Events

IEEE  Distinguished Lecturer Presentation hosted jointly by the IEEE Ottawa EMC and CASS/SSCS/EDS Chapters:

Speaker  :     Dr. Marcos Rubinstein, Professor, University of Applied Sciences of Western Switzerland

Topic    :     The Lightning Phenomenon

Date     :     Tuesday October 22, 2019

Time     :     12(noon) – 1pm

Location :     4124-ME (Meckenzie Building), Carleton University, 1125 Colonel By Drive, Ottawa – K1S5B6

Registration:  Free, Please E-mail Ram Achar (achar@doe.carleton.ca)

Refreshments: Served

Parking  : Payment based Metered Parking spots in the campus

Organizers:

               Ram Achar, Dept. of Electronics, Carleton University

               Chairman CASS/SSCS/EDS Chapters

               achar@doe.carleton.ca

               Dr. Syed Bokhari, Chairman, IEEE Ottawa EMC chapter

Abstract

Lightning is one of the primary causes of damage and malfunction of telecommunication and power networks and one of the leading causes of weather-related deaths and injuries.

Lightning is composed of numerous physical processes, of which only a few are visible to the naked eye.

This lecture presents various aspects of the lightning phenomenon, its main processes and the technologies that have been developed to assess the parameters that are important for engineering and scientific applications. These parameters include the channel-base current and its associated electromagnetic fields.

The measurement techniques for these parameters are intrinsically difficult due to the randomness of the phenomenon and to the harsh electromagnetic environment created by the lightning itself.

Besides the measurement of the lightning parameters, warning and insurance applications require the real-time detection and location of the lightning strike point. The main classical and emerging lightning detection and location techniques, including those used in currently available commercial lightning location systems will be described in the lecture. The newly proposed Electromagnetic Time Reversal technique, which has the potential to revolutionize lightning location will also be presented.

Biography

Marcos Rubinstein received the Master’s and Ph.D. degrees in electrical engineering from the University of Florida, Gainesville.

In the decade of the 1990’s, he worked as a research engineer at the Swiss Federal Institute of Technology, Lausanne and as a program manager at Swisscom in the areas of electromagnetic compatibility and lightning. Since 2001, he is a professor at the University of Applied Sciences of Western Switzerland HES-SO, Yverdon-les-Bains, where he is currently responsible for the advanced Communication Technologies Group. He is the author or coauthor of 300 scientific publications in reviewed journals and international conferences. He is also the coauthor of nine book chapters and the co-editor of a book on time reversal. He served as the Editor-in-Chief of the Open Atmospheric Science Journal, and currently serves as an Associate Editor of the IEEE Transactions on EMC.

Prof. Rubinstein received the best Master’s Thesis award from the University of Florida, the IEEE achievement award and he is a co-recipient of the NASA’s Recognition for Innovative Technological Work award. He also received the ICLP Karl Berger award. He is a Fellow of the IEEE and an EMP Fellow, a member of the Swiss Academy of Sciences and of the International Union of Radio Science.

Registration is required. Space is limited!

Attending lecture only is FREE, refreshments will be served.

Attending lecture with lunch afterwards:

• IEEE WIE Members: FREE
• IEEE Members: 10 CAD
• Non-members: 12 CAD

Agenda:

12:00 – 01:00 PM: Seminar

01:00 – 02:00 PM: Lunch

 

Seminar Information:

ABSTRACT:

Given the fast pace of innovation in digital health technologies, specifically in relation to the evolution of medical devices with more complex software and increased network connectivity, a new frontier of cybersecurity vulnerabilities has emerged. As a result, designers of such technologies face many challenges and must consider many inter-related factors that contribute to such an insecure environment.

In this talk, we will identify the key classes of vulnerabilities to which modern medical devices and digital health technologies are exposed, discuss the security and privacy challenges in designing these technologies, and outline some of the defensive measures that can address this complex and multi-faceted problem.

BIOGRAPHY:

Dr. Jason Jaskolka is an Assistant Professor in the Department of Systems and Computer Engineering and the Director of the Cyber Security Evaluation and Assurance (CyberSEA) Research Lab at Carleton University. He received his Ph.D. in Software Engineering in 2015 from McMaster University. His research interests include cybersecurity evaluation and assurance, security-by-design, and formal methods and algebraic approaches for software and security engineering. He is interested in applying his research to critical infrastructures, cyber-physical and distributed systems, and the Internet of Things (IoT).

Lunch Information:

Located on the 3rd Floor Residence Commons, the caf is an all-you-care-to-eat dining hall featuring 14 unique stations that offer a wide variety of food choices. 

More information: https://carleton.campusdish.com/LocationsAndMenus/TheCaf?locationId=5087&storeIds=&mode=Daily&periodId=2084&date=11%2F2%2F2019

Title: 5G for Smart Everything: From Smart Meters to the New Power Grid. What is needed to get there ?

Speaker: Akshay Sharma, Executive Research Fellow, neXtCurve: www.next-curve.com

Date/Time: Tuesday, November 12, 2019, from 2 – 3 pm.

Admission: Free, but registration is required for security purposes. Please contact by e-mail: branislav @ieee.org or ajit.pardasani@ieee.org.

Abstract: This talk discusses how 5G with Edge Computing, and Ultra-low latency (sub-5ms) with Gigabit speed bandwidth will be a game changer with Smart Meters and a new Electric Grid can be enabled with Smart Lamposts. As we transition to DevOps, AIOps, newer Closed Loop Automation systems will occur. As we connect AI-powered Virtual Personal Assistants to IoT devices in the home, now we have to imagine the entire macro-infrastructures being all hyper-connected. What is needed to get there will be discussed at the seminar.

 

Speaker’s Bio: Akshay Sharma is originally from Ottawa, B. Eng Computer Systems Engineering from Carleton, a tech analyst, formerly from Gartner, having authored or co-authored over 280 research notes, on emerging technologies like SD-WAN, 5G, mobile video, cloud CDN, IoT, etc. in the past decade. A frequent speaker at tech events, he is often quoted in leading institutions like CNN, Wall St. Journal, etc. He is a former CTO of one of the first video/WiFi smartphone firms, former Chief Architect at Siemens Mobile, and has been given awards by the NJ IEEE Chapter on talks he gave on 5G and Cybersecurity. He is on the tech advisory board for 5G and DevOps startups: LB-N, Kovair, along with others. Mr Sharma’s recent publications include: Search Results for “akshay” – neXt Curve

IEEE Women in Engineering is pleased to announce a lunch and learn on “Women’s Impact in the Industry” presented by Eng. Mohammed Ali Rencüz

TITLE: Women’s Impact in the Industry

ABSTRACT:

Life in the software engineering world, some networking theory, and women’s impact in the industry!

Location: 4359 Mackenzie Building, Carleton University.

Map: https://carleton.ca/campus/map/

Time: 12:00-2:00 PM

Date: November 30th, 2019

Lecture Admission is FREE!

Lunch: FREE for IEEE WIE members / $12 others

RSVP is required for Lunch: manarhelal@ieee.org

BIOGRAPHY: Carleton University alumnus with B. Eng. Degree in Computer Systems. He is currently working as a Software Engineer in Cisco Systems.

IEEE Photonics Society Distinguished Lecturer Program

Advanced semiconductor lasers:Ultra-low operating energy and heterogeneous integration with Si photonics devices

Shinji Matsuo, NTT Photonics Laboratories, Japan

Abstract: The electrical power consumed in data transmission systems is now hampering efforts to further increase the speed and capacity at various scales, ranging from data centers to microprocessors. Optical interconnects employing an ultralow energy directly modulated lasers will play a key role in reducing the power consumption. Since a laser’s operating energy is proportional to the size of its active volume, developing high-performance lasers with a small cavity is important. For this purpose, we have developed membrane DFB and photonic crystal (PhC) lasers, in which active regions are buried with InP layer. Thanks to the reduction of cavity size and the increase in optical confinement factor, we have achieved extremely small operating energy and demonstrated 4.4-fJ/bit operating energy by employing wavelength-scale PhC cavity. Reduction of the cost is also important issue because huge number of transmitters are required for short distance optical links. For this purpose, Si photonics technology is expected to be a potential solution because it can provide large-scale phonic integrated circuits (PICs), which can reduce the assembly cost compared with transmitters constructed by discrete devices. Therefore, heterogeneous integration of III-V compound semiconductors and Si has attracted much attention. For fabricating these devices, we have developed wafer-scale fabrication procedure that employs regrowth of III-V compound semiconductors on directly bonded thin InP template on SiO2/Si substrate. A key to realize high-quality epitaxial layer is total thickness, which must be below the critical thickness, typically 430 nm. Thus, membrane structure is quite suitable for heterogeneous integration. I will talk about our recent progress, focusing on ultralow-powerconsumption directly modulated lasers and their photonic integrated circuit. I will also describe progress in heterogeneous integration of these lasers and Si photonics devices.

Bio: Dr. Matsuo received a B.E. and M.E. degrees in electrical engineering from Hiroshima University, Hiroshima, Japan, in 1986 and 1988, and the Ph.D. degree in electronics and applied physics from Tokyo Institute of Technology, Tokyo, Japan, in 2008. In 1988, he joined NTT Optoelectronics Laboratories, Atsugi, where he was engaged in research on photonic functional devices using MQW-pin modulators and VCSELs. In 1997, he researched optical networks using WDM technologies at NTT Network Innovation Laboratories, Yokosuka. Since 2000, he has been researching InP-based photonic integrated circuits including fast tunable lasers and photonic crystal lasers at NTT Photonics Laboratories, Atsugi. Dr. Matsuo is a member of the IEEE Photonics Society, Japan Society of Applied Physics and the Institute of Electronics, Information and Communication Engineers (IEICE) of Japan.