From Propagation Models to Physics-Based Digital Twins of Emerging Wireless Communication Systems
FROM PROPAGATION MODELS TO PHYSICS-BASED DIGITAL TWINS
OF EMERGING WIRELESS COMMUNICATION SYSTEMS
By Dr. COSTAS SARRIS
WHEN: November 12th at 10H30 AM EST
VIA ZOOM: https://uqtr.zoom.us/j/81521084215?pwd=bchQDndZg7DTlpVuaeag6bhGwaOvn9.1
Meeting ID : 815 2108 4215
Password : 018477
The continuous proliferation of wireless technologies, from 5G communications to the Internet of Things, creates a compelling need to intelligently plan the deployment of such systems in indoor and outdoor environments. This planning is required to meet the desired Quality of Service objectives (e.g. high bit-rates for Wi-Fi networks) along with safety standards for exposure of users to radiated emissions, and to ensure compatibility with existing systems. Wireless propagation modeling, which is the prediction of the electromagnetic field levels generated by a wireless communication system, is an essential element of such an intelligent planning process. These models can be deduced by numerical algorithms based on the physics of electromagnetic wave propagation, or by measurements.
Software-based planning is a reality in several areas, including the design of environmentally friendly buildings, where simulation tools are used to optimize heat and air flow. The question is how to enable a similar approach for wireless infrastructure that is becoming as indispensable as any other infrastructure element.
This presentation is aimed at demonstrating that machine learning enabled propagation models can address this question, overcoming the dichotomy between accuracy and efficiency that has dominated this area for decades. We give an overview of the most recent advances in the field, including neural networks that can accurately predict, in real-time, signal strength levels of indoor and outdoor wireless networks by processing the geometry and the position of one or more transmitters. We discuss the use of such models for the rapid placement of massive numbers of access points of wireless networks, such as those providing wireless connectivity to spectators in large sports venues. Finally, we show that this research leads to reliable “digital twins” of wireless communication systems. These are robust computational models that allow for the full evaluation of the performance of wireless networks, under changes in the environment and the conditions of operation over time.
BIOGRAPHY
Dr. Costas Sarris is a Professor with the Department of Electrical and Computer Engineering, University of Toronto. His research area is computational electromagnetics, with an emphasis on time-domain modeling. He also works on physics-based wireless propagation models (with full-wave, asymptotic, and hybrid techniques), uncertainty quantification, and scientific machine learning.
Dr. Sarris is an IEEE Fellow and a Distinguished Lecturer of the IEEE Antennas and Propagation Society for 2024-2026. He was a recipient of the 2021 Premium Award for Best Paper in IET Microwaves, Antennas & Propagation, and the IEEE MTT-S Outstanding Young Engineer Award in 2013. He was the TPC Chair of the 2015 IEEE AP-S International Symposium on Antennas and Propagation and the CNC/USNC Joint Meeting, the 2019 and 2023 MTT-S Numerical Electromagnetics, Multiphysics and Optimization (NEMO) Conference, the TPC Vice-Chair of the 2012 IEEE MTT-S International Microwave Symposium, and the Chair of the MTT-S Technical Committee on Field Theory and Numerical Electromagnetics (2018–2020). In 2019-2024, he was the Editor-in-Chief of the IEEE JOURNAL ON MULTISCALE AND MULTIPHYSICS COMPUTATIONAL TECHNIQUES.
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- Starts 23 October 2025 04:00 AM UTC
- Ends 12 November 2025 05:00 AM UTC
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Dr. Sarris
From Propagation Models to Physics-Based Digital Twins of Emerging Wireless Communication Systems
Abstract:
The continuous proliferation of wireless technologies, from 5G communications to the Internet of Things, creates a compelling need to intelligently plan the deployment of such systems in indoor and outdoor environments. This planning is required to meet the desired Quality of Service objectives (e.g. high bit-rates for Wi-Fi networks) along with safety standards for exposure of users to radiated emissions, and to ensure compatibility with existing systems. Wireless propagation modeling, which is the prediction of the electromagnetic field levels generated by a wireless communication system, is an essential element of such an intelligent planning process. These models can be deduced by numerical algorithms based on the physics of electromagnetic wave propagation, or by measurements.
Software-based planning is a reality in several areas, including the design of environmentally friendly buildings, where simulation tools are used to optimize heat and air flow. The question is how to enable a similar approach for wireless infrastructure that is becoming as indispensable as any other infrastructure element.
This presentation is aimed at demonstrating that machine learning enabled propagation models can address this question, overcoming the dichotomy between accuracy and efficiency that has dominated this area for decades. We give an overview of the most recent advances in the field, including neural networks that can accurately predict, in real-time, signal strength levels of indoor and outdoor wireless networks by processing the geometry and the position of one or more transmitters. We discuss the use of such models for the rapid placement of massive numbers of access points of wireless networks, such as those providing wireless connectivity to spectators in large sports venues. Finally, we show that this research leads to reliable “digital twins” of wireless communication systems. These are robust computational models that allow for the full evaluation of the performance of wireless networks, under changes in the environment and the conditions of operation over time.
Biography:
Dr. Costas Sarris is a Professor with the Department of Electrical and Computer Engineering, University of Toronto. His research area is computational electromagnetics, with an emphasis on time-domain modeling. He also works on physics-based wireless propagation models (with full-wave, asymptotic, and hybrid techniques), uncertainty quantification, and scientific machine learning.
Dr. Sarris is an IEEE Fellow and a Distinguished Lecturer of the IEEE Antennas and Propagation Society for 2024-2026. He was a recipient of the 2021 Premium Award for Best Paper in IET Microwaves, Antennas & Propagation, and the IEEE MTT-S Outstanding Young Engineer Award in 2013. He was the TPC Chair of the 2015 IEEE AP-S International Symposium on Antennas and Propagation and the CNC/USNC Joint Meeting, the 2019 and 2023 MTT-S Numerical Electromagnetics, Multiphysics and Optimization (NEMO) Conference, the TPC Vice-Chair of the 2012 IEEE MTT-S International Microwave Symposium, and the Chair of the MTT-S Technical Committee on Field Theory and Numerical Electromagnetics (2018–2020). In 2019-2024, he was the Editor-in-Chief of the IEEE JOURNAL ON MULTISCALE AND MULTIPHYSICS COMPUTATIONAL TECHNIQUES.
Email:
Address:Department of Electrical and Computer Engineering, University of Toronto, Toronto, Quebec, Canada