Courses

Explore a comprehensive compilation of videos covering the electronic CAD capabilities in Fusion 360. Learn to generate PCB manufacturing files, design blocks in electronics, and optimize electromechanical workflows. Discover the latest features and updates in Fusion 360 Electronics, including the SnapEDA add-in and 3D model mapping. Gain insights on avoiding PCB manufacturing and product assembly issues through integrated E-CAD and mechanical CAD. Master exporting ODB++ files, creating custom electronic parts, and utilizing advanced features like Edit in Place. Delve into fundamental electronics concepts, circuit design, and component functions. Explore electromechanical design workflows, collaboration tools, and library management. Follow step-by-step tutorials on schematic analysis, board layout, routing techniques, and manufacturing data preparation. Understand high-speed design considerations, SPICE simulation, and Design Rule Checking (DRC). Learn to create enclosures from PCB boards and import files from other CAD software. This extensive video collection covers everything from beginner concepts to advanced techniques in electronics design using Fusion 360.

"Contemporary Electronic system Design" is a core compulsory course for undergraduates majoring in electrical and electronics. It is a part of the national high-quality course and national resource sharing course "Fundamentals of Electronic Technology" which includs "Fundamentals of Analog Electronic Technology", " Fundamentals of Digital Electronic Technology", and "Electronic Technology Course Design". It is a small class course reformed from the course "Electronic Technology Course Design". This course can be taken as a replacement of "Electronic Technology Course Design". The main contents of the course include the composition and design methods of contemporary electronic systems, sensors and actuators, DC power supplies, analog and analog-digital hybrid circuits, FPGA and digital system design, brief introduction of microprocessors and SoC, system design with customized SoC and programmable SoC (including PSoC and SOPC), SoC experimental content, experimental equipment and experimental results display, etc., with the aim to help students systematically master the design methods of contemporary electronic systems, as well as cultivate the ability of innovative design. This two-week course starts from the summer semester and has a total of 64 hours. It can also be started in the spring and autumn semesters. This course is deeply popular among students, offering a great sense of achievement, innovative teaching methods, open content, advanced equipment and teaching ideas, which provide in-depth understanding of electronic system design and the opportunity to enhance practical skills, cultivate innovative thinking and teamwork spirit.

The objective of this course is to provide students with a comprehensive understanding of digital systems and their design process. Throughout the course, students will learn the fundamental concepts of number systems and how they are utilized to represent data. They will explore digital gates and their functionality in performing operations on binary numbers. The curriculum also encompasses combinational and sequential designs, including key digital circuits such as adders, subtractors, multiplexers, flip-flops, Counter and Shift registers. Additionally, students will gain knowledge about analog-to-digital converters, digital-to-analog converters, and logic families. By the end of the course, students will have acquired the necessary skills to analyze and create various digital circuits for practical real-world applications.Course credit4

6.622 covers modeling, analysis, design, control, and application of circuits for energy conversion and control. As described by the Institute of Electrical and Electronics Engineers (IEEE), power electronics technology "encompasses the use of electronic components, the application of circuit theory and design techniques, and the development of analytical tools toward efficient electronic conversion, control, and conditioning of electric power." Students taking this class will come away with an understanding of the fundamental principles of power electronics, and knowledge of how to both analyze and design power electronic components and systems.

In this tutorial, you will learn how to use various modeling tools to create complex electronics in Rhino 5. Software required: Rhino 5. In this tutorial, you will learn how to use various modeling tools to create complex electronics in Rhino 5. We will use sweep, chamfer, fillet and Booleans to begin modeling a headphone set. We'll also learn how to add many details quickly using the array function. By the end of this tutorial, you will have used Rhino's powerful modeling tools to create a finished model with 2D plans. Software required: Rhino 5.

Instructors: Prof. A. N. Chandorkar, Prof. D. K. Sharma, Prof. Sachin Patkar, and Prof. Virendra K. Singh, Department of Electrical Engineering, IIT Bombay. This course covers topics in VLSI design: Historical perspective of VLSI, CMOS VLSI design for power and speed consideration, Logical effort, Designing fast CMOS circuits, Datapath design, Interconnect aware design, Hardware description Languages for VLSI design, FSM controller/datapath and processor design, VLSI design automation, and VLSI design test and verification.

In a circular economy, products are designed to last. Yet every product will eventually reach the end of its functional life. Recycling can help recover the value embedded in its materials so that these can be used again. However, for complex products like electronics, applying this seemingly simple principle can raise big challenges. This two-course program supports designers, engineers and decision makers in the Electrical and Electronic Equipment (EEE) industry in making the transition towards a circular economy by exploring both Design for Recycling and Designing with Recycled plastics. In the first course, you will explore the basic concepts of the circular economy and their implementation from various perspectives: how businesses can create value by reusing and recycling products; how designers can come up with amazingly clever solutions; and how to apply systems thinking to the transition to the circular economy. In the second course, you will learn how the recyclability of EEE products or consumer electronics can be optimized through good design and how to utilize recycled plastic content in existing or new products using new methods. We will examine inspiring examples and provide insight into current and future recycling technologies, legislation and business models. If you are looking for ways to upskill yourself and become a designer who not only creates great products but contributes to sustainable design and a positive environmental impact – this is the program for you!

Explore the fundamentals of EMI (Electromagnetic Interference) filtering in power electronics through this 47-minute lecture from MIT's Power Electronics course. Delve into the importance of ripple and EMI filtering in preventing interference with other electronic devices, such as radios and televisions. Learn about basic considerations and requirements for designing effective EMI filters, essential knowledge for engineers working with power supplies and electronic systems. Gain insights from instructor David Perreault in this comprehensive introduction to a critical aspect of power electronics design.

Explore electronics design and prototyping through a comprehensive 17-minute video featuring Jonathan Odom's journey creating innovative consumer products for the Autodesk University Factory Experience. Discover the behind-the-scenes process of designing smart air quality sensors, learn about the challenges of electronics prototyping and value engineering, and gain insights into creating digital conference badges with limited resources. Master practical approaches to turning ambitious product ideas into functional prototypes while understanding the collaboration between mechanical designers and electronics teams. Examine real-world projects including air quality sensors, digital conference badges, and keypad designs, with detailed coverage of design improvements and communication strategies. Benefit from practical advice on overcoming prototyping challenges, implementing value engineering principles, and transforming creative concepts into working electronic devices, making complex electronics design accessible to makers, engineers, and tech enthusiasts at all levels.

Explore the world of free and open-source hardware (FOSH) for electronic circuit design in this 29-minute conference talk from Ubuntu Summit 2022. Discover how complex electronic circuits can be designed, developed, and brought to reality without expensive software. Follow hardware embedded engineer Dario Murgia as he shares his experience using primarily FOSS tooling for electronic designs and discusses his journey in creating and sharing open-source hardware with the community. Gain insights into the advantages and possibilities of FOSH in electronic circuit design, and learn how this approach can revolutionize the field.

INTENDED AUDIENCE: 3rd Year UG and PG PREREQUISITES: 12th Standard COURSE OUTLINE: The purpose of this course is to sensitize a registrant to various aspects of an electronics product. Specifically onnon electrical aspects like mechanical design and detailing. Starting from a need translated into specifications, leading to design and prototyping and ending up in a manufacturable physical prototype.

The purpose of this course is to sensitise a registrant to various aspects of an electronics product. Specifically onnon electrical aspects like mechanical design and detailing. Starting from a need translated into specifications, leading to design and prototyping and ending up in a manufacturable physical prototype.INTENDED AUDIENCE: 3rd Year UG and PGPREREQUISITES: 12th Standard

Explore the world of Electronic Design Automation (EDA) and its impact on the resurgence of chip design in this Stanford seminar. Delve into topics such as NVidia's 2.5D-IC technology, current design capabilities, and the challenges posed by the end of Dennard scaling. Examine the heroic efforts in the industry, including the transport of EUV systems, and consider the future of computing beyond Moore's Law. Gain insights into the digital design flow from a high-level perspective and understand the crucial role of EDA tools in chip design. Analyze the EDA market segments, historical trends, and the industry's position within the broader semiconductor landscape. Trace the brief history of EDA and compare electronic automation capabilities to mechanical automation. Discover recent innovations in the field, including ESL for FPGA, higher-level design approaches, and the widespread integration of IP in modern chip design.

Learning ObjectivesLearn automotive design principles, including aerodynamics, safety, and manufacturing.Gain practical skills for automotive design roles.Build a portfolio of automotive design projects.Benefits for StudentsLearn automotive design principles, including aerodynamics, safety, and manufacturing.Gain practical skills for automotive design roles.Build a portfolio of automotive design projects.Benefits for Professionals/EngineersGain expertise in automotive design for industry careers.Optimize vehicle design and meet regulatory standards.Enhance career prospects in the automotive industry.Benefits for EnterprisesOptimize vehicle design and meet regulatory standards.Accelerate innovation in automotive product development.Reduce development costs with skilled designers.Benefits for AcademiaOffer specialized courses in automotive design and engineering.Equip students with skills in automotive design principles.Promote research in vehicle design and safety.

Learning ObjectivesDevelop expertise in CAD modeling, materials selection, and product lifecycle management.Gain practical skills for product development roles.Build a portfolio of design projects.Benefits for StudentsDevelop expertise in CAD modeling, materials selection, and product lifecycle management.Gain practical skills for product development roles.Build a portfolio of design projects.Benefits for Professionals/EngineersGain skills required for product development roles.Improve design efficiency and engineering accuracy.Enhance career prospects in product design.Benefits for EnterprisesImprove design efficiency and engineering accuracy.Reduce product development costs.Enhance innovation in product development.Benefits for AcademiaPrepare students for careers in product design and development.Integrate product design principles into curriculum.Foster collaboration between design and engineering departments.

Learning ObjectivesExplore lightweight materials, structural integrity, and aerospace CAD tools.Gain practical skills for aerospace design roles.Build a portfolio of aerospace design projects.Benefits for StudentsExplore lightweight materials, structural integrity, and aerospace CAD tools.Gain practical skills for aerospace design roles.Build a portfolio of aerospace design projects.Benefits for Professionals/EngineersBuild expertise in aerospace engineering and CAD software.Improve aircraft design and structural analysis.Enhance career prospects in the aerospace industry.Benefits for EnterprisesImprove aircraft design and structural analysis.Develop cutting-edge aerospace technology.Reduce development costs with skilled engineers.Benefits for AcademiaProvide training in aerospace engineering and design principles.Equip students with skills in aerospace CAD tools.Promote research in lightweight materials and structural integrity.

This course is a system design-oriented course aimed to provide exposure to mathematical analysis and its importance in the translational biomedical systems. Biomedical electronics and subsequent mathematical analysis are popular research areas, and this course is an introduction to both. The emphasis is on biostatistical aspects with an introduction to standard Biological system design and experimental protocols. Expected course outcomes:• Introduction to Biomedical optics• Multimodal Approaches for Tissue phenotyping• Mathematical Modelling of Biomedical System Design• Acquisition, Preprocessing and Analysis of Biological Signals• Demonstration of EEGLab and ERPLab for EEG and ERP signal processingINTENDED AUDIENCE : Engineering students, Faculty from Engineering Colleges, Medical StudentsPREREQUISITES : Basic Electronics

Since 2020, with the gradual maturation of the Internet of Things and 5G technology, the smart home industry has ushered in a period of comprehensive explosion. The state has introduced multiple policies to encourage and support the development of the smart home industry. This course focuses on simple smart home systems and is based on the assessment content of the competition item for secondary vocational students in vocational college skills competitions, Electronic Product Assembly and Application. After a comprehensive analysis of the learning situation of secondary vocational students, six projects are designed: the DC regulated power supply module, the simulated exhaust fan module, the combustible gas detection module, the sound and light alarm module, the human body infrared detection module, and the microcontroller main control module. Each project can produce an independent electronic product. The DC regulated power supply module provides energy for all modules, and the microcontroller main control module can control the operation of the sound and light alarm module and the simulated exhaust fan module based on signals from the combustible gas detection module and the human body infrared detection module, thereby realizing two typical applications of smart home: kitchen safety and intelligent anti-theft.Each project is implemented following the task flow of circuit design, component selection, simulation verification, drawing and board manufacturing, and soldering and debugging, accurately replicating the entire process of electronic product production and aligning the learning process with the production process.The course emphasizes helping students clarify the steps of product production and safety operation standards, fostering quality awareness and safety consciousness among students; during the soldering and debugging tasks, the course adopts a six-step teaching method of inquiry, planning, decision-making, implementation, inspection, and evaluation, aiding students in developing good work habits.

Fundamentals of Electrical Engineering and Electronic Design is a highly applied professional platform course. The main purpose of the course is to enable learners to master the basic theories, fundamental knowledge, and essential analytical and problem-solving methods of various major branches of electrical and electronic technology. It aims to empower learners to use electrical and electronic theories to construct circuit models from practical problems, choose appropriate solving methods, and quickly find optimal or satisfactory solutions using software. Through training students in practical (electronic) circuit design, the course cultivates their overall thinking and application awareness in electronic circuit design, enhances learners' abilities to analyze and solve real-world problems, and lays a solid foundation for further study in subsequent courses.

Discover the advantages of transitioning from Autodesk EAGLE to Fusion 360 for electronics design in this 27-minute webinar recording. Explore improved data sharing capabilities through versioning and collaboration features, utilize enhanced violator options for efficient component placement and routing, and access comprehensive PCB design tools within a single software solution. Learn how to design products holistically, avoiding costly redesigns and manufacturing oversights through Fusion 360's electromechanical workflow. The webinar covers topics such as electronic document management, team collaboration, schematic mode, environment violators, and PCB creation, providing a seamless PCB design experience for electronics engineers.