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Technologies of Mobile Communication Networks
Major: System Administration of Telecommunications Networks
Code of subject: 7.172.02.E.32
Credits: 5.00
Department: Telecommunication
Lecturer: PhD, Maksymyuk Taras
Semester: 2 семестр
Mode of study: денна
Learning outcomes: The learning outcomes of this course detail the following program learning outcomes:
1. Understanding of theories and methods for designing radio engineering and telecommunications systems and networks at a level necessary to solve specialized tasks and practical problems in the professional field.
2. Ability to apply a methodological basis for conducting scientific research in the field of radio electronics and telecommunications.
3. Ability to apply knowledge in the field of information security of radio engineering and telecommunications systems and networks to plan and implement measures, make decisions, and ensure the protection of information and technical systems in professional activities.
4. Ability to apply knowledge in the field of civil defense in professional activities to minimize the impact of emergencies on the functioning of radio engineering and telecommunications systems.
5. Proficiency in the English language at a level sufficient for carrying out professional activities, writing scientific articles, reading, and interpreting international technical standards.
6. Knowledge of technologies for building and functioning, architectures, and protocols of mobile communication systems and networks of 3-5 generations at a level sufficient for their calculation and planning.
7. Knowledge of the basics of building and functioning, architectures, and protocols of heterogeneous mobile communication networks of 4-5 generations at a level sufficient for their calculation and planning.
8. Ability for lifelong learning and continuous professional development in the workplace.
Required prior and related subjects: Previous academic disciplines:
1. Mobile communication systems
Associated and subsequent academic disciplines
1. Software platform development technologies
2. Theory of construction and protocols of information communication networks
Summary of the subject: 1. Development and standardization of mobile communication network technologies.
2. Architecture and principles of building LTE mobile communication networks.
2.1. Current LTE standards and technologies.
2.2. Planning and designing LTE network coverage.
2.3. Planning and designing LTE network coverage in buildings.
3. Structure of the LTE radio interface.
3.1. Channel separation in radio access networks.
3.2. OFDMA technology.
3.3. MIMO technology.
3.4. Radio resource management in LTE networks.
4. Structure of the LTE network core.
4.1. Key differences between LTE core networks and second and third-generation networks.
4.2. LTE protocols.
4.3. Main interfaces in LTE networks.
4.4. Structure of information flows in LTE networks.
4.5. Basic principles of IMS (IP Multimedia Subsystem) architecture.
5. Development of 5th generation (5G) mobile communication networks.
5.1. Requirements and potential technical solutions for 5G mobile communication networks.
5.2. Spectral densification of mobile communication networks.
5.3. Functional features and requirements for 5G mobile communication network radio interfaces.
5.4. Main unsolved problems in heterogeneous 5G mobile communication networks.
6. Radio access technologies for the deployment of Internet of Things (IoT) systems
7. Conclusions and practical recommendations.
Assessment methods and criteria: The midterm assessment is worth 40 points, while the final exam is worth 60 points.
Recommended books: 1. Bhushan N. Network densification: the dominant theme for wireless evolution into 5G / N. Bhushan, Li Junyi, D. Malladi et al. // IEEE Communications Magazine.– USA: Institute of Electrical and Electronics Engineers, 2014 – vol. 52, no. 2 – P.82-89.
2. Hoydis J. Massive MIMO: How Many Antennas Do We Need? / J. Hoydis, S. ten Brink, and M. Debbah // 49th Annual Allerton Conf. Commun., Control, and Computing – Sept. 2011 – P. 545–50
3. Damnjanovic A. A Survey on 3GPP Heterogeneous Networks / A. Damnjanovic, J. Montojo, Y. Wei et al. // IEEE Wireless Communications – USA: Institute of Electrical and Electronics Engineers, 2011 – vol. 18 – no. 3 – P.10-21.
4. Annapureddy S. Coordinated Joint Transmission in WWAN / S. Annapureddy // IEEE Commun. Theory Wksp. – Cancun, Mexico, May 2010.
5. Weiss T. A. Spectrum pooling: An innovative strategy for the enhancement of spectrum efficiency / T. A. Weiss and F. K. Jondral // IEEE Commun. Mag, radio Communications Supplement, Mar. 2004 – vol. 42 – no. 3 – pp. S8–S14
6. C-RAN: The Road Towards Green RAN – White Paper, ver. 3.0 — China: China Mobile Research Institute, Oct. 2011. — 91 p.
7. Choi S.-H. Channel Estimations Using Extended Orthogonal Codes for AF Multiple-Relay Networks Over Frequency-Selective Fading Channels / S.-H. Choi, J.-S. Baek, J.-S. Han, and J.-S. Seo // IEEE Transactions on Vehicular Technology, January 2014 – vol. 63 – no. 1 – P.417-42
8. System and method for distributed input distributed output wireless communications / A. Forenza, R. W. Heath Jr, S. G. Perlman, R. Van der Laan and J. Speck – U.S. Patent No. 8,428,162. Washington, DC: U.S. Patent and Trademark Office, 2013.
9. Lee J.-H. Probabilistic Limited Feedback Precoding in MIMO Interference Channels / J.-H. Lee // IEEE Communications Letters ¬ December, 2012 — vol. 16 – no. 12
10. Insoo N. A Holistic View on Hyper-Dense Heterogeneous and Small Cell Networks / H. Insoo, S. Bongyong, S.S. Soliman // IEEE Communications MagazineUSA: Institute of Electrical and Electronics Engineers, 2013 – vol. 51 – no. 6 – P.20-27
Technologies of Mobile Communication Networks (курсовий проєкт)
Major: System Administration of Telecommunications Networks
Code of subject: 7.172.02.E.34
Credits: 3.00
Department: Telecommunication
Lecturer: PhD, Maksymyuk Taras
Semester: 2 семестр
Mode of study: денна
Learning outcomes: The learning outcomes of this course detail the following program learning outcomes:
1. Understanding of theories and methods for designing radio engineering and telecommunications systems and networks at a level necessary to solve specialized tasks and practical problems in the professional field.
2. Ability to apply a methodological basis for conducting scientific research in the field of radio electronics and telecommunications.
3. Ability to apply knowledge in the field of information security of radio engineering and telecommunications systems and networks to plan and implement measures, make decisions, and ensure the protection of information and technical systems in professional activities.
4. Ability to apply knowledge in the field of civil defense in professional activities to minimize the impact of emergencies on the functioning of radio engineering and telecommunications systems.
5. Proficiency in the English language at a level sufficient for carrying out professional activities, writing scientific articles, reading, and interpreting international technical standards.
6. Knowledge of technologies for building and functioning, architectures, and protocols of mobile communication systems and networks of 3-5 generations at a level sufficient for their calculation and planning.
7. Knowledge of the basics of building and functioning, architectures, and protocols of heterogeneous mobile communication networks of 4-5 generations at a level sufficient for their calculation and planning.
8. Ability for lifelong learning and continuous professional development in the workplace.
Required prior and related subjects: Previous academic disciplines:
1. Mobile communication systems
Associated and subsequent academic disciplines
1. Software platform development technologies
2. Theory of construction and protocols of information communication networks
Summary of the subject: The term project is designed for practical acquisition by students of skills and abilities in the use of methods, techniques, and tools intended for planning and designing mobile communication networks of the fourth and fifth generation standards, as well as mastering the use of relevant standards and other regulatory and professional literature, in particular, in English, which regulates the requirements for project work in the field of telecommunications networks.
Assessment methods and criteria: The current control in the form of verification by the teacher of parts of the course project (course work) according to the description of the stages of the course project (course work) execution.
The final control in the form of defending the course project (course work).
Current control - 45 points
Checking the text and graphic part of the course project - 25 points
Defense of the course project - 30 points
Recommended books: 1. Bhushan N. Network densification: the dominant theme for wireless evolution into 5G / N. Bhushan, Li Junyi, D. Malladi et al. // IEEE Communications Magazine.– USA: Institute of Electrical and Electronics Engineers, 2014 – vol. 52, no. 2 – P.82-89.
2. Hoydis J. Massive MIMO: How Many Antennas Do We Need? / J. Hoydis, S. ten Brink, and M. Debbah // 49th Annual Allerton Conf. Commun., Control, and Computing – Sept. 2011 – P. 545–50
3. Damnjanovic A. A Survey on 3GPP Heterogeneous Networks / A. Damnjanovic, J. Montojo, Y. Wei et al. // IEEE Wireless Communications – USA: Institute of Electrical and Electronics Engineers, 2011 – vol. 18 – no. 3 – P.10-21.
4. Annapureddy S. Coordinated Joint Transmission in WWAN / S. Annapureddy // IEEE Commun. Theory Wksp. – Cancun, Mexico, May 2010.
5. Weiss T. A. Spectrum pooling: An innovative strategy for the enhancement of spectrum efficiency / T. A. Weiss and F. K. Jondral // IEEE Commun. Mag, radio Communications Supplement, Mar. 2004 – vol. 42 – no. 3 – pp. S8–S14
6. C-RAN: The Road Towards Green RAN – White Paper, ver. 3.0 — China: China Mobile Research Institute, Oct. 2011. — 91 p.
7. Choi S.-H. Channel Estimations Using Extended Orthogonal Codes for AF Multiple-Relay Networks Over Frequency-Selective Fading Channels / S.-H. Choi, J.-S. Baek, J.-S. Han, and J.-S. Seo // IEEE Transactions on Vehicular Technology, January 2014 – vol. 63 – no. 1 – P.417-42
8. System and method for distributed input distributed output wireless communications / A. Forenza, R. W. Heath Jr, S. G. Perlman, R. Van der Laan and J. Speck – U.S. Patent No. 8,428,162. Washington, DC: U.S. Patent and Trademark Office, 2013.
9. Lee J.-H. Probabilistic Limited Feedback Precoding in MIMO Interference Channels / J.-H. Lee // IEEE Communications Letters ¬ December, 2012 — vol. 16 – no. 12
10. Insoo N. A Holistic View on Hyper-Dense Heterogeneous and Small Cell Networks / H. Insoo, S. Bongyong, S.S. Soliman // IEEE Communications MagazineUSA: Institute of Electrical and Electronics Engineers, 2013 – vol. 51 – no. 6 – P.20-27