Center for Power Electronics Systems, Virginia Tech的动态

Thrilled to have completed the Introduction to Semiconductor Devices 1 course! Gained valuable insights into the fundamentals of semiconductor technology, further fueling my passion for electronics and communication engineering. #Semiconductors #Learning #Engineering

Chris Hinkle, the Leonard C. Bettex Professor of Electrical Engineering at the University of Notre Dame, is investigating new materials to power faster, smaller, and more efficient chips for next generation microelectronics. This is a new National Science Foundation (NSF) funded, multi-institutional project looking into "switchable" semiconductor materials that can either conduct or impede the flow of electricity when activated by an external trigger. Dr. Hinkle is the principal investigator for this project. ? In a related project, Professor Hinkle is working with an interdisciplinary team to find new materials for metal wires. These tiny wires have slower electrons than big wires, making them less efficient carriers of electrical current. Using codesign methods, the team has already discovered a new material that outperforms current state-of-the-art copper. #notredame #microelectronics #semiconductors

Exciting news from ASU! The White House and United States Department of Defense have awarded $29.6M to five Southwest Advanced Prototyping (SWAP) Hub projects to strengthen the nation’s semiconductor capabilities, including the Integrated RF GaN Technology Project—a critical collaboration between Arizona State University, NXP Semiconductors, Raytheon and NI (National Instruments). ASU’s Advanced Electronics and Photonics Core Facility is proud to support this project, which aims to transform the future of telecommunications. This project focuses on developing small form-factor Gallium nitride (GaN) power amplifiers for NextG, 5G and 6G wireless systems. As data demands surge, these innovations will provide reconfigurable radio architectures that meet stringent size, weight and power requirements, enabling telecom systems to operate at higher frequencies and bandwidths with dynamic performance adjustments. “The SWAP Hub has developed an unmatched network of partner capabilities that reflect the objectives and intentions of the Microelectronics Commons,” says ASU President Michael Crow, “and these project awards enable us to translate the Hub’s capabilities into impact by solving pressing national security technology challenges.” Headquartered in Arizona, the SWAP Hub is part of the Microelectronics Commons network, connecting the Southwest’s robust semiconductor industry to a growing defense and electronics network across the country. Learn more about how ASU and its partners are innovating in microelectronics to support America’s leadership in technology: https://lnkd.in/gFArC4tB Advanced Electronics and Photonics Core capabilities: https://lnkd.in/gF_cHytR SWAP Hub information: https://lnkd.in/erAEvubA #ASUCoreFacilities #ASUCores #ASUResearch #ASUEngineering #SWAPHub #Microelectronics #MicroelectronicsCommons #Semiconductors #Microchips #SemiconductorIndustry #CHIPSAct #CHIPS #TelecomInnovation School of Electrical, Computer and Energy Engineering — ASU ECEE School for Engineering of Matter, Transport and Energy Ira A. Fulton Schools of Engineering at Arizona State University School of Computing and Augmented Intelligence ASU Knowledge Enterprise

?? Explore the Future of Power Electronics: Deep Dive Session "I" at CTI SYMPOSIUM 2024 in Berlin! On the afternoon of December, 4th, join us for an engaging Deep Dive Session I "Power Electronics", offering a profound insight into current trends and developments. Meet renowned experts who will present key insights on crucial topics. ?? Watch our video and see which speakers will share their knowledge! #CTI_Sym #electronics #engineering #CTISymposium

?? Proud to share my latest achievement! Just completed a certification in Digital Circuits! ?? This course enhanced my understanding of the foundational concepts of digital electronics, including logic gates, combinational circuits, and sequential circuits. I'm excited to apply this knowledge to future projects and continue exploring the world of digital systems. #DigitalCircuits #ElectronicsEngineering #LearningJourney #BTech #ECE #CircuitDesign

I continued to think about how to tackle energy issues, I came to the conclusion that we need to rethink from the architecture of AI, semiconductors, and communications. Coming from an electrical engineering background, I was fortunate to have studied power systems, control systems, information communication, and semiconductors during my student days—and I was also a computer geek. Nowadays, electrical and electronic engineering has become more specialized, divided into three areas: power and control, information communication, and semiconductor devices. But it's a missed opportunity not to think of them in an integrated way to create impact. We should go back to thinking in the era of Tesla and Marconi.

Opening ceremony of the IEEE ECCE today. My final remarks in the opening "Remember, there's no such thing as too much power electronics!" #powerelectronics #renewable #ieeepels #conference #efficiency #education

Presented My Research paper on Heart Failure Prediction Using Machine Learning Techniques At The Organizing Committee of 3rd IEEE International Conference on Power Electronics, Intelligent Control and Energy Systems held at Department of Electrical Engineering, Delhi Technology University from 26 - 28 April 2024. #research #machinelearning #technology #engineering #datascientist

Just finished the course “Electronics Foundations: Semiconductor Devices” by Barron Stone!?Here’s to continuous growth, learning, and leveling up! ???? What’s next? Stay tuned! ?? ?#semiconductor #engineering #electronics #circuitdesign #LifelongLearner?#NextChapter

Exploring the Future of Electronics with Advanced Materials I'm excited to share a piece of literature that delves into the innovative realm of ceramic embedding of SiC semiconductors using cofiring technology. This work represents a significant leap forward in our quest for more efficient, robust, and miniaturized electronic components. Key Takeways: The study outlines a novel approach to integrating SiC semiconductors within ceramic matrices, offering enhanced thermal stability and electrical performance. Cofiring technology emerges as a pivotal technique, enabling the seamless integration of SiC semiconductors in a way that could redefine power electronics. The implications for industries ranging from automotive to aerospace are profound, hinting at more reliable, energy-efficient, and compact electronic systems Why It Matters: As we push the boundaries of electronics towards greener, more sustainable technologies, the materials and methods we employ are crucial. This literature not only sheds light on the technical feasibility of such advancements but also paves the way for future research and applications that could transform our technological landscape. Looking Ahead: The integration of SiC semiconductors using cofiring technology is just the beginning. I'm keen to see how these methodologies evolve and how they will be applied in solving real-world challenges. I encourage professionals, researchers, and enthusiasts in the fields of materials science, electronics, and engineering to delve into this fascinating study. Let's discuss the potential impacts, applications, and any insights you might have on the future of electronic component manufacturing. More details see the literature; https://lnkd.in/eaTZpxDs #SiCSemiconductor #LTCC & ULTCC Cofiring Technology #MaterialsScience #ElectronicsEngineering #Innovation #FutureTech