design of Embedded Systems

Code:NAV
Ac.Year:2019/2020
Sem:Summer
Curriculums:
ProgrammeField/
Specialization
YearDuty
IT-MSC-2MBI-Compulsory-Elective - group C
IT-MSC-2MBS-Compulsory-Elective - group C
IT-MSC-2MGM-Elective
IT-MSC-2MIN-Elective
IT-MSC-2MIS-Elective
IT-MSC-2MMM-Elective
IT-MSC-2MPV2ndCompulsory
IT-MSC-2MSK2ndCompulsory-Elective - group C
MITAINADE-Compulsory
MITAINBIO-Elective
MITAINCPS-Compulsory
MITAINEMB-Compulsory
MITAINGRI-Elective
MITAINHPC-Elective
MITAINIDE-Elective
MITAINISD-Elective
MITAINISY-Elective
MITAINMAL-Elective
MITAINMAT-Elective
MITAINNET-Elective
MITAINSEC-Elective
MITAINSEN-Elective
MITAINSPE-Elective
MITAINVER-Elective
MITAINVIZ-Elective
Language of Instruction:Czech
Credits:5
Completion:examination (written)
Type of
instruction:
Hour/semLecturesSeminar
Exercises
Laboratory
Exercises
Computer
Exercises
Other
Hours:26016010
 ExamsTestsExercisesLaboratoriesOther
Points:60150817
Guarantor:Růžička Richard, doc. Ing., Ph.D., MBA (DCSY)
Deputy guarantor:Strnadel Josef, Ing., Ph.D. (DCSY)
Lecturer:Růžička Richard, doc. Ing., Ph.D., MBA (DCSY)
Instructor:Šimek Václav, Ing. (DCSY)
Faculty:Faculty of Information Technology BUT
Department:Department of Computer Systems FIT BUT
Prerequisites: 
Hardware/Software Codesign (HSC), DCSY
Schedule:
DayLessonWeekRoomStartEndLect.Gr.Groups
WedlecturelecturesG202 08:0009:501MIT 2MIT MPV xx
 
Learning objectives:
  To develop knowledge gained in courses from the area of computer systems construction and demonstrate these principles in the field of  embedded systems design and integration. To utilize this knowledge in the design and implementation of complex digital systems with comprehensive sequential behavior. Students will be taught how to analyze the conditions in which the equipment under design will operate and on the basis of the analysis how to identify the trade-off between price, reliability and dynamic parameters. In laboratory tutorials students will study the structure and operation principles of  embedded systems components and their design in design system environment.
Description:
  The themes of lectures deal with problems that must be solved by a designer during the design of components of an embedded system. Students will become acquainted with the principles of I/O bus system operation and the communication with adapters (communication with memory components, registers, interrupt request generation and its service, DMA request generation and its service). The principles of component design (synthesis) for peripheral operation control will be discussed. The laboratory tutorials will be directed towards the presentation of these principles on a computer structure in a design system environment.
Knowledge and skills required for the course:
  
  • Knowledge of programming in an assembly language and C language, basics of VHDL.
  • Knowledge of electronic circuit principles and computer architectures.
Subject specific learning outcomes and competencies:
  
  • Students will become acquainted with the principles of digital systems design with complex sequential behavior reflecting the conditions in which the application will operate.
  • They will become acquainted with tools to support designer.
  • They will learn how an implementation will be subdivided between software and hardware components.
  • They will learn how to design controllers of independently operating computer systems operating in real environment and communicating with a user or systems on higher level.
Generic learning outcomes and competencies:
  
  • Student learns to design a master's work solo and as a member of a team.
  • Student learns terminology in Czech and English language.
Syllabus of lectures:
 
  1. Embedded system, design techniques, specification, embedded system requirement.
  2. Selection of an appropriate platform, microcontroller. Pros and cons of using micro-controller in various situations.Other options how to implement an embedded system.
  3. Hardware and software approach to embedded system functions.
  4. Digital inputs, binary information processing, digital outputs, two-state actuators control, extending digital inputs and outputs.
  5. Analog input and output, converters, comparators, control of analog actuators.
  6. Sensors and their interfacing to an embedded system. Modern types of sensors.
  7. Human interaction of embedded system, keyboard, status and general information visualization, LED displays, LCD character-based and graphics displays.
  8. Communication inside embedded system with multiple processors, communication with external systems, serial synchronous and asynchronous, parallel, widespread protocols, networks.
  9. System level design, design of a System on Chip (SoC).
  10. How to design and realise an embedded system on a PCB, techniqes and constraints of PCB design.
  11. Power supply and power consumption of an embedded systems. Principles and techniques of power savin.
  12. Typical software architecture of embedded system. Styles and techniques used in embedded software.
  13. Debugging and diagnostics of embedded systems.
Syllabus of laboratory exercises:
 
  • A minimal embedded computer system with a MCU.
  • Expanding MCU outputs practically.
  • Communication between MCU and a peripheral or a sensor.
  • Push-pull driver and H-bridge control.
Syllabus - others, projects and individual work of students:
 
  • Basic design of a small embedded system.
Fundamental literature:
 
  • Don Anderson: Universal Serial Bus System Architecture, Addison Wesley, 2001, ISBN 0201309750, 544 pages
  • Jonathan Corbet, Alessandro Rubini, Greg Kroah-Hartman: Linux Device Drivers, 3rd Edition, O'Reilly Media, 2005, ISBN-10: 0596005903, 640 pages
  • Jonathan W. Valvano: Embedded Microcomputer Systems, Real Time Interfacing. Brooks/Cole, 2000, ISBN 0-534-36642-2.
  • Ken Arnold: Embedded Controller Hardware Design. LLH Technology Publishing, 2001, ISBN 1-878707-52-3.
  • Stuart R. Ball: Embedded Microprocessor Systems: Real World Design. Newnes, 2002, ISBN 0-7506-7534-9.
Study literature:
 
  • Daniele Lacamera: Embedded Systems Architecture - Explore architectural concepts, pragmatic design patterns, and best practices to produce robust system. Packt Publishing, 2018, ISBN 978-1788832502.
  • Stuart R. Ball: Embedded Microprocessor Systems: Real World Design. Newnes, 2002, ISBN 0-7506-7534-9.
  • Jonathan W. Valvano: Embedded Microcomputer Systems, Real Time Interfacing. Brooks/Cole, 2000, ISBN 0-534-36642-2.
Progress assessment:
  
  • Lab experiments - 8 points.
  • Evaluated project with the defense - 17 points.
  • Written mid-term exam - 15 points.
  • Final written examination - 60 points.
 

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