Wireless Networks
Structure Type: | Study unit |
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Code: | ITTS3102 |
Type: | Optional obligatory / Professional Studies |
Curriculum: | TT 2018V |
Level: | Bachelor of Engineering |
Year of Study: | 4 (2021-2022) |
Semester: | Autumn |
Credits: | 5 cr |
Responsible Teacher: | Gao, Chao |
Language of Instruction: | English |
Courses During the Academic Year 2021-2022
Impl. | Group(s) | Study Time | Teacher(s) | Language | Enrolment |
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3002 | TT2018-4A, TT2018-4B, TT2018V-4A, TT2018V-4B | 2021-08-23 – 2021-12-19 | Antti Virtanen, Kalevi Ylinen | Finnish | 2021-08-01 – 2021-09-06 |
Learning Outcomes
After completing the course successfully, the student will understand main concepts of wireless communications networks and will be able to compare wireless networks with respect to costs, performance, efficiency, requirements, and applications. They will understand the technical differences between different network standards including cellular networks (GSM, 3G, 4G), WiFi, PANs, etc. Moreover, they will have good knowledge for different aspects about physical layer, mobile channels and radio propagation, medium access control, modulation and coding. Furthermore, there will be several practical experiments to demonstrate important concepts in wireless networks. Emphasis will put on wireless communication and networking for the applications of Internet of Things (IoT) in energy industry.
Student's Workload
135 h, containing 70 h of scheduled contact studies at VAMK and 40 h at University of Vaasa. In weekend studies at VAMK 50 h of contact studies.
The assessment of student’s own learning 1 h is included in contact lessons.
Prerequisites / Recommended Optional Courses
Local Area Networks, Telecommunications.
Contents
The course consists of three parts: a theoretical and a practical part, as well as a seminar.
Theoretical part (VAMK): Signal propagation and wireless channel properties, Modulation and demodulation of radio signals, Cellular basics: reuse factor and capacity, Access technologies (FDMA, TDMA, CDMA, OFDMA), Access technologies (CSMA/CA, ALOHA, and other MAC protocols for short range wireless communications), Cellular network standards (GSM/GPRS/WCDMA/HSPA/LTE), Short-range wireless standards (T/IEEE802.15.4/6LowPAN/LoRa, Routing/Synchronization/Clustering).
Practical part (VAMK): Spectrum analysis, modulation and demodulation in Matlab, PAN: IEEE802.15.4 network constructing and testing, LoRa network constructing and testing.
Seminar part (VY): Beside the intensive theoretical and practical parts, there will be also seminar-type part where each student should prepare a topic in related area and write a small report and present his/her work in a dedicated session. The topics can be determined by the teacher. The purpose of the seminar is to train students for material collection, teach them how to write technical reports and how to present their ideas publically. Moreover, to provide more knowledge about communication networks. However, the following topics are given as examples: Bluetooth Protocols and Industrial applications, Zigbee Protocols and Industrial applications, Ultra-wide-Band Technology for IoT, Wireless Sensor Networks for IoT, Industrial Requirements for Wireless Networks, Wireless Automation, Security in IoT, LTE- Advanced Applications in Industry, 5G and IoT, Wireless Broadband over MIMO-OFDM, IoT Applications in Energy Industry, Satellite Networks.
Recommended or Required Reading and Other Learning Resources/Tools
T. Rappaport, Wireless Communication: Principles and Practice, 2nd Edition, Prentice Hall, 2002. Papers and articles from literature. Material prepared by the teacher.
Mode of Delivery / Planned Learning Activities and Teaching Methods
Lectures, assignments and laboratory exercises.
Assessment Criteria
Grade 5: The student understands most of the concepts discussed on the course, and she is able to combine different wireless communication technologies together to solve a related problem. She has a solid understanding of wireless networks in theory, so that she can continue a research work in this area.
Grade 3: The student understands a considerable portion of course concepts, and is able to develop a given wireless application by selecting a wireless standard or technology which best meets the requirements.
Grade 1: The student understands the basics of wireless communication, such as signal propagation, antenna features, modulation, gain/attenuation, etc., and is able to apply them to wireless communication in practice.
Assessment Methods
Assignments, laboratory exercises, an examination.