Montreal, Quebec, Canada
• Experienced wireless engineering researcher with over 7 years of solid experience in algorithm design, simulation, and performance evaluation of wireless communication systems. • Excellent academic background, and the ability to learn fast a variety of new techniques and interested in learning new technologies. • Able to work on own initiative or as part of a team, can deal with administrative duties competently using the available resources effectively efficiently. • Excellent communication and presentation skills, proven leadership skills involving managing, developing, and motivating teams to achieve objectives. Research and Teaching Assistant Activities: [2015-01 – Present ] Research and Teaching Assistant, Concordia University, Montreal, QC, Canada. Research Activities: • Implemented accurate system level simulators using MATLAB and Mathematica to investigate the impact of different types of blockages on the performance of Mm-Wave cellular systems to achieve rigorous requirements of the diverse use cases for 5G and beyond networks. • Analyzed the impact of blockages on Handover Probability for 5G Mobile Users, including: Static, Dynamic and self-blockages. • Considered 5G standards in designing the system models and the system parameters and leveraged stochastic geometry to model and analyze the impact of different blockages models on resource allocation in 5G Mm-Wave Cellular Systems to achieve high network reliability, low latency, high spectral and energy efficiencies. • Developed D2D selection technique for the internet of things (IoT) devices in Mm-Wave systems by leveraging stochastic geometry to model the system, considering the impact of blockages on Mm-Wave signals. • Conducted weekly tutorials and lab sessions, marking assignment, lab reports and quizzes, and organizing examinations and online submissions for courses including: Introduction to Telecommunication Networks, Introduction to Digital Communication, and Digital Signal Processing. Supervised undergraduate graduation projects, administered and supervised computer laboratory tasks.
5G and 6G Cellular Networks, Mm-Wave Communication, High Altitude Platform Stations, Heterogeneous Networks, Implementation of AI (Artificial Intelligence) in the future generation of cellular systems.
Teaching courses: Data Communication and Computer Networks, Telecommunication Networks, Cellular Systems, Wireless Communication Systems, Introduction to Microprocessors, Microprocessor Programming.
Head of the Graduate Studies Department, Supervising graduation projects in higher professional education, Teaching courses: Information Theory, Data Communication and Computer Networks, Computer Applications Using MATLAB.
Teaching courses: Advanced Wireless Communication Systems, Multi-Media Networks.
Performance analysis of 5G and beyond based Non-Terrestrial Networks (NTN): Developing dynamic wireless system-level simulation using MATLAB, Python and Mathematica to analyze and evaluate the system performance for 5G radio technology and beyond based NTN including: High-Altitude Platform Station (HAPS), UAVs and GEO and LEO Satellite systems. • Proposing innovative technology solutions for control and transfer of user data at the physical and protocol layers. • Analyzing HAPS system capacity using mm-wave communication considering the distance limitations in Ku, K, Ka and V bands and comparing the capacity of mm-wave bands with the capacity of Sub-6 GHz band-based systems. • Link budget analysis of Non-Terrestrial Networks (NTN) including: Path loss analysis in different scenarios, Received power calculations, SNR, SINR, RSSI, RSRP and RSRQ, BER and latency. • Performance and capacity analysis of NTN system with multiple layers, including HAPS system, GEO Satellite, LEO Satellite, UAVs and on ground station, by considering different scenarios and different configuration. • Developing dynamic wireless system-level simulation platform and tools to support the evaluation and analysis of technology solutions for 5G radio and beyond.