BEGIN:VCALENDAR VERSION:2.0 PRODID:IEEE vTools.Events//EN CALSCALE:GREGORIAN BEGIN:VTIMEZONE TZID:Australia/Victoria BEGIN:DAYLIGHT DTSTART:20201004T030000 TZOFFSETFROM:+1000 TZOFFSETTO:+1100 RRULE:FREQ=YEARLY;BYDAY=1SU;BYMONTH=10 TZNAME:AEDT END:DAYLIGHT BEGIN:STANDARD DTSTART:20210404T020000 TZOFFSETFROM:+1100 TZOFFSETTO:+1000 RRULE:FREQ=YEARLY;BYDAY=1SU;BYMONTH=4 TZNAME:AEST END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTAMP:20201012T025639Z UID:3EB93E7F-9E94-4A7D-8B7D-630639056D6C DTSTART;TZID=Australia/Victoria:20201009T180000 DTEND;TZID=Australia/Victoria:20201009T190000 DESCRIPTION:Prof. Dr. Levent Svegi\, IEEE AP-S Distinguished Lecturer\n\nTh e role of Electromagnetic (EM) fields in our lives has been increasing. Co mmunication\, remote sensing\, integrated command/ control/surveillance sy stems\, intelligent transportation systems\, medicine\, environment\, educ ation\, marketing\, defense are only a few areas where EM fields have crit ical importance. We have witnessed the transformation from Engineering Ele ctromagnetics to Electromagnetic Engineering for the last few decades afte r being surrounded by EM waves everywhere. Among many others\, EM engineer ing deals with broad range of problems from antenna design to EM scatterin g\, indoor–outdoor radiowave propagation to wireless communication\, rad ar systems to integrated surveillance\, subsurface imaging to novel materi als\, EM compatibility to nano-systems\, electroacoustic devices to electr o-optical systems\, etc. The range of the devices we use in our daily life has extended from DC up to Terahertz frequencies. We have had both large- scale (kilometers-wide) and small-scale (nanometers) EM systems. Large por tion of these systems are broadband and digital\, and have to operate in c lose proximity that results in severe EM interference problems. Engineers have to take EM issues into account from the earliest possible design stag es. This necessitates establishing an intelligent balance between strong m athematical background (theory)\, engineering experience (practice)\, and modeling and numerical computations (simulation).\n\nThis keynote lecture aims at a broad-brush look at certain teaching / training challenges that confront wave-oriented EM engineering in the 21st century\, in a complex c omputer and technology-driven world with rapidly shifting societal and tec hnical priorities.\n\nThe lecture also discusses modeling and simulation s trategies pertaining to complex EM problems and supplies several user-frie ndly virtual tools\, most of which have been presented in the IEEE AP Maga zine and which are very effective in teaching and training in lectures suc h as EM Wave Theory\, Antennas and Radiowave Propagation\, EM Scattering a nd Diffraction\, Guided Wave Theory\, Microstrip Circuit Design\, Radar Cr oss Section Prediction\, Transmission Lines\, Metamaterials\, etc.\n\nCo-s ponsored by: AP-S chapters in Australia\n\nSpeaker(s): Prof. Dr. Levent Sv egi\, \n\nVirtual: https://events.vtools.ieee.org/m/241379 LOCATION:Virtual: https://events.vtools.ieee.org/m/241379 ORGANIZER:e.vinnal@ieee.org SEQUENCE:5 SUMMARY:From Engineering Electromagnetics to Electromagnetic Engineering: T eaching/Training Next Generations URL;VALUE=URI:https://events.vtools.ieee.org/m/241379 X-ALT-DESC:Description: <br /><p>Prof. Dr. Levent Svegi\, IEEE AP-S Disting uished Lecturer</p>\n<p>The role of Electromagnetic (EM) fields in our liv es has been increasing. Communication\, remote sensing\, integrated comman d/ control/surveillance systems\, intelligent transportation systems\, med icine\, environment\, education\, marketing\, defense are only a few areas where EM fields have critical importance. We have witnessed the transform ation from Engineering Electromagnetics to Electromagnetic Engineering for the last few decades after being surrounded by EM waves everywhere. Among many others\, EM engineering deals with broad range of problems from ante nna design to EM scattering\, indoor&ndash\;outdoor radiowave propagation to wireless communication\, radar systems to integrated surveillance\, sub surface imaging to novel materials\, EM compatibility to nano-systems\, el ectroacoustic devices to electro-optical systems\, etc. The range of the d evices we use in our daily life has extended from DC up to Terahertz frequ encies. We have had both large-scale (kilometers-wide) and small-scale (na nometers) EM systems. Large portion of these systems are broadband and dig ital\, and have to operate in close proximity that results in severe EM in terference problems. Engineers have to take EM issues into account from th e earliest possible design stages. This necessitates establishing an intel ligent balance between strong mathematical background (theory)\, engineeri ng experience (practice)\, and modeling and numerical computations (simula tion).</p>\n<p>This keynote lecture aims at a broad-brush look at certain teaching / training challenges that confront wave-oriented EM engineering in the 21st century\, in a complex computer and technology-driven world wi th rapidly shifting societal and technical priorities.</p>\n<p>The lecture also discusses modeling and simulation strategies pertaining to complex E M problems and supplies several user-friendly virtual tools\, most of whic h have been presented in the IEEE AP Magazine and which are very effective in teaching and training in lectures such as EM Wave Theory\, Antennas an d Radiowave Propagation\, EM Scattering and Diffraction\, Guided Wave Theo ry\, Microstrip Circuit Design\, Radar Cross Section Prediction\, Transmis sion Lines\, Metamaterials\, etc.</p> END:VEVENT END:VCALENDAR