Filippo Campagnaro (OES Young Professional 2023-2024) and Hari Vishnu (Acoustic Research Laboratory, National University of Singapore)
On Wednesday, 17 April, 2023, during the OCEANS Conference in Singapore, a panel session related to Ocean Decade observatories took place, titled “Ocean Observing Platforms and Technologies for Ocean Decade: Prospects and Perspectives.” As many of our readers already know, the vision of the Ocean Decade is “the science we need for the ocean we want” and it seeks to stimulate ocean science and knowledge generation to reverse the decline of the state of the ocean system. The 3Ms: Measure, Monitor and Model the ocean data are fundamental to understand the science of our oceans and ocean management. However, the vastness, harsh environment, and accessibility issues to remote areas makes it challenging for observing the oceans widely. Alternatively, the availability of limited platforms and technologies restricts our ability to collect large enough data through sustained and long-term monitoring. Low-cost autonomous platforms and persistent measurement technologies are now shaping the future of the ocean observing systems.
This panel addressed and showcased some of the technologies and platforms that have either been tested and deployed or being developed to increase sustained ocean observing capacity globally. More than 30 people attended the panel that was organised and moderated by Venugopalan Pallayil. Venugopalan, after a quick but inspiring introductory speech, introduced the speakers of the panel. Their names and affiliations are listed below:
- Justin Manley, President of the Marine Technology Society,
- Yi Chao, Founder & CEO of Seatrec,
- Julie Angus, CEO & Co-Founder of Open Ocean robotics,
- Carlos Barrera Rodriguez, VIMAS Head, Oceanic Platform of the Canary Islands – PLOCAN,
- Allan Adams, Physicist and PI of the Future Ocean Lab, MIT,
- Kendra McDonald, Chief Executive Officer Canada’s Ocean Supercluster, and
- Jani Tanzil, Director of the St. Johns Island National Marine laboratory.
The panelists addressed how these emerging ocean observing approaches can contribute on the surface, in water and on the seabed measurements and how it can serve different industry sectors.
Justin mentioned that, when speaking of the “Blue Economy” and “Blue Energy,” everyone thinks about turbines. But the application is not that straightforward as most people think, as you need 2000-3000 windmill turbines to produce enough energy for a city, hence the footprint of such deployment may be very high and so the deployment cost for making energy.
Changing topic, he highlighted another aspect – that smart buoys and mooring systems are collecting precious data, but such deployments are not scalable as they cost millions of US Dollars (USD) and are hard to be deployed. Simpler systems, like Argos, cost a few tens of thousands of USD and are well known for their scalability. Other smaller buoys exist now in the market (with a price of 5k USD) and their deployment may scale even better, indicating these types of systems as promising solutions to help studying the oceans.
Julie Angus addressed another promising technology that can push the study of ocean waters forward, i.e., the use of relatively low-cost Autonomous Surface Vessels (ASVs), with a price of about 100 thousand USD each, equipped with sensors for collecting maritime data. The modular structure of such vessels allows customization sensor payloads and configure the ASVs for any user needs. The data, including the vessel’s mission, can be retrieved in real-time. These solar powered ASVs are a drive towards sustainable operation.
Yi Chao presented how research activities performed by academia can have a significant innovation impact and result in the creation of startups and commercial products. He presented Seatrec’s InfiniTEâ float as a case study. The float measures several water properties including conductivity, temperature and depth along the water column for long periods. The energy harvesting feature of this float provides sustainable operation in the Subsea. He opined that it could be an alternative to Argo floats, but with less impact on the ocean floor as the new system, unlike Argo floats, does not leave anything on the seabed. He also mentioned that these floats can be equipped with additional sensors such as an echosounder for bathymetry mapping and hydrophones for passive acoustic monitoring.
Kendra then presented the Canada’s National Ocean Cluster, a big action and accelerator to fund made-in-Canada solutions for Ocean Energy, sustainable seafood, future transport and ocean climate solutions. She highlighted that national and international funding actions are essential to push the study on the ocean a step forward, by supporting the development of new technology that covers several aspects of ocean science, hence using a holistic approach. This includes, among the others, genomics, fish tracking, satellite data, autonomous vessels, data analysis with AI for various accurate predictions and data retrieval through underwater acoustic communications.
Speaking on the subject of data accessibility, Carlos presented how European level data retrieved by floats, ferries, mooring, gliders, and research vessels is well-organized in several frameworks to provide high quality measurements in standardized databases. This is missing for Unmanned Surface Vessels (USVs), although many USVs already transit from academia to market. They are very capable energy wise due to solar panels and ability to retrieve energy from waves. Many sensors can be installed, and technology is mature, but there is a lack at the network level (technology, mission and operation, etc.). Therefore, at the European level, there is the ongoing European Ocean Observing System (EOOS) project where this problem is in the process of being addressed and more actions are in process with U.S. and Global Ocean Observing System (GOOS).
Finally, Jani presented the Singapore St. Johns Island National Marine laboratory and its facilities, including a research vessel and various resources and infrastructure for experimentation. As part of her ongoing Marine environmental sensing network (MESN) projects, an R&D buoy was developed in a modular way, where one can add and remove sensor modules depending on the observation needs of researchers. She mentioned that for a busy port like Singapore autonomous sensing platforms, such as USVs and ASVs, may not be the best due to limited space and very shallow waters. A research community-based database is made available online to everyone, to help research activities and make the students aware of the environment. There are big challenges on fronts such as “unwanted biodiversity,” or biofouling, that is still an unresolved issue. Jani said she is looking for help on this front if anyone has the solution.
After these inspiring speeches, a Q&A session started, where audiences could interact with the panelists.
In reaction to a question related to whether the world is reacting well enough to address the climate change problem, Justin and Julie agreed that the Blue Economy is going to have to scale a lot in response to this, and we need this for the decarbonization of shipping activities. According to Kendra, Julie and Jani, it is essential to make the general public (and not just scientists or technologists) aware of the impact of climate change, and to show them the easy-to-understand and unequivocable data. The lack of awareness outside of our community of scientists, engineers, educators and technologists, slows down the process, as the whole population, including those outside this community, are the ones driving actions, and convincing politicians with their vote. Following the same theme, Carlos added in another aspect that the technology sooner or later will arrive, but the main problem is regulation to enable it to be applied.
The second question pointed out that oceanography research and monitoring faces problems with vandalisms that cause mooring systems to go missing or out of service sooner than expected. Moreover, all activities related to data retrieval for ocean studies are very expensive and many countries cannot afford them. Carlos answered that in case of vandalism, there is not a lot that can be done, and that the perfect ocean monitoring system does not exist, but it comes from the creation of a system-of-systems where equipment already in place is integrated with new devices, creating a holistic platform. Julie agreed that vandalism is always a risk, but technology can help as, in the case of a USV, you can send another USV if the first gets vandalized without the need of going in with a ship. Moreover, using lower cost assets have less impact if vandalized, and it is more important that the data is retrieved even if the unit is lost, which can now be done thanks to wireless connectivity. Yi stated that it is difficult to make a mooring system vandalism-proof, and redundancy is an option. The defense community is coming out with methodology to reduce the footprint and we will see in the near future if this is applicable. Kendra also agreed that redundancy to have data in real-time through wireless communications is essential so that the data is not lost if the assets get vandalized. It is also important to provide a way to locate the sensor and get it back if it is lost. Justin pointed out that for vandalism, making the sensors “invisible” can help – for example, have them below the water surface like Argo floats.
A comment from the audience highlighted that adding sensors to monitor the ocean is also increasing the ocean pollution. While Justin on the one hand agrees that if sensors are lost they may become a source of pollution, the small pollution they are creating is a small price to pay compared to the importance of the data they are acquiring to help decarbonize the oceans. In fact, this pollution is definitely negligible compared to other human actions.
The next question was related to the use of the data acquired from these observatories, and what steps are needed to facilitate actions starting from data products.
In response, Justin opined that ocean data itself is becoming a business, and without this happening it will be hard to have a strong action. Hence, he advocates for ocean data to be commercialized. Kendra highlighted that there are many actions under the umbrella of the Ocean Decade, and a lot is going on with Artificial Intelligence to make predictions from data. She went on to mention that it is time now to investigate how this information is valuable for aquaculture, defense or other activities. Yi agreed that industry started making sensors and databases without knowing what the customers were doing with the data, and fortunately the new trend is understanding the final use of this data, hence making customization to the final user.
Julie spoke on the fact that lots of intelligence onboard the sensors can allow to classify vessels, do passive acoustics and many other operations. Then, on shore data fusion can be performed with satellite data to better understand what it is happening in a certain area. Jani thought that the main problem in terms of sustainability of the platform, is to have the money for using and maintain such systems in the long term, and to figure out how the data can be useful for policy makers. Carlos highlighted that it is important to understand the role of the people and the institutions in the chain of data management and exportation, as the data itself is only the starting point and the roles on the added value chain must be clarified.
To conclude the panel, the final question addressed to the panelists was on increasing people awareness on ocean topics, and how to prevent possible problems with misinformation and people misunderstanding on these topics. Carlos highlighted the importance of a multidisciplinary approach with new technology and the importance to cooperate with other fields involved in the same project to have a very efficient approach. Jani states that it is essential that the scientific community never sows climate change skepticism. The problem is how do we convey this information to general people, student sharing our knowledge to have a strong impact? This is an important point that needs to be discussed. Julie also agreed that communication to people is very important, and so is working with people and making them feel that new technologies, such as robots, are not about stealing their jobs.
Yi said that, in fact, when mapping the ocean, people ask why the public money is spent to perform this task when there are many other problems directly related to people life. Communication with people is important to make them understand the importance of this activity. Kendra stated that it is a big challenge having the world understanding research as the way the academia communicate is different than how the public communicate. So, we need to put in an effort to simplify our communication and make it more accessible to general public. Finally, Justin mentioned that the problem is that communities make decisions based on emotions and not on data provided by scientists, and for this reason we need to make this information more accessible to avoid this to happen.
Overall, the panel provided many diverse and excellent insights into this important topic of ocean observation in a sustainable and low-cost manner, which is a crucial aspect of the ongoing UN Ocean Decade.
Suleman Mazhar has been working as a professor in Information & Communication Engineering at Harbin Engineering University (China) since July 2019. He did PhD from Tokyo University (Japan) and postdoctorate from Georgetown University (Washington DC, USA). He had BS-CS from FAST-NUCES (Lahore) and MS from GIK Institute (Pakistan). He is TYSP young scientist fellow (Ministry of Science & Technology China) and have won several research grants from international organizations such as DAAD (Germany), ICIMOD (Nepal), NRPU (Higher Education Commission Pakistan), WWF (Worldwide Fund for Nature) Pakistan. His research focus is deep learning and signal processing applications for environmental monitoring, with particular focus on underwater acoustics, and marine mammal conservation. He is a reviewer for professional journals such as Journal of Acoustical Society (America), IEEE Journal of Oceanic Engineering, IEEE Sensors Journal, Applied Acoustics, IEEE Transactions on Intelligent Transportation Systems.
Peng Ren is a full professor with the College of Oceanography and Space Informatics, China University of Petroleum (East China). He is the director of Qingdao International Research Center for Intelligent Forecast and Detection of Oceanic Catastrophes. He received the K. M. Scott Prize from the University of York, the Natural Science award (first rank) from China Institute of Electronics, and the Eduardo Caianiello Best Student Paper Award from 18th International Conference on Image Analysis and Processing as one co-author. He has served as an associate editor of IEEE Transactions on Geoscience and Remote Sensing.
Mohd Rizal Arshad is a full professor at the School of Electrical and Electronic Engineering at Universiti Sains Malaysia (USM), Malaysia, where he specializes in ocean robotics technology and intelligent system. He received his B.Eng. in Medical Electronics & Instrumentation and PhD in Electronic Engineering from University of Liverpool, UK in 1994 and 1999, respectively. He completed his MSc. in Electronic Control Engineering from the University of Salford, UK in Dec 1995. He has supervised many postgraduate students and published extensively in local and international publications. He is a senior member of the IEEE, and was awarded IEEE OES Presidential Award in 2019.
Itzik Klein is an Assistant Professor, heading the Autonomous Navigation and Sensor Fusion Lab, at the Charney School of Marine Sciences, Hatter Department of Marine Technologies, University of Haifa. He is an IEEE Senior Member and a member of the IEEE Journal of Indoor and Seamless Positioning and Navigation (J-ISPIN) Editorial Board. Prior to joining the University of Haifa, he worked at leading companies in Israel on navigation topics for more than 15 years. He has a wide range of experience in navigation systems and sensor fusion from both industry and academic perspectives. His research interests lie in the intersection of artificial intelligence with inertial sensing, sensor fusion, and autonomous underwater vehicles.
John R. Potter (IEEE M’94, SM’02, F’18) graduated in the previous century with a joint honours Mathematics and Physics Degree from Bristol and a PhD. in Glaciology and Oceanography from Cambridge, UK studying Antarctic ice mass balance, where he spent four consecutive summers. This work helped underscore the non-linear fragility of polar ice to climate change and led to him receiving the Polar Medal from Queen Elizabeth II in 1988.
Nick is a Visiting Fellow at the UK National Oceanographic Center, Southampton His nomination was endorsed by the Underwater Acoustics Technology Committee. He had worked as a Research Associate and Lecturer at University of Birmingham and has been working as a Research Scientist at the Applied Research Laboratory, University of Texas, Austin. He has also served as a Program Officer at the Office of Naval Research Global. He is a senior member of IEEE (OES) and a Fellow of Acoustical Society of America (ASA). Nick has also been serving as Assoc. Editor for IEEE JoE and JASA. He is widely acknowledged for his expertise are seabed acoustics, parametric array modeling, sonar beamformer, underwater signal processing.
Maurizio Migliaccio (M’91-SM’00-F’17) is Full professor of Electromagnetics at Università di Napoli Parthenope (Italy) and was Affiliated Full Professor at NOVA Southeastern University, Fort Lauderdale, FL (USA). He has been teaching Microwave Remote Sensing since 1994. He was visiting scientist at Deutsche Forschungsanstalt fur Lüft und Raumfahrt (DLR), Oberpfaffenhofen, Germany. He was member of the Italian Space Agency (ASI) scientific committee. He was member of the ASI CosmoSkyMed second generation panel. He was e-geos AdCom member. He was Italian delegate of the ESA PB-EO board. He was Member of South Africa Expert Review Panel for Space Exploration. He serves as reviewer for the UE, Italian Research Ministry (MIUR), NCST, Kazakhstan and Hong Kong Research board. He lectured in USA, Canada, Brazil, China, Hong Kong, Germany, Spain, Czech Republic, Switzerland and Italy. He was Italian delegate at UE COST SMOS Mode Action. He is listed in the Italian Top Scientists. He is an IEEE Trans. Geoscience and Remote Sensing AE, International Journal of Remote Sensing AE, and was IEEE Journal of Oceanic Engineering AE Special Issue on Radar for Marine and Maritime Remote Sensing, IEEE JSTARS AE of the Special Issue on CosmoSKyMed, Member of the Indian Journal of Radio & Space Physics Editorial board. His main current scientific interests cover SAR sea oil slick and man-made target monitoring, remote sensing for marine and coastal applications, remote sensing for agriculture monitoring, polarimetry, inverse problems for resolution enhancement, reverberating chambers. He published about 160 peer-reviewed journal papers on remote sensing and applied electromagnetics.
He has developed various types of Autonomous Underwater Vehicles (AUVs) and related application technologies including navigation methods, a new sensing method using a chemical sensor, precise seafloor mapping methods, a precise seabed positioning system with a resolution of a few centimeters, a new sensing system of the thickness of cobalt-rich crust; and more. He has shown, by using these technologies that AUVs are practicable and valuable tools for deep-sea exploration.
Donna Kocak has had an outstanding career in defense and scientific projects developing and applying solutions in subsea optics, imaging and robotics. She graduated with an M.Sc in Computer Science in 1997 from the University of Central Florida; an MBA in 2008 from the University of Florida; and M.Sc in Industrial Engineering in 2011 from the University of Central Florida. She is currently a Senior Scientist, Advanced Concepts Engineering, and Fellow at the Harris Corporation in Melbourne, Florida, where she has developed novel optical imaging and communication solutions for under-sea defense and scientific projects. Prior to 2008 Donna Kocak was Founder and President of Green Sky Imaging, LLC (GSI) who developed laser/video photogrammetry software for underwater inspection and survey. Her earlier career positions were with Naval Training Systems Center, Florida; Harbor Branch Oceanographic Institution, Florida; eMerge Interactive; and the Advanced Technologies Group in Florida.
John Potter has a Joint Honours degree in Mathematics and Physics from Bristol University in the UK and a PhD in Glaciology and Oceanography from the University of Cambridge on research in the Antarctic, for which he was awarded the Polar Medal in 1988. John has worked on polar oceanography, underwater acoustics, ambient noise (including imaging), marine mammals, communications, IoUT, autonomous vehicles and strategic development. He has 40 years’ international experience working at the British Antarctic Survey in the UK, NATO in Italy, SIO in California, NUS in Singapore and most recently at NTNU in Norway. John is a Fellow of the IEEE and MTS, an Associate Editor for the IEEE Journal of Oceanic Engineering, IEEE OES Distinguished Lecturer, PADI Master Scuba Diver Trainer & an International Fellow of the Explorer’s Club.
Dr. James V. Candy is the Chief Scientist for Engineering and former Director of the Center for Advanced Signal & Image Sciences at the University of California, Lawrence Livermore National Laboratory. Dr. Candy received a commission in the USAF in 1967 and was a Systems Engineer/Test Director from 1967 to 1971. He has been a Researcher at the Lawrence Livermore National Laboratory since 1976 holding various positions including that of Project Engineer for Signal Processing and Thrust Area Leader for Signal and Control Engineering. Educationally, he received his B.S.E.E. degree from the University of Cincinnati and his M.S.E. and Ph.D. degrees in Electrical Engineering from the University of Florida, Gainesville. He is a registered Control System Engineer in the state of California. He has been an Adjunct Professor at San Francisco State University, University of Santa Clara, and UC Berkeley, Extension teaching graduate courses in signal and image processing. He is an Adjunct Full-Professor at the University of California, Santa Barbara. Dr. Candy is a Fellow of the IEEE and a Fellow of the Acoustical Society of America (ASA) and elected as a Life Member (Fellow) at the University of Cambridge (Clare Hall College). He is a member of Eta Kappa Nu and Phi Kappa Phi honorary societies. He was elected as a Distinguished Alumnus by the University of Cincinnati. Dr. Candy received the IEEE Distinguished Technical Achievement Award for the “development of model-based signal processing in ocean acoustics.” Dr. Candy was selected as a IEEE Distinguished Lecturer for oceanic signal processing as well as presenting an IEEE tutorial on advanced signal processing available through their video website courses. He was nominated for the prestigious Edward Teller Fellowship at Lawrence Livermore National Laboratory. Dr. Candy was awarded the Interdisciplinary Helmholtz-Rayleigh Silver Medal in Signal Processing/Underwater Acoustics by the Acoustical Society of America for his technical contributions. He has published over 225 journal articles, book chapters, and technical reports as well as written three texts in signal processing, “Signal Processing: the Model-Based Approach,” (McGraw-Hill, 1986), “Signal Processing: the Modern Approach,” (McGraw-Hill, 1988), “Model-Based Signal Processing,” (Wiley/IEEE Press, 2006) and “Bayesian Signal Processing: Classical, Modern and Particle Filtering” (Wiley/IEEE Press, 2009). He was the General Chairman of the inaugural 2006 IEEE Nonlinear Statistical Signal Processing Workshop held at the Corpus Christi College, University of Cambridge. He has presented a variety of short courses and tutorials sponsored by the IEEE and ASA in Applied Signal Processing, Spectral Estimation, Advanced Digital Signal Processing, Applied Model-Based Signal Processing, Applied Acoustical Signal Processing, Model-Based Ocean Acoustic Signal Processing and Bayesian Signal Processing for IEEE Oceanic Engineering Society/ASA. He has also presented short courses in Applied Model-Based Signal Processing for the SPIE Optical Society. He is currently the IEEE Chair of the Technical Committee on “Sonar Signal and Image Processing” and was the Chair of the ASA Technical Committee on “Signal Processing in Acoustics” as well as being an Associate Editor for Signal Processing of ASA (on-line JASAXL). He was recently nominated for the Vice Presidency of the ASA and elected as a member of the Administrative Committee of IEEE OES. His research interests include Bayesian estimation, identification, spatial estimation, signal and image processing, array signal processing, nonlinear signal processing, tomography, sonar/radar processing and biomedical applications.
Kenneth Foote is a Senior Scientist at the Woods Hole Oceanographic Institution. He received a B.S. in Electrical Engineering from The George Washington University in 1968, and a Ph.D. in Physics from Brown University in 1973. He was an engineer at Raytheon Company, 1968-1974; postdoctoral scholar at Loughborough University of Technology, 1974-1975; research fellow and substitute lecturer at the University of Bergen, 1975-1981. He began working at the Institute of Marine Research, Bergen, in 1979; joined the Woods Hole Oceanographic Institution in 1999. His general area of expertise is in underwater sound scattering, with applications to the quantification of fish, other aquatic organisms, and physical scatterers in the water column and on the seafloor. In developing and transitioning acoustic methods and instruments to operations at sea, he has worked from 77°N to 55°S.
René Garello, professor at Télécom Bretagne, Fellow IEEE, co-leader of the TOMS (Traitements, Observations et Méthodes Statistiques) research team, in Pôle CID of the UMR CNRS 3192 Lab-STICC.
Professor Mal Heron is Adjunct Professor in the Marine Geophysical Laboratory at James Cook University in Townsville, Australia, and is CEO of Portmap Remote Ocean Sensing Pty Ltd. His PhD work in Auckland, New Zealand, was on radio-wave probing of the ionosphere, and that is reflected in his early ionospheric papers. He changed research fields to the scattering of HF radio waves from the ocean surface during the 1980s. Through the 1990s his research has broadened into oceanographic phenomena which can be studied by remote sensing, including HF radar and salinity mapping from airborne microwave radiometers . Throughout, there have been one-off papers where he has been involved in solving a problem in a cognate area like medical physics, and paleobiogeography. Occasionally, he has diverted into side-tracks like a burst of papers on the effect of bushfires on radio communications. His present project of the Australian Coastal Ocean Radar Network (ACORN) is about the development of new processing methods and applications of HF radar data to address oceanography problems. He is currently promoting the use of high resolution VHF ocean radars, based on the PortMap high resolution radar.
Hanu Singh graduated B.S. ECE and Computer Science (1989) from George Mason University and Ph.D. (1995) from MIT/Woods Hole.He led the development and commercialization of the Seabed AUV, nine of which are in operation at other universities and government laboratories around the world. He was technical lead for development and operations for Polar AUVs (Jaguar and Puma) and towed vehicles(Camper and Seasled), and the development and commercialization of the Jetyak ASVs, 18 of which are currently in use. He was involved in the development of UAS for polar and oceanographic applications, and high resolution multi-sensor acoustic and optical mapping with underwater vehicles on over 55 oceanographic cruises in support of physical oceanography, marine archaeology, biology, fisheries, coral reef studies, geology and geophysics and sea-ice studies. He is an accomplished Research Student advisor and has made strong collaborations across the US (including at MIT, SIO, Stanford, Columbia LDEO) and internationally including in the UK, Australia, Canada, Korea, Taiwan, China, Japan, India, Sweden and Norway. Hanu Singh is currently Chair of the IEEE Ocean Engineering Technology Committee on Autonomous Marine Systems with responsibilities that include organizing the biennial IEEE AUV Conference, 2008 onwards. Associate Editor, IEEE Journal of Oceanic Engineering, 2007-2011. Associate editor, Journal of Field Robotics 2012 onwards.
Milica Stojanovic graduated from the University of Belgrade, Serbia, in 1988, and received the M.S. and Ph.D. degrees in electrical engineering from Northeastern University in Boston, in 1991 and 1993. She was a Principal Scientist at the Massachusetts Institute of Technology, and in 2008 joined Northeastern University, where she is currently a Professor of electrical and computer engineering. She is also a Guest Investigator at the Woods Hole Oceanographic Institution. Milica’s research interests include digital communications theory, statistical signal processing and wireless networks, and their applications to underwater acoustic systems. She has made pioneering contributions to underwater acoustic communications, and her work has been widely cited. She is a Fellow of the IEEE, and serves as an Associate Editor for its Journal of Oceanic Engineering (and in the past for Transactions on Signal Processing and Transactions on Vehicular Technology). She also serves on the Advisory Board of the IEEE Communication Letters, and chairs the IEEE Ocean Engineering Society’s Technical Committee for Underwater Communication, Navigation and Positioning. Milica is the recipient of the 2015 IEEE/OES Distinguished Technical Achievement Award.
Dr. Paul C. Hines was born and raised in Glace Bay, Cape Breton. From 1977-1981 he attended Dalhousie University, Halifax, Nova Scotia, graduating with a B.Sc. (Hon) in Engineering-Physics.