13M051IoT - IoT Systems

Course specification
Course title		IoT Systems
Acronym		13M051IoT
Study programme		Electrical Engineering and Computing
Module		Applied Mathematics, Audio and Video Communications, Audio and Video Technologies, Biomedical and Environmental Engineering, Biomedical and Nuclear Engineering, Computer Engineering and Informatics, Electronics, Electronics and Digital Systems, Energy Efficiency, Information and Communication Technologies, Microwave Engineering, Nanoelectronics and Photonics, Power Systems - Networks and Systems, Power Systems - Renewable Energy Sources, Power Systems - Substations and Power Equipment, Signals and Systems, Software Engineering, System Engineering and Radio Communications
Type of study		master academic studies
Lecturer (for classes)		professor PhD Aleksandar Rakić professor PhD Ivan Popović
Lecturer/Associate (for practice)		professor PhD Aleksandar Rakić professor PhD Ivan Popović
Lecturer/Associate (for OTC)
ESPB		6.0	Status	elective
Condition		none
The goal		Introduce students to principles, technological basics, available methods of integration and implementation domains of IoT system.
The outcome		Students gain insight into the problem of design and implementation of the IoT systems. They are able to choose an appropriate approach in problem analysis and system design, to define: the system functionality, integration model, to delegate functionalities on the distributed hardware/software modules, as well as to implement functionalities either at the concept level or directly.
Contents
URL to the subject page		https://automatika.etf.bg.ac.rs/sr/13m051iot
URL to lectures		https://teams.microsoft.com/l/team/19%3AtSvugQ-MCdmFK_BAO4AgtjlYKu4fycqkDV_HLzONVrg1%40thread.tacv2/conversations?groupId=158f9fe6-2df3-4c0d-a4c4-3970e5e6bead&tenantId=1774ef2e-9c62-478a-8d3a-fd2a495547ba
Contents of lectures		Integration of control, digital systems, communications and computing. Network-enabled embedded hardware platforms. Architecture and standards of the IoT system; cloud and fog model, design styles for large-scale networks, resource and service oriented architectures, application protocols, security. Applications in industrial control, smart homes and cities, smart grid, precision agriculture, etc.
Contents of exercises		Demonstration and implementation of the existing technological solutions for the implementation of the IoT systems: embedded and general-purpose hardware platforms, development environments, network and application connectivity, various models for integration in application development.
Literature
S.Cirani, G.Ferrari, M.Picone, L.Veltri, Internet of Things: Architectures, Protocols and Standards. UK: John Wiley & Sons, 2018. (Original title) A. Bahga, V. Madisetti, Internet of Things: A hands-on Approach. Madisetti, 2014. (Original title) O. Hersent, D. Boswarthick, O. Elloumi, The Internet of Things: Key Applications and Protocols. John Wiley & Sons, 2012. (Original title) T. Chou, Precision: Principles, Practices and Solutions for the Internet of Things. CrowdStory Publishing, 2016. (Original title)
Number of hours per week during the semester/trimester/year
Lectures	Exercises	OTC	Study and Research	Other classes
3	1
Methods of teaching		Lectures and exercises. Students are obliged to solve and defend the individually assigned project, which earns them the exam points.
Knowledge score (maximum points 100)
Pre obligations		Points	Final exam	Points
Activites during lectures			Test paper	30
Practical lessons			Oral examination
Projects		55
Colloquia		15
Seminars