Publication

[1]      N. Al-falahy and O. Y. K. Alani, “Reducing the Exposure to Millimetre Wave Radiation Using Distributed Base Stations in C-RAN Architecture,” in 10th Computer Science & Electronic Engineering Conference (CEEC), 2018, pp. 1–6.

[2]      N. Al-falahy and O. Alani, “Design Considerations of Ultra Dense 5G Network in Millimetre Wave Band,” in The ninth International Conference on Ubiquitous and Future Networks (ICUFN ), 2017, pp. 141–146.

[3]      N. Al-Falahy and O. Alani, “The Impact of Higher Order Sectorisation on the Performance of Millimetre Wave 5G Network,” in The 10th International Conference on Next Generation Mobile Applications, Security and Technologies (NGMAST2016), 2016, pp. 1–5.

[4]      N. Al-Falahy and O. Alani, “Technologies for 5G Networks: Challenges and Opportunities,” IEEE IT Prof., vol. 19, no. 1, pp. 12–20, 2017.

[5]      N. Al-falahy and O. Y. K. Alani, “Millimetre Wave Frequency Band as a Candidate Spectrum for 5G Network Architecture?: A Survey,” Elsevier Phys. Commun., vol. 32, no. DOI:10.1016/j.phycom.2018.11.003, pp. 120–244, 2019.

[6]      N. Al-Falahy and O. Alani, “Supporting Massive M2M Traffic in the Internet of Things Using Millimetre Wave 5G Network,” in 9th Computer Science & Electronic Engineering Conference (CEEC), 2017, pp. 83–88.

[7]      N. Al-falahy and O. Alani, “Network capacity optimisation in millimetre wave band using fractional frequency reuse,” IEEE Access, no. DOI 10.1109/ACCESS.2017.2762338, 2018.

[8]      N. Al-falahy and O. Alani, “The Impact of Base Station Antennas Configuration on the Performance of Millimetre Wave 5G Networks,” in The ninth International Conference on Ubiquitous and Future Networks (ICUFN ), 2017, pp. 636–641.

[9]      N. Al-Falahy and O. Alani, “Improved Capacity and Fairness of Massive Machine Type Communications in Millimetre Wave 5G Network,” Computers, vol. 7, no. DOI:10.3390/computers7010016, pp. 1–19, 2018.

[10]    N. Al-falahy and O. Y. K. Alani, “Coverage and Capacity Improvement of Millimetre Wave 5G Networks Using Remote Radio Heads,” IET Networks, pp. 1–17, 2019.

Lectures

No.	Subjects	Lectures	Stage	File	Video
1	Information Theory	INTRODUCTION TO PROBABILITY	Fourth
2	Information Theory	INTRODUCTION TO INFORMATION THEORY	Fourth
3	Information Theory	Source-Coding Theorem	Fourth
4	Information Theory	Prefix Coding	Fourth
5	Information Theory	Shannon Coding Theorem	Fourth
6	Information Theory	LZ Coding & Data compression	Fourth
7	Information Theory	DISCRETE MEMORYLESS CHANNELS	Fourth
8	Information Theory	Channel Capacity of Discrete memoryless channel	Fourth
9	Information Theory	Binary Erasure Channel	Fourth
10	Information Theory	ERROR DETECTION	Fourth
11	Information Theory	Error Correcting Codes	Fourth
12	Information Theory	CYCLIC CODES	Fourth
13	Information Theory	CONVOLUTIONAL CODES	Fourth
14	Information Theory	Incorrect Decoding of Received Sequence	Fourth
15	Information Theory	Huffman Coding	Fourth
16	Advanced Communications Systems	Introduction	Fourth
17	Advanced Communications Systems	Earth-Orbiting Satellites	Fourth
18	Advanced Communications Systems	Satellite Motion	Fourth
19	Advanced Communications Systems	ORBIT MANOUVERS	Fourth
20	Advanced Communications Systems	Solar Eclipse	Fourth
21	Advanced Communications Systems	PATH LOSS	Fourth
22	Advanced Communications Systems	FRIIS TRANSMISSION FORMULA	Fourth
23	Advanced Communications Systems	RADAR EQUATION	Fourth
24	Advanced Communications Systems	RANGE AMBIGUITY	Fourth
25	Advanced Communications Systems	Spread Spectrum	Fourth
26	Advanced Communications Systems	Direct Sq Spread	Fourth
27	Advanced Communications Systems	Notion of Spread	Fourth
28	Advanced Communications Systems	Freq Hoop Spread	Fourth
29	Advanced Communications Systems	Computer Exp	Fourth
30	Advanced Communications Systems	Spectrum Modulation	Fourth
31	Fundamentals of EE 1	Basic Concepts	First
32	Fundamentals of EE 1	Power and Energy	First
33	Fundamentals of EE 1	Basic Laws	First
34	Fundamentals of EE 1	Series Resistors and Voltage Division	First
35	Fundamentals of EE 1	WYE- Delta Transformations	First
36	Fundamentals of EE 1	Nodal Analysis	First
37	Fundamentals of EE 1	Analysis with Voltage Sources	First
38	Fundamentals of EE 1	Mesh Analysis	First
39	Fundamentals of EE 1	Mesh Analysis with Current Sources	First
40	Fundamentals of EE 1	Linearity Property	First
41	Fundamentals of EE 1	Practice Problem	First
42	Fundamentals of EE 1	Source Transformation	First
43	Fundamentals of EE 1	Thevenin’s Theorem	First
44	Fundamentals of EE 1	Norton’s Theorem	First
45	Fundamentals of EE 1	Maximum Power Transfer	First
46	Fundamentals of EE 2	Capacitors and Inductors	First
47	Fundamentals of EE 2	Series and Parallel Capacitors	First
48	Fundamentals of EE 2	Series and Parallel Inductors	First
49	Fundamentals of EE 2	Phasors	First
50	Fundamentals of EE 2	Phasor Relationships for Circuit Elements	First
51	Fundamentals of EE 2	Kirchhoff’s Laws in The Frequency Domain	First
52	Fundamentals of EE 2	Sinusoidal Steady State Analysis	First
53	Fundamentals of EE 2	Mesh Analysis	First
54	Fundamentals of EE 2	Superposition Theorem	First
55	Fundamentals of EE 2	Source Transformation	First
56	Fundamentals of EE 2	Practice Problem	First
57	Fundamentals of EE 2	AC Power Analysis	First
58	Fundamentals of EE 2	Maximum Average Power Transfer	First
59	Fundamentals of EE 2	Effective of RMS Value	First
60	Fundamentals of EE 2	Apparent Power and Power Factor	First
61	Fundamentals of EE 2	References	First
62	Advanced Communications Systems	References	Fourth
63	Information Theory	References	Fourth

Other

Conferences

The 10th International Conference on Next Generation Mobile Applications, Security and Technologies (NGMAST) – 2016 – Cardiff-UK

The 9th Computer Science & Electronic Engineering Conference (CEEC), 2017, Essex-UK

The 9th International Conference on Ubiquitous and Future Networks (ICUFN )-2017, Milan – Italy

The 10th Computer Science & Electronic Engineering Conference (CEEC), 2019, Essex-UK.