(https://seattlein2025.org/)IEEE" target="_blank" title="https://seattlein2025.org](https://seattlein2025.org/)IEEE">https://seattlein2025.org](https://seattlein2025.org/)IEEE will be there, and you have an opportunity to attend and contribute as an IEEE member or student member alongside your peers from Seattle Section for a day, for a few days, or for the entire event. We’re hoping for a good turnout from Vancouver on the weekend: Fri, 15 August, Sat, 16 August and Sun, 17 <a href="http://August.Instructions" target="_blank" title="August.Instructions">August.Instructions for registering for the conference can be found athttps://seattlein2025.org/memberships/memberships/ .You have multiple options including day passes, full conference registration, <a href="http://etc.IEEE" target="_blank" title="etc.IEEE">etc.IEEE will have a booth at Worldcon. If you would like to volunteer to join a shift or two, please let us know!IEEE members like myself, Alon Newton, John Vertner, and Tom Coughlin (2024 President) will be at Worldcon. We hope that you can join us!In the meantime, please help us plan ahead by registering through this vTools page so that we can gauge interest and keep you informed. At this point, you’re simply expressing interest. Final confirmation won’t be required for a week or <a href="http://two.David" target="_blank" title="two.David">two.David MichelsonCounsellor, IEEE Student Branch @ UBCBldg: Summit Expansion, Seattle Convention Center, 900 Pine Street, Seattle, Washington, United States, 98101

The development of innovative cybersecurity technologies, tools, and methodologies that advance the energy system’s ability to survive cyber-attacks and incidents while sustaining critical functions is needed for the secure operation of utility and industrial systems. It is essential to verify and validate the ability of the developed solutions and methodologies so that they can be effectively used in practice. Developing solutions to mitigate cyber vulnerabilities throughout the energy delivery system is essential to protect hardware assets. It will also make systems less susceptible to cyber threats and provide reliable delivery of electricity if a cyber incident <a href="http://occurs.This" target="_blank" title="occurs.This">occurs.This talk will describe how the developed solution can protect the power grid and industrial infrastructure from cyber-attacks and build cybersecurity protection into emerging power grid components and services. This includes microgrid and demand-side management components and protecting the network (substations and productivity lines) and data infrastructure (SCADA) to increase the resilience of the energy delivery systems against cyber-attacks. These developments will also help utility security systems manage large amounts of cybersecurity risk data and cybersecurity operations. For these developments to succeed, cybersecurity testbeds and testing methodologies are necessary to evaluate the effectiveness of any proposed security <a href="http://technologies.The" target="_blank" title="technologies.The">technologies.The focus on developing cybersecurity capabilities in energy systems should span over multiple strategies: in the near term, midterm, and long term. Continuous security state monitoring across cyber-physical domains is the goal in the near term. The development of continually defending interoperable components that continue operating in degraded conditions is required in the midterm. Developing methodologies to mitigate cyber incidents to return to normal operations quickly is necessary for all system components in the long term. We will discuss R&D efforts in these areas centered on developing operational frameworks related to communication and interoperability, control, and <a href="http://protection.The" target="_blank" title="protection.The">protection.The importance of interoperability between smart grid applications and multi-vendor devices must be considered. The current grid comprises multi-vendor devices and multi-lingual applications that add to the complexity of integrating and securing the smart grid components. Standards development entities have been working with utilities, vendors, and regulatory bodies to develop standards that address smart grid interoperability. These include IEEE, IEC, NIST, ANSI, NERC, and others. In this presentation, we will conceptualize a comprehensive cyber-physical platform that involves the communication and power network sides integrating the cyber information flow, physical information flow, and the interaction between them. A data-centric communication middleware provides a common-data bus to orchestrate the system’s components, leading to an expandable multi-lingual system. We will present a hardware protocol gateway that was developed as a protocol translator capable of mapping IEC 61850 generic object-oriented substation event (GOOSE) and sampled measured value (SMV) messages into the data-centric Data Distribution Service (DDS) global data bus. This is necessary for integrating the widely used IEC 61850-based devices into an exhaustive microgrid control and security <a href="http://framework.We" target="_blank" title="framework.We">framework.We will also discuss a scalable cloud-based Multi-Agent System for controlling large-scale penetration of Electric Vehicles (EVs) and their infrastructure into the power grid. This is a system that can survive cyber-attacks while sustaining critical functions. This framework’s network will be assessed by applying contingencies and identifying the resulting signatures for detection in real-time operation. As a result, protective measures can be taken to address the dynamic threats in the foreseen grid-integrated EV parks where the developed system will have an automated response to a <a href="http://cyber-attack.In" target="_blank" title="cyber-attack.In">cyber-attack.In distributed energy management systems, the protection system must be adaptive. Communication networks assist in reacting to dynamic changes in the microgrid configurations. This presentation will also describe a newly developed protection scheme with extensive communication provided by the IEC 61850 standard for power networks to monitor the microgrid during these dynamic changes. The robustness and availability of the communication infrastructure are required for the success of protection measures. This adaptive protection scheme for AC microgrids can survive communication failures through energy storage <a href="http://systems.Co-sponsored" target="_blank" title="systems.Co-sponsored">systems.Co-sponsored by: Power Electronics/Industrial ElectronicsSpeaker(s): Osama, Room: UA1140, Bldg: UA, 2000 Simcoe Street North, Oshawa, Ontario, Canada, L1G7K4

Abstract: There are three waves of Artificial Intelligence. The first Wave of AI is Crafted Knowledge, which includes rule-based AI systems. The second wave of AI is Statistical Learning, which includes machine becoming intelligent by using statistical methods. The third wave of AI is contextual adaptation. In the third wave, instead of learning from data, intelligent machines will understand and perceive the world on its own, and learn by understanding the world and reason with it. Neuro-symbolic AI, which combines neural networks with symbolic representations, has emerged as a promising solution of the third wave of AI. In this talk, first I will share my journey from counter-unmanned aircraft systems to explainable AI to neuro-symbolic AI. Then I will present the past, present, and future of neuro-symbolic AI. I will also share my perspective on the emerging area of neuro-symbolic <a href="http://AI.Speaker:" target="_blank" title="AI.Speaker:">AI.Speaker: Houbing Herbert Song, Ph.D., IEEE Fellow, Co-EiC of IEEE TIISpeaker(s): Prof. Houbing Herbert SongBldg: ICT 516, University of Calgary, Calgary, Alberta, Canada