IEEE Dayton Section

[] Prof. Shlomi Dolev, Executive Director of the BGU-Negev Hi-Tech Faculty Startup Accelerator, will present on Post Quantum Internet. The need for a post-quantum Internet is emerging, and this is a great opportunity to re-examine the legacy of public key infrastructure. There is a need for perspective on the evolution of cryptography over the years, including the perfect information-theoretical secure schemes and the computationally secure schemes, in particular. There is also a need to examine the evolving Internet infrastructure to identify efficient design and secure cryptographic schemes over the existing Internet infrastructure. A combination of overlay security, blockchain, and Merkle trees with Lamport’s signatures offers just such an easily implementable post-quantum Internet over the existing Internet. The talk will cover recent research that resulted in start-ups creation initiatives, including Secret Double Octopus, SecretSkyDB, SodsBC. Speaker(s): Prof. Shlomi Dolev, Virtual: https://events.vtools.ieee.org/m/414083

Simulation-driven design changed product development forever, enabling engineers to reduce design, iterations, and prototype testing. Increasing scientific computing power expanded the opportunity to apply analysis, making large design studies possible within the timing constraints of a program. Now engineering adoption of Artificial Intelligence (AI) and Machine Learning (ML) is transforming product development again. Combination of physics-based simulation-driven design with machine learning, leveraging the latest in high-performance cloud computing, enables industry to explore more and identify high-potential designs – while rejecting low-potential concepts – even earlier in development cycles as well as help create “Digital Twins”. With the increase in connected devices and platforms (such as 5G, 6G, C-V2X, ADAS etc.), advanced computational electromagnetic (CEM) tools have become part of the product design cycle. Now numerical simulations can be performed to evaluate the effects of antenna design, placement, radiation hazard, EMC/EMI, etc. for wide ranging industry applications. Interfacing with propagation tools, system level design can be accomplished that includes operating environment of the devices for device connectivity and throughput. Advent of cloud computing and AI/ML, and convergence with CEM simulations made connected, smart device design faster with reduced time from concept to the market propelling productivity and innovation. This talk will focus on advanced CEM simulation tools that incorporate numerical methods, such as Method of Moments (MoM), Multilevel Fast Multipole Method (MLFMM), Finite Element Method (FEM), Finite Difference Time Domain (FDTD), Physical Optics (PO), Ray Lunching Geometrical Optics (RL-GO), and Uniform Theory of Diffraction (UTD). As the complexity of connected devices increases each day, designers are taking advantage of AI/ML to generate trained models for their physical antenna designs and perform fast and intelligent optimization on these trained models. Using the trained models, different optimization algorithms and goals can be run quickly, in seconds, that can be utilized for comparison studies, stochastic analysis for tolerance studies etc. Use of cloud computing combined with AI/ML, many design iterations can be performed in a short period and reducing the time to market. This talk will also focus on future trends in cloud computing for physics-based simulations and the emerging topics such as Digital Twins. Co-sponsored by: Wright-Patt Multi-Intelligence Development Consortium (WPMDC), The DOD & DOE Communities Speaker(s): C.J. Reddy Agenda: Simulation-driven design changed product development forever, enabling engineers to reduce design, iterations, and prototype testing. Increasing scientific computing power expanded the opportunity to apply analysis, making large design studies possible within the timing constraints of a program. Now engineering adoption of Artificial Intelligence (AI) and Machine Learning (ML) is transforming product development again. Combination of physics-based simulation-driven design with machine learning, leveraging the latest in high-performance cloud computing, enables industry to explore more and identify high-potential designs – while rejecting low-potential concepts – even earlier in development cycles as well as help create “Digital Twins”. With the increase in connected devices and platforms (such as 5G, 6G, C-V2X, ADAS etc.), advanced computational electromagnetic (CEM) tools have become part of the product design cycle. Now numerical simulations can be performed to evaluate the effects of antenna design, placement, radiation hazard, EMC/EMI, etc. for wide ranging industry applications. Interfacing with propagation tools, system level design can be accomplished that includes operating environment of the devices for device connectivity and throughput. Advent of cloud computing and AI/ML, and convergence with CEM simulations made connected, smart device design faster with reduced time from concept to the market propelling productivity and innovation. This talk will focus on advanced CEM simulation tools that incorporate numerical methods, such as Method of Moments (MoM), Multilevel Fast Multipole Method (MLFMM), Finite Element Method (FEM), Finite Difference Time Domain (FDTD), Physical Optics (PO), Ray Lunching Geometrical Optics (RL-GO), and Uniform Theory of Diffraction (UTD). As the complexity of connected devices increases each day, designers are taking advantage of AI/ML to generate trained models for their physical antenna designs and perform fast and intelligent optimization on these trained models. Using the trained models, different optimization algorithms and goals can be run quickly, in seconds, that can be utilized for comparison studies, stochastic analysis for tolerance studies etc. Use of cloud computing combined with AI/ML, many design iterations can be performed in a short period and reducing the time to market. This talk will also focus on future trends in cloud computing for physics-based simulations and the emerging topics such as Digital Twins. Virtual: https://events.vtools.ieee.org/m/410052

On Saturday, April 13th, 2024 the IEEE Dayton Section will host its annual awards banquet to honor outstanding achievements of its members. The reception, dinner, and award presentations will be at the Charity Earley Auditorium of the Ponitz Center of Sinclair Community College. During the event, members will also have opportunity to recognize and encourage local middle and high school students for their science fair projects, and Dayton-area graduate students. As a special element of the banquet, the keynote address will be given by prominent engineer Dr. Carrie Root, who wil speak on Work-Life Balance and Generationally Informed Decisions. Parking for the event is in the garage to the Ponitz Center, Sinclair Community College, and guests will receive a parking voucher at the event. The garage entrance is located at the corner of Perry St (N-S) and W. Fourth St (E-W), and the entrance to the Charity Earley Auditorium is at the north side of the garage. The awards to be presented are: - IEEE Dayton Section Harrell V. Noble Award: given to an outstanding candidate who has made significant contributions to the research, development, and/or application of electronic devices or in education, or management in the area of electronic devices. - IEEE Dayton Section Ravi Pallerla Memorial Award for Young Professionals: given to an outstanding young professional in the Dayton Section who has made a significant technology-related contribution in one of the following fields: engineering, business, management, marketing, or law. - IEEE Dayton Section Industrial Energy and Power (PEAL) Award: given to an outstanding IEEE member in the Dayton Section to recognize exceptional contributions in the field of Industry Applications, Power and Energy, or Power Electronics. - IEEE Dayton Section Aerospace and Electronic Systems Society (AES) Award: given to an outstanding IEEE member in the Dayton Section to recognize exceptional contributions in the field of Aerospace and Electronic Systems. - IEEE Dayton Section Photonics Society (PHO) Award: given to an outstanding IEEE member in the Dayton Section to recognize exceptional contributions in the field of Photonics. - IEEE Dayton Section Computer Society (CS) Award: given to an outstanding IEEE member in the Dayton Section to recognize exceptional contributions in the field of Computing. For additional information, contact the event hosts David and Katherine Perez at the link below (Contact Event Host). Speaker(s): Dr. Carrie Root Agenda: 5:30 – 6:00 Registration, Science Fair Projects (middle & high school) & cash bar 6:00 – 6:45 Dinner 6:45 – 7:45 Keynote Speaker 7:45 – 8:45 Award Presentations 8:45 – 9:00 Door Prizes Guests are welcome to remain afterwards until the Center closes at 10:00 pm. Bldg: Ponitz Center , 444 W Third St, Sinclair Community College, Dayton, Ohio, United States, 45402