This course can also be taken for academic credit as ECEA 5360, part of CU Boulder’s Master of Science in Electrical Engineering degree. Programmable Logic has become more and more common as a core technology used to build electronic systems. By integrating soft-core or hardcore processors, these devices have become complete systems on a chip, steadily displacing general purpose processors and ASICs. In particular, high performance systems are now almost always implemented with FPGAs. This course will give you the foundation for FPGA design in Embedded Systems along with practical design skills. You will learn what an FPGA is and how this technology was developed, how to select the best FPGA architecture for a given application, how to use state of the art software tools for FPGA development, and solve critical digital design problems using FPGAs. You use FPGA development tools to complete several example designs, including a custom processor. If you are thinking of a career in Electronics Design or an engineer looking at a career change, this is a great course to enhance your career opportunities. Hardware Requirements: You must have access to computer resources to run the development tools, a PC running either Windows 7, 8, or 10 or a recent Linux OS which must be RHEL 6.5 or CentOS Linux 6.5 or later. Either Linux OS could be run as a virtual machine under Windows 8 or 10. The tools do not run on Apple Mac computers. Whatever the OS, the computer must have at least 8 GB of RAM. Most new laptops will have this, or it may be possible to upgrade the memory.

This course can also be taken for academic credit as ECEA 5730, part of CU Boulder’s Master of Science in Electrical Engineering degree. This course will provide you with a firm foundation in lithium-ion cell terminology and function and in battery-management-system requirements as needed by the remainder of the specialization. After completing this course, you will be able to: - List the major functions provided by a battery-management system and state their purpose - Match battery terminology to a list of definitions - Identify the major components of a lithium-ion cell and their purpose - Understand how a battery-management system “measures” current, temperature, and isolation, and how it controls contactors - Identify electronic components that can provide protection and specify a minimum set of protections needed - Compute stored energy in a battery pack - List the manufacturing steps of different types of lithium-ion cells and possible failure modes

You Will Learn in This Course Electrical Installation Design Part 1 :- - Different Types of Electrical Installed Powers - Design Different Types of Electrical Loads Single Phase Circuits and Three Phase Circuits - Apply Diversity Factor on Branch and Main Electrical Circuits - Classify Different Types of Electrical Transformers and How To Select The Suitable Transformer Rating - We Will Explain Different Types of Circuit Breakers - Sizing Miniature Circuit Breaker and Molded Case Circuit breaker for Single Phase circuits and Three Phase Circuits - Sizing Earth Leakage Circuit Breaker - Low voltage Circuit Breakers , Medium voltage Circuit breakers and High Voltage Circuit Breakers - sizing Fuse - Sizing Cable  , Wire Sizing - Low voltage cables , medium Voltage cables and High Voltage Cables - Complete Design For Branch and Main circuits Our Goal - To Reduce The Gap Between Academic Studies and Practical Life and How To Apply The Academic Studies In Your Work - Give You a lot of Different Design Examples to Give You flexibility of Mind Without Following Specific Rules - Deep Understanding Of Electrical Power System Equipment and to Design and Install Them - Deep Understanding Of  Electrical Wiring How to Read Single Line Diagram  of Electrical Designs - Give You Powerful Resources to Study Well - Gain Practical Experience ............................................................... After This Course You Will Have Deep Understanding of Electrical Drawing Design and How To Design Electrical Power Systems Networks Electrical Design and Single Line Diagrams For Residential , Commercial and Industrial Projects and Apply This Experience in Your WorkPlace This course is a summary of a set of scientific research , many references and work experience.

Embedded Software and Hardware Architecture is a first dive into understanding embedded architectures and writing software to manipulate this hardware. You will gain experience writing low-level firmware to directly interface hardware with highly efficient, readable and portable design practices. We will now transition from the Host Linux Machine where we built and ran code in a simulated environment to an Integrated Development Environment where you will build and install code directly on your ARM Cortex-M4 Microcontroller. Course assignments include writing firmware to interact and configure both the underlying ARM architecture and the MSP432 microcontroller platform. The course concludes with a project where you will develop a circular buffer data structure. In this course you will need the Texas Instruments LaunchPad with the MSP432 microcontroller in order to complete the assignments. Later courses of the Specialization will continue to use this hardware tool to develop even more exciting firmware.

This unique Master-level course provides you with in-depth know-how of microwave engineering and antennas. The course combines both passive and active microwave circuits as well as antenna systems. Future applications, like millimeter-wave 5G/beyond-5G wireless communications or automotive radar, require experts that can co-design highly integrated antenna systems that include both antennas and microwave electronics. We will provide you with the required theoretical foundation as well as hands-on experience using state-of-the-art design tools. The web lectures are supported by many on-line quizzes in which you can practice the background theory. Next to this, we will provide you hands-on experience in a design-challenge in which you will learn how to design microwave circuits and antennas. Throughout the course you will work on the design challenge in which you will design a complete active phased array system, including antennas, beamformers and amplifiers. The course is supported by a book written by the team of lecturers, which will be made available to the students. After finalizing the course a certificate can be obtained (5 ECTS), which can be used when you start a full MSc program at Eindhoven University of Technology. The lecturers all have an academic and industrial background and are embedded in the Center for Wireless Technology Eindhoven (CWT/e) of Eindhoven University of Technology, The Netherlands.

Hi, this is a course series I started to help various colleagues in the world of electrical engineering and industrial automation to understand and to be able to design and implement a most common motor starter for industrial automation applications - DOL motor starter. Since this is a first course in the series, I start of not only by building a whole circuit diagram but also explaining in detail all the circuit components, both for power and control circuit. You'll also learn how to properly dimension (size) all the power circuit components. In the following courses we will more concentrate on the control circuit since after this course you will understand: the symbols (IEC/NFPA) the power circuit components such as fuse, contactor, motor overload switch aka motor protection circuit breaker (MPCB) the control circuit components such as START/STOP pushbuttons, emergency stop pushbutton, signal lamps (aka pilot lights), relay and it's role etc. Regarding manual controls, that is, pilot devices, I will also publish soon 2 courses (one for Siemens devices and one for Allen Bradley) that will teach you how to efficiently plan those pilot devices such as START/STOP push buttons, emergency stop push button, selector switch (MAN-O-AUTO), twin push button, pilot lights (signal lamps). So please refer to those respective courses if you want to learn in detail how to configure those devices which tend to get complicated since they normally constitute from many different parts/pieces which if properly configured then form a whole working component. Hope you will enjoy the course and I'll be seeing you in the lectures. Stay safe and well. Best regards, Ivan Vidovic

This course is an introduction to electrical controls with an emphasis on motor controls in the real world. In this course, we focus on industrial and commercial installations, we will start with the absolute basics of electrical circuits. We look at the fundamentals of resistive circuits, and introduce Ohms Law, a mathematical formula that all electricians learn. The course looks at the different types of voltages and where they come from in the real world, focussing on transformer formations from the power supply authority, and AC and DC Voltages . As this is a course on the fundamentals of electrical controls, we will go through the basics of control circuits such as, normally open and normally closed , and look at how controls are made up of series and parallel circuits . Taking a more practical approach to the subject, we dive inside control panels and look at each electrical component that we will be using later in the course, in our own motor control installation . We look inside the parts in detail and see how they work, discuss ratings, and learn how to size them up, with a particular focus on contactors and overloads . We also simplify an explanation of how an asynchronous motor works. Before we get to wiring up our own control circuit, we look at the different types of c ontrol voltages in the real world and follow them  from end device at the customers installation all the way back to the supply transformer at the power company, so we can see how a full installation might look, and get an insight into different systems that we might find in industry. After learning the basics, we look at how we would install a motor control installation from scratch, including the motor itself. We get to see all the parts that we have learned about, working together in a mock real world installation, we learn how to size up the components and then go through the wiring of the circuit step by step. Part of installing a control board is commissioning it, so we go through the operation of the circuit after we have installed it to make sure it works. Installations are often amended and modified in the real world, so we'll look at a few ways in which we could modify our mock installation, change our wiring around and re-commission the installation. At the end of the course, we're going to challenge ourselves, and learn how to fault find a circuit as we would if we were called to a breakdown as an electrical controls technician . We'll go through a few faults that we might come up against in the industry and look at how we might repair them. We also briefly touch on preventative maintenance techniques and discuss why they are important, for safety reasons and also financial reasons too. Controls can be quite daunting and complicated, we will go through slowly and steadily, learning each part of the installation in detail before putting it all together, the course is weighted towards learning from practical examples, perfect for those of us that are visual learners. And, instead of enforcing hard and fast rules of how things must be done, We focus more on learning how to break down circuits and understand them for ourselves.  I will show you wiring techniques used by Controls Electricians in the real world. What is covered in the course: Learn the fundamentals: AC and DC voltages, 3 phase voltages, resistive circuits, ohms law, normally open and normally closed, series and parallel circuits, supply transformers (star & delta), faults to earth. Electrical components: Control panels, isolating switches, circuit breakers, fuses, contactors, overloads, asynchronous motors, push buttons, indicator lights, power supplies. Types of installations: Single phase, dual phase, power supply, mixed voltage control. Installation of a motor control circuit: Install electrical components, wiring of a mock installation, commission installation. Modifying an installation: Add and remove components, wire a hold in circuit, commission. Fault finding and maintenance: Fault find and repair, use a multimeter, preventative maintenance. Are you ready to upskill?

This course Electric Motor Control explain the fundamental concepts of designing and maintaining electrical control for the three phase induction motors. Design simple and complex control circuits. all circuits discussed in this course are practical. first section electrical control and protective devices is about fundamental components of motor controls, devices that control the flow of current in circuits. circuit breakers , fuse , relays , switches , contactor and timers. second section is about sizing electric motor panels. third section is about electric control circuits.

In this course students learn the basic concepts of acoustics and electronics and how they can applied to understand musical sound and make music with electronic instruments. Topics include: sound waves, musical sound, basic electronics, and applications of these basic principles in amplifiers and speaker design.

Welcome to the Introduction to Embedded Systems Software and Development Environments. This course is focused on giving you real world coding experience and hands on project work with ARM based Microcontrollers. You will learn how to implement software configuration management and develop embedded software applications. Course assignments include creating a build system using the GNU Toolchain GCC, using Git version control, and developing software in Linux on a Virtual Machine. The course concludes with a project where you will create your own build system and firmware that can manipulate memory. The second course in this 2 course series , Embedded Software and Hardware Architecture, will use hardware tools to program and debug microcontrollers with bare-metal firmware. Using a Texas Instruments MSP432 Development Kit, you will configure a variety of peripherals, write numerous programs, and see your work execute on your own embedded platform!