Events

Feb
9
Fri
Lecture: Integrated Quantum Frequency Combs @ University of Ottawa, School of Electrical Engineering and Computer Science (EECS), ARC538, Advanced Research Complex
Feb 9 @ 14:00 – 17:00

The IEEE Ottawa Photonics Society (PS) Chapterand Antennas and Propagation Society and Microwave Theory & Techniques Society (AP/MTT) Joint Chapter, IEEE Ottawa Section (OS), and School of Electrical Engineering and Computer Science (EECS) at University of Ottawa are inviting all interested IEEE members and other engineers, technologists, and students to the IEEE Photonics Society Distinguished Lecture.

Hospitality: Refreshments will be served.
ADMISSION: Free. Registration required. To ensure a seat, please contact Dr. Jianping Yao (jpyao@uottawa.ca) or Dr. Qingsheng Zeng (qzeng@eecs.uottawa.ca)

IEEE Photonics Society Distinguished Lecture

By Dr. Roberto Morandotti
Institut National de la Recherche Scientifique-Centre
Energie, Materiaux et Telecommunications (INRS-EMT)
Université du Quebec

Abstracts

The generation of optical quantum states on an integrated platform will enable low-cost and accessible advances for quantum technologies such as secure communications and quantum computation. We demonstrate that integrated quantum frequency combs (based on high-Q microring resonators made from a CMOS-compatible, high refractive-index glass platform) can enable, among others, the generation of pure heralded single photons, cross-polarized photon pairs, as well as bi- and multi-photon entangled qubit and quDit states over a broad frequency comb covering the S, C, L telecommunications band, constituting an important cornerstone for future practical implementations of photonic  quantum information processing.

Biography

Roberto Morandotti received a M.Sc. in Physics from the University of Genova (Italy) in 1993, and a Ph.D. degree from the University of Glasgow (Scotland) in 1999. From 1999 to 2001, he was with the Weizmann Institute of Science, Rehovot, Israel, and from 2002 to 2003, he was with the University of Toronto, Toronto, ON, Canada, where he worked on the characterization of novel optical structures. In June 2003, he joined the Institut National de la Recherche Scientifique-Centre Energie, Materiaux et Telecommunications (INRS-EMT), Université du Quebec, Montreal, QC, Canada, where he has been a Full Professor since 2008.

He is the author and coauthor of more than 750 papers in international scientific journals (>200, including over 50 contributions to Physical Review Letters, Nature, Science, Nature Photonics, Science Advances, Nature Communication and Physics Report) and conferences. His research interests deal with the linear and nonlinear properties of various structures for integrated optics, nonlinear and quantum optics as well as with nonlinear optics at unusual wavelengths (e.g., THz). Dr. Morandotti is currently serving and/or has served as a Technical Committee Member and a Chair for several Optical Society of America (OSA), Lasers and Electro-Optics Society, IEEE and SPIE meetings. He is an E.W.R. Steacie Memorial Fellow (the most prestigious award for young scientists in Canada), a Fellow of the Royal Society of Canada, and a Fellow of the OSA, APS, SPIE among others.

Feb
14
Wed
Seminar: Optoelectronic Components for Near and Mid Infrared, Based on Ge-Rich SiGe Alloys @ 4124 Mackenzie Building, Carleton Univeristy
Feb 14 @ 14:30 – 16:00

A WIE/Photonics Seminar

Presented by Dr. Vladyslav Vakarin
Postdoctoral Researcher

Date: Wednesday, February 14, 2017
Time: 2:30 to 4:00
Location: 4124 Mackenzie Building

All departments welcome

In collaboration with:

Feb
15
Thu
Seminar: Self-Fulfilling Prophecy in Smart Green Communities; A Game Theory Approach in Transactional Demand @ Algonquin College, T-Building, Room T129
Feb 15 @ 17:35 – 18:35

AGENDA:

  • Refreshments, Registration and Networking: 18:00
  • Seminar: 18:30 – 20:00.

PLACE: Algonquin College, T-Building, Room T129, 1385 Woodroffe Ave., Ottawa.
PARKING: No fee after 5 p.m. at the Parking Lots 8 & 9. Please respect restricted areas

By Dr. Javad Fattahi, University of Ottawa SAGE Lab

Abstract

The immediate consequence of shift from uniform to as-bid pricing would be a radical change in bidding behaviour that would introduce new inefficiencies, weaken competition in new generation, and impede expansion in capacity. Furthermore, using DER and purchasing its power to sew up supplies at favourable rates is not a zero-sum game, and may not obtain those favourable rates that are excepted to be typically obtained at the expense of smaller buyers. To tackle the above mentioned challenges, a self-fulfilling prophecy approach may be used which defines a impartial credit mechanism to deal with the strategic behaviour of big and small players in a shortterm auction game. It can be shown for a N-player dynamic game the Nash Equilibrium (NE) under pay-as-bid pricing will yield a larger and flatten demand being served when demand is elastic. Moreover, this multi-strategy approach can potentially fulfil the other smart-grid needs such as demand response, green house gas reduction and so on. This method is fully aligned with the scalability and interoperability requirements of smart grid standards in the presence of elastic demand.

Speakers Bio

Javad Fattahi received the B.Sc. in Electrical Engineering from Isfahan University of Technology in 2003. He received his M.Sc. in 2011 and Ph.D. in 2015 in Mechatronics Engineering (Control and Robotics) from Sharif University of Technology and the University of Ottawa, respectively. Since then, he has been active in the field in distributed control, power electronics, IoT sensors, and embedded computing as a research associate in the Smart Autonomous Grid Edge laboratory (SAGE-Lab) at uOttawa. His research interests are in the areas related to systems control, including embedded computer control, linear/nonlinear systems, and control systems for advanced motion and power electronics applications.

Mar
23
Fri
Workshop: Lumerical: an industry-standard photonics simulation software @ AP340, Carleton University
Mar 23 @ 13:00 – 16:00

Proudly presented by the IEEE Women-in-Engineering Ottawa Chapter and Carleton University SPIE Student Chapter

Learn to use the industry-standard photonic simulation software from Lumerical

Date: Friday, March 23, 2018

Time: 1:00pm to 4:00pm

Location: AP340 (Carleton University)

Registration: Please email dusan.gostimirovic@carleton.ca to register

Networking: Lunch at 11:30 (FREE with SPIE membership, or $15)

Topics: basics, optimizing your simulation, scripting, Q&A session

Apr
17
Tue
Seminar: Fundamentals and Advances in Power Integrity Modeling and Analysis Methods @ Fidus Systems Inc.
Apr 17 @ 17:00 – 19:00

Speaker : Dr. Ihsan Erdin, Celestica, Ottawa

Topic : Fundamentals and Advances in Power Integrity Modeling and Analysis Methods

Parking : Free

Registration: Free, and is on a first to reply basis. Preference given to IEEE EMC/MTT/AP/CPMT society members. Seating is limited. E-mail Reservation is required. Pizza and soft drinks will be served.

Organizer: Dr. Syed Bokhari, Chairman, IEEE Ottawa EMC chapter
Syed.Bokhari@fidus.com
Office :(613) 595 – 0507 Ext. 377, Cell: (613) 355 – 6632

Dr. Qingsheng Zeng , Chairman of the IEEE Ottawa MTT/AP Chapters
qingsheng.zeng.2011@ieee.org

 

Abstract

For multicore processors with current loads exceeding 100 A, the power noise is not only a growing electromagnetic interference (EMI) concern, but also a potential logic problem in high-speed printed circuit designs. Depending on the type of application, on-board or on-package local decoupling capacitors are the most commonly used components to mitigate this problem. The board/package real-estate concerns, however, impede the haphazard placement of these components and makes imperative the use of optimization methods for their most effective placement and selection. The computation of power noise in high-speed designs lies at the core of all optimization techniques. For decades, the computation methods that rely on lumped circuit theory have been very popular as quick and dirty analysis tools. At today’s circuit speeds, however, they are too simplistic for accurate results. Numerical electromagnetic analysis tools are arguably the reliable alternatives but they are computationally too intensive for repetitive analysis. Semi-analytic algorithms based on planar circuit theory will be discussed as a balance between these two extreme cases. Accuracy and performance comparison with state-of-the art tools will be provided. The practical implications of these methods will be discussed with application to real-life scenarios. {us}

Biography

Ihsan Erdin received the M. Sc. degree from Middle East Tech. U, Ankara, Turkey in 1993 and the Ph.D. degree from Carleton University in 2001, both in electrical engineering. From 1995 to 1996, he was a research fellow at DRDC Ottawa. From 2000 to 2007, he worked as an SI/PI engineer at Nortel in the Passport Project. Since 2007, he has been working in the same job function at Celestica Engineering Design Services in Ottawa. He is an adjunct faculty member with the Electronics Department of Carleton University since 2007. Dr. Erdin is a member of the Professional Engineers Ontario and a senior member of IEEE. He also serves as a member of Signal and Power Integrity Technical Committee (TC-10) of EMC Society. His research interests are analytical methods in electromagnetics as applied to printed and integrated circuit structures.

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