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3D integration of 2D electronics - Nature Reviews Electrical Engineering

🔎 FAQ: What is ESE? Embedded Systems Engineering (ESE) integrates: 🔹 Software Development: Requirements development, legacy system retrofitting, agency compatibility updates, reverse engineering, and documentation. 🔹 Electrical Engineering: Circuit design, PCB layout, fabrication, EMI testing, and assembly. 🔹 Independent Verification & Validation (IV&V): Tool validation, test planning, code reviews, integration testing, and results reporting. Paired with the Display Systems group’s mechanical, optical, and production expertise, ESE enables us to be a one-stop shop for any engineering need. #EmbeddedSystems #Engineering #GeneralDigital Learn more at https://lnkd.in/eerih9SM

**Revolutionizing Electronics through 3D Integration of 2D Microarchitecture** Innovation never stands still, and the field of electrical engineering is no exception. The efforts by researchers at The Pennsylvania State University are testament to this, as an intriguing new path opens up in the world of microelectronics. A transformative and groundbreaking development has emerged - the adoption of three-dimensional (3D) integration. This progressive technique has already substantially revolutionized NAND flash memory technology, but the real game-changer lies in its potential implications for logic circuits! Imagining in 3D, we now look beyond conventional 2D planes, stacking transistors into the enticing third dimension, an arena yet unexplored in the mainstream. The brainchild of this innovative research is the industrious team at the Department of Engineering Science and Mechanics, The Pennsylvania State University, led by renowned engineers Darsith Jayachandran, Najam Sakib, and Saptarshi Das. Their profound insights published in the upcoming issue of Nature Reviews in Electrical Engineering, unravel the intricate science of 3D integration of 2D electronics, offering an entirely new perspective on microarchitecture design. To delve deeper into these groundbreaking advancements, visit the original article https://lnkd.in/eH4RQfMu. This development lies at the heart of a paradigm shift in microelectronics, acting as a stepping stone to novel modernized equipment and techniques. As we eagerly await future advancements in this riveting discipline, one thing is certain - the horizon of electrical engineering has just broadened! #PennState #3DIntegration #EngineeringInnovation #Microelectronics #TechnologicalRevolution

#PCBDesign #Electronics #Engineering #HighFrequencyDesign #PowerDistribution #AdvancedElectronics Hey LinkedIn Community, Building on our previous discussions about PCB design, let’s explore some final tips to elevate your designs to the next level: 1. High-Frequency Design Techniques: For high-frequency circuits, use short, direct routing paths and proper grounding to minimize signal degradation and maintain signal integrity. 2. Power Distribution Networks (PDNs): Design robust PDNs to ensure stable power delivery across the board. Incorporate wide traces and multiple vias to handle higher currents and reduce voltage drop. 3. Design for Reliability: Consider factors like environmental conditions and mechanical stresses. Use appropriate components and layout strategies to ensure long-term reliability and durability. 4. Simulation and Validation: Perform extensive simulations (electrical, thermal, and mechanical) and validate your design with prototypes to catch and fix potential issues before mass production. 5. User Feedback and Iteration: Gather feedback from users and iterate on your design based on real-world performance. This can provide valuable insights and lead to improvements in future versions. 6. Continuous Learning: Stay updated with the latest trends and technologies in PCB design. Join forums, attend workshops, and read up on new advancements to keep your skills sharp. These final tips will help you refine your PCB designs and achieve better performance and reliability. Feel free to share your experiences or ask questions about any of these topics! Happy designing and innovating!

Here is our latest review article published in Nature Reviews Electrical Engineering. We discuss how 3D integration of functionally diverse 2D materials and devices can usher in a new era for microelectronics. https://lnkd.in/eHCApNx6

Successfully completed ' Electronic circuit design for Engineers '.Excited to apply the latest techniques and insights to my work. #ContinuousImprovement #ProfessionalDevelopment

Continuing our exploration of "Electronic Development Using Stage," let's delve into Chapter 2: "Electronic Design." This chapter focuses on the key steps involved in preparing for the design phase. Here's a more summarized version of the three steps: Step 1: Discuss and Verify Concept: Collaborate closely with the electronic and mechanical engineers to discuss and verify the concept, ensuring alignment and compatibility between the electronic and mechanical aspects of the design. Step 2: Create Variants Schematic: Design different versions or configurations of the electronic circuitry to explore possibilities and optimize the design for performance and cost. Step 3: Check Hardware and Software Interface: Verify and ensure proper communication and interaction between hardware components and controlling software, conducting thorough checks and tests. Next Chapter: "Stages of Electronic Design": Chapter 2 sets the stage for electronic design. In the next chapter, we will explore the various stages involved in the electronic design process. We will delve into topics such as component selection, schematic capture, circuit simulation, and PCB layout considerations. Stay tuned for an in-depth exploration of these essential stages. Feel free to leave comments and questions below. Let's continue our journey of electronic development together! #ElectronicDevelopment #Electronics #Engineering #ElectronicDesign #Collaboration #embeddedSystem

Exciting news! I'm delighted to share that I've successfully completed my 4-bit Pseudo-random Number Generator project. This marks a significant milestone in my journey through the fascinating realm of electronic design. - Incorporating essential components such as flip-flops, XOR gates, and set circuits, this project showcases a deep understanding of circuit architecture and functionality. - Leveraging Tanner EDA from Siemens, I meticulously crafted the design and layout of the circuit, ensuring optimal performance, speed and efficiency. - Rigorous verification through Design Rule Checks (DRC), Layout vs. Schematic (LVS) verification, and Post Layout Simulation validated the integrity and functionality of the design. - Results? A robust 4-bit Pseudo-random number generator, poised to integrate seamlessly into various digital systems and applications. In my pursuit of excellence, I employed a powerful tool: Tanner EDA from Siemens: Providing the platform for design and layout, ensuring precision and accuracy and verify with post layout simulation. #EDA #CircuitDesign #PseudoRandomNumberGenerator #Electronics #Innovation #TannerEDA #Siemens #Simulation #DesignVerification #LinkedIn

#PCBDesign #Electronics #Engineering #EMIControl #LayerRouting #AdvancedElectronics Hello LinkedIn Community, Continuing from our previous posts on PCB design, let's explore some advanced techniques to further refine your PCB designs: 1. Electromagnetic Interference (EMI) Control: Implement EMI shielding techniques such as adding copper pours and using ground planes to minimize interference and improve signal clarity. 2. Layer Routing: Utilize different layers for specific functions, like separating analog and digital signals, to reduce crosstalk and noise in your design. 3. Component Placement Optimization: Use thermal and signal integrity analysis tools to optimize component placement. Ensuring proper layout can enhance performance and reduce design revisions. 4. Design for Manufacturability (DFM): Consider assembly constraints and component tolerances. Avoid designs that are difficult or expensive to manufacture and assemble. 5. Gerber Files and CAM Checks: Double-check your Gerber files and perform CAM (Computer-Aided Manufacturing) checks to ensure there are no errors before sending your design for production. 6. Documentation and Revision Control: Maintain clear documentation and manage revisions carefully. This helps in tracking changes and ensures that everyone involved is on the same page. By applying these advanced techniques, you can create more robust and production-ready PCBs. If you have any insights or questions about these practices, drop them in the comments! Keep pushing the boundaries of your designs!

Missed our DesignCon paper? Don't worry, you have a second chance to delve into the HOTTEST topic of 2000 Amp PCB Power Delivery Design, Simulation, and Measurement Challenges with Heidi Barnes and Benjamin Dannan! Join us for an electrifying webinar on May 9th at 8am PT/11am ET. Don't miss out on this award-winning opportunity! #PCB #DesignCon #Webinar