VHDL, or Very High-Speed Integrated Circuit Hardware Description Language, is a hardware description language used in the design and development of digital circuits. As the demand for skilled VHDL programmers continues to grow, many individuals are seeking online courses to learn this essential skill. In this article, we will explore some of the best VHDL courses available online, taking into consideration factors such as course content, instructor expertise, and student reviews.
Here’s a look at the Best Vhdl Courses and Certifications Online and what they have to offer for you!
Best Online Course For Fpga And Vhdl
- Best Online Course For Fpga And Vhdl
- 1. Learn VHDL and FPGA Development by Jordan Christman (Udemy) (Our Best Pick)
- 2. Learn the Fundamentals of VHDL and FPGA Development by Jordan Christman (Udemy)
- 3. Learn VHDL Design using Xilinx Zynq-7000 ARM/FPGA SoC by Clyde R. Visser, P.E. (Udemy)
- 4. Xilinx Vivado: Beginners Course to FPGA Development in VHDL by Augmented Startups (Udemy)
- 5. FPGA Design and VHDL by Eduvance (Microchip Certified Trainer, AUP Trainer, CUA Trainer) (Udemy)
- 6. Introduction to VHDL by Jordan Christman (Udemy)
- 7. Xilinx FPGAs: Learning Through Labs using VHDL by Jordan Christman (Udemy)
- 8. Introduction to VHDL for FPGA and ASIC design by Scott Dickson (Udemy)
- 9. Altera FPGAs: Learning Through Labs using VHDL by Jordan Christman (Udemy)
- 10. VHDL for an FPGA Engineer with Vivado Design Suite by Kumar Khandagle (Udemy)
1. Learn VHDL and FPGA Development by Jordan Christman (Udemy) (Our Best Pick)
The Learn VHDL and FPGA Development course, led by Jordan Christman, is designed to teach students how to create a VHDL design that can be simulated and implemented on Xilinx or Altera FPGA development boards. The course is suitable for beginners and intermediates and supports both Xilinx and Altera FPGA development boards. The course contains over 20 lectures and 7 labs that aim to teach students the syntax, structure, and use of specific VHDL keywords.
The lectures included in each lab provide background information on the digital logic circuit the student will be implementing. The labs are designed to help students learn VHDL by actually coding it themselves. For each lab, the student receives a set of VHDL files that they will need to modify or change in order to get the project to simulate correctly in ModelSim and implement the design on their FPGA board.
The course covers VHDL data types, syntax, coding structure, test bench, implementing state machines in VHDL, and FPGA development boards. Additionally, the course covers both Altera and Xilinx tools, including the BASYS 3 or BASYS 2 FPGA development board. The labs cover a range of topics, including the Full Adder, Shift Register, Universal Shift Register, 7 Segment Display, Counter, Multiplier, and RC Servo. The course also includes lecture notes and extra references. Before signing up for the course, students are encouraged to message the instructor.
The course Learn the Fundamentals of VHDL and FPGA Development teaches the basics of VHDL design and FPGA development through eight different projects. Students will learn by coding VHDL designs and running simulations to verify their code. While running code on real hardware is not required, the course recommends using Altera or Xilinx boards for this purpose. The course covers topics such as VHDL design structure, statements and data types, simulations, and more. Each project is explained through demonstration videos and walk-throughs, ensuring that students have a deep understanding of how the project works.
The Learn VHDL Design using Xilinx Zynq-7000 ARM/FPGA SoC course is suitable for both beginners and experienced engineers, providing instruction on how to use Vivado on the Zybo Z7 Xilinx Zynq FPGA Development Board. The course teaches participants the analysis and synthesis of digital systems using VHDL, with hands-on experience utilizing a Xilinx FPGA Development Board and simulation software. The course covers component modeling, data flow description in VHDL, behavioral description of hardware, and VHDL applications. Upon completion, participants will be able to describe VHDL syntax and semantics, create synthesizable designs, use the Digilent Zybo Z7 development board, use the Xilinx Vivado toolset, and design simple and practical test-benches in VHDL.
Prerequisites for the course include familiarity with digital logic design, electrical engineering, or equivalent experience. Even individuals who are familiar with VHDL may find something new to learn, such as finite state machine design, the two-process design methodology, test-bench design, combinatorial and sequential logic, and extensible synthesizable designs that are reusable.
The course is divided into several sections, including Basics, Data types & operations, Concurrent statements, Sequential statements, Processes, Subprograms, Packages, Design for synthesis, Advanced topics, and Additional libraries. Each section covers different aspects of VHDL design, with a focus on developing practical skills and knowledge. This course is suitable for anyone looking to improve their understanding of VHDL and its practical applications in digital design.
The Xilinx Vivado: Beginners Course to FPGA Development in VHDL is a training course offered by Augmented Startups. The course aims to teach participants the fundamentals of the Vivado Design Suite in a short amount of time to enable them to start developing on FPGA’s. The instructor is an FPGA Designer with a Masters Degree in Electronic Engineering and has over 7300 students on Udemy. The course offers practical and easy to understand labs to help participants learn how to design, simulate, and implement HDL code in Vivado.
The course is designed for those who want to learn the new Xilinx Development Environment called Vivado Design Suite, those who are migrating from the old ISE environment to Vivado, and those who are new to FPGA’s. The course will teach participants how to build an effective FPGA design, use proper HDL coding techniques, make good pin assignments, set basic XDC constraints, and use the Vivado to build, synthesize, implement, and download a design to their FPGA.
The training duration is 1 hour and participants will gain skills in designing for 7 series+ FPGAs, using the Project Manager to start a new project, identifying the available Vivado IDE design flows, identifying file sets such as HDL, XDC, and simulation, analyzing designs by using Schematic viewer and Hierarchical viewer, synthesizing and implementing a simple HDL design, building custom IP cores with the IP Integrator utility, building a Block RAM (BRAM) memory module and simulating the IP core, creating a microblaze processor from scratch with a UART module, using the primary Tcl Commands to Generate a Microblaze Processor, and describing how an FPGA is configured.
The course costs $200 and will increase to $210 as of 1st February 2019 due to updated content. This course is significantly cheaper than most Official Xilinx Partner Training Courses which can cost over thousands of dollars.
The FPGA Design and VHDL course provides instruction on digital design and FPGA design, utilizing VHDL as a language. The comprehensive course is designed to teach candidates the core concepts of digital systems design using FPGAs.
The course focuses on utilizing a Hardware Description Language (HDL) called VHDL, teaching candidates about each component of VHDL, and how various language constructs are applied in hardware design. Candidates are then offered the choice to perform real hardware experiments remotely, or simulate experiments using downloadable software.
The course is broken down into individual sections, including Understanding VHDL, Entity, Data Modes, Architecture, and Signals, Processes and Sequential Statements, Building Larger Designs Using Smaller Designs, Clock Dividers and Counters, and Designing Finite State Machines.
Overall, this course is designed for candidates interested in learning digital and FPGA design using VHDL, and provides a comprehensive and in-depth instruction on the topic.
Introduction to VHDL is a course aimed at individuals who have no prior knowledge of VHDL but are interested in learning and understanding the language. The course covers various data types associated with the VHDL language, focusing on how the syntax can be used to design circuits. Over eight examples of digital designs implemented in VHDL are provided in the course.
The course structure begins with explaining the background and history of VHDL followed by an introduction to data types and objects. The course then delves into the keywords and syntax of the VHDL language and different design architectures used in VHDL. Students also learn how to design a test bench to simulate and verify functionality of their designs.
The course includes several design examples such as logical gates, flip-flops, and encoders. Upon completing the course, students will have their own library of VHDL designs that can be used and referred to later. The final project involves implementing a priority encoder on a development board, taking students through the various phases of design, testing, and implementation.
Overall, the course is designed to provide individuals with a comprehensive understanding of VHDL and its applications in digital circuit design. Students can message the instructor with any questions before signing up for the course. The course is divided into several sections covering topics such as data flow, behavioral design style, and FPGA development flow.
The Xilinx FPGAs: Learning Through Labs with VHDL course offers a hands-on approach to learning digital design using VHDL implementation. The course includes 9 labs that cover topics such as BCD Display, Random Number Generator, Signed Multiplier, Barrel Shifter, Arithmetic Logic Unit, Temperature Sensor, Tilt Sensor, Microphone Interface, and Potentiometer Interface. Each lab comes with a design to complete and completed code solutions are available for download.
The course is structured such that each section contains a specific topic that is briefly discussed before diving into the lab. Additionally, each section includes a setup lecture to explain how to set up the lab and a demonstration video for reference. The course covers various topics such as Booth’s Algorithm, Linear Feedback Shift Register, and ALU.
The course intends to provide students with a thorough understanding of VHDL through hands-on experience. The focus is on practical implementation rather than theory, enabling students to learn how to write and create designs themselves. The course is suitable for those who have a Basys 2, Basys 3, Arty, or ArtyZ-7 FPGA.
Introduction to VHDL for FPGA and ASIC design is a course offered by Scott Dickson. The course covers twelve lectures, starting with the basics of VHDL, including the entity, architecture, and process. Students will learn about the differences between sequential and concurrent VHDL and engage in discussions of good synchronous design methodology.
The course also includes demonstrations on how to use the Altera Modelsim and Xilinx Vivado simulators for VHDL design. Additionally, students will participate in six lab projects for hands-on experience, with the instructor showing how he would have done each lab.
The course content is divided into six sections, which cover Introduction to VHDL, a first look, Concurrent and Sequential VHDL, RTL, VHDL Types, VHDL Operators, and Verification. Overall, the course is designed to teach students the fundamentals of VHDL and how they can apply them to FPGA and ASIC designs.
This course titled Altera FPGAs: Learning Through Labs using VHDL is taught by Jordan Christman and provides a hands-on approach to learning about FPGA through labs. The course focuses on VHDL implementation rather than theory, as writing and creating designs oneself is considered the most efficient way to learn VHDL. The course consists of 9 labs that cover topics such as BCD Display, Random Number Generator, Signed Multiplier, Barrel Shifter, Arithmetic Logic Unit, Temperature Sensor, Tilt Sensor, Microphone Interface, and Potentiometer Interface.
Each section of the course contains a specific topic that is briefly discussed, followed by a design to start with to complete the lab. Completed code solutions for each project will be available for download as a resource. Additionally, each section includes a setup lecture that explains how to set up the lab, along with a demonstration video as a reference for a working design.
The course content is structured with an introduction to the course, followed by Lab 1 – BCD Display, Lab 2 – Linear Feedback Shift Register, Lab 3 – Booth’s Algorithm, Lab 4 – Barrel Shifter, Lab 5 – ALU (Arithmetic Logic Unit), Lab 6 – Temperature Sensor Interface, Lab 7 – Tilt Sensor Interface, Lab 8 – Microphone Interface, Lab 9 – Potentiometer Interface, Lecture Explained Notes, and a Conclusion.
This course, titled VHDL for an FPGA Engineer with Vivado Design Suite, is aimed at professionals seeking to enhance their skills in the field of FPGA design using Xilinx FPGA’s. The course emphasizes the use of VHDL, one of the two most popular Hardware Description Languages (HDLs) with a focus on practical, real-life examples.
The curriculum covers various topics such as modeling styles, blocking and non-blocking assignments, synthesizable FSM, building memories with block and distribute memory resources, Vivado IP integrator, and hardware debugging techniques such as ILA and VIO. The course also explores the FPGA design flow with the Xilinx Vivado Design suite, implementation strategies to achieve desired performance, and projects to illustrate the usage of Verilog constructs to interface real peripheral devices to the FPGA.
The course is divided into several sections, beginning with an introduction on installing Vivado and a performance comparison motivation. Other sections include frequently asked questions, Vivado Design Flow Part 1 and 2, fundamentals of signal and variable, dataflow modeling style, behavioral modeling style, understanding testbench, structural modeling style, finite state machines in VHDL, using IP’s, hardware debugging, memories in FPGA, timing domain projects, data-dominant projects, and fundamentals of FPGA architecture.
Throughout the course, practical examples are used to help the learners build a strong understanding of the concepts being discussed. By the end of this course, learners will have a comprehensive understanding of VHDL and the Xilinx Vivado Design suite, making them better equipped to design complex systems using FPGA technology.