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

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

Design for Testability (DFT) plays a crucial role in the field of mechanical engineering. In this article we will  learn the significance of DFT and how it influences the work of mechanical engineers. One key aspect of DFT in mechanical engineering is the emphasis on designing systems and structures that are not only functional but also easily testable on various load conditions.

It is the era of intelligent machines - Integration of Mechanics and Electronics with intensive computer integration using a multidisciplinary approach to product and manufacturing system design. It is a design philosophy which encourages engineers to integrate precision mechanical engineering, digital and analog electronics, control theory and computer engineering in the design of “intelligent” products, systems and processes rather than engineering each set or requirements separately.

🔧Mastering EMC Simulations for Electronic Designs🔧 CADFEM (UK-IE) invite you to join this upcoming Hands-On Ansys Session, suitable for: Electromagnetic Compatibility Engineers, Mechanical Design Engineers, RF Engineers, Electrical Engineers 📅 Wednesday 11th December ⏰ 3pm - 7pm GMT 📍 Register here: https://lnkd.in/gcRGAkd7 It can be challenging for EMC and product design engineers to understand how to use simulation tools effectively. Guided by experts, you will learn: ✔️CAD File Preparation: Master the process of importing mechanical CAD designs, assigning materials, and preparing for simulations. ✔️PCB and Package Setup: Discover the steps to import electronic design files for PCBs and packages, including automation of the setup process. ✔️Cable Specification: Gain hands-on experience in defining cables through the co-simulation with multi-conductor transmission line solvers. ✔️Component Modeling: Understand how to represent components using ideal or SPICE circuit models for co-simulation with 3D geometries. ✔️Performance Evaluation: Learn to transform simulation results into formats that facilitate comparison with standard measurements for device performance assessment. #CADFEM #Ansys #EMC #ProductDesign #Simulation

I embarked on a fascinating journey into the realm of amplifier design, focusing on the intricacies of crafting a Wilson Current Mirror using Bipolar Junction Transistors (BJTs) within LTspice. Allow me to walk you through the meticulous process: Step 1: Circuit Design At the heart of this endeavor lies the creation of the schematic for the Wilson current mirror, a configuration comprising three crucial BJTs—Q1, Q2, and Q3—interspersed with three pivotal resistors—R1, R2, and R3. This foundational step lays the groundwork for the entire design journey. Step 2: Component Selection Selecting the right components is paramount to ensuring the mirror's optimal performance. In this endeavor, I meticulously chose 2N3904 BJTs paired with 1 kΩ resistors, aligning seamlessly with our design objectives. Step 3: Simulation Setup With the components in place, the next logical step was defining the simulation commands essential for analyzing the circuit's behavior. By incorporating commands for an operating point analysis (.OP) and plotting output currents alongside voltage drops across components, we set the stage for comprehensive analysis. Step 4: Run Simulation The moment of truth arrived as we executed the simulation within LTspice, eagerly awaiting insights into the mirror's behavior. This pivotal step allowed for real-time observation and scrutiny of the circuit's performance under varying conditions. Step 5: Analysis Armed with simulation results, a thorough analysis ensued to dissect the nuances of the Wilson current mirror's performance. This critical phase empowered me to discern intricate patterns, identify potential bottlenecks, and fine-tune component values or circuit configurations to align with our desired performance metrics. By meticulously navigating through these steps, I have not only gained invaluable hands-on experience but also deepened my understanding of amplifier design principles. This journey underscores the essence of continuous learning and exploration in the realm of electronics engineering

Understanding Electronic Design Engineering Explore the essentials of Electronic Design Engineering. Learn about key concepts, tools, and methodologies to design and develop advanced electronic systems. Perfect for engineers and tech enthusiasts For more information, visit: https://lnkd.in/gCSGTEJA #ElectronicDesignEnginering #ElectronicDesign #ElectronicEngineering #PCBDesign #ElectronicsIndustry

🔌🚗 𝗗𝗶𝘀𝗰𝗼𝘃𝗲𝗿 𝗺𝘆 𝗲𝗻𝗱 𝗼𝗳 𝘀𝘁𝘂𝗱𝗶𝗲𝘀 𝗽𝗿𝗼𝗷𝗲𝗰𝘁 : 𝗧𝗵𝗲 𝘂𝗻𝗶𝘃𝗲𝗿𝘀𝗮𝗹 𝗮𝘂𝘁𝗼𝗺𝗼𝘁𝗶𝘃𝗲 𝗛𝗶𝗴𝗵 𝗩𝗼𝗹𝘁𝗮𝗴𝗲 𝗣𝗼𝘄𝗲𝗿 𝗢𝘂𝘁𝗹𝗲𝘁 (𝗛𝗩𝗣𝗢)  🚗🔌 Dear network, I am excited to share with you the solution developed in my end-of-studies project, which earned an 'Excellent' distinction. This project focuses on the design and development of a universal automotive high voltage power outlet (HVPO) designed for use in vehicles. This innovative outlet allows for the provision of 220V to various devices directly from the vehicle. With its universal design, this HVPO can accommodate multiple types of plugs, making it extremely useful in critical situations, especially when you are abroad and need to connect to different electrical standards. This successfully completed project opens up new perspectives for energy use in modern vehicles, combining efficiency and innovation. #Engineering #Innovation #Automotive #AutomotiveEngineering #HVPO #FinalYearProject #UniversalOutlet #ElectricVehicles #EnergySolutions #AutomotiveDesign #HighVoltagePower #AutomotiveSolutions #CATIA #Solidworks #Abaqus #Altium #PCBDesign #FEM #NumericalSimulation #Keyshot

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

Come see PCEA-Printed Circuit Engineering Association at #PCBCarolina tomorrow. Mike Buetow, Frances Stewart, William Bruwer, plus Stephen V. Chavez, our association chairman will be available to answer your questions about our association. #printedcircuitengineering #engineering #PCBdesign #PCBfabrication #PCBassembly #engineers #PCBtraining #hightechnology