This module explores The Fundamentals of EDA Tools module introduces students to the essential concepts and workflows involved in modern digital design using Electronic Design Automation (EDA) tools. It provides a strong foundation in the use of Hardware Description Languages (HDLs) such as Verilog or VHDL to describe digital systems, followed by simulation and synthesis processes. Students will learn how to model combinational and sequential logic, simulate their designs using tools like ModelSim, and analyze outputs through waveform viewers. The module also covers the basics of logic synthesis using industry-standard platforms like Xilinx Vivado or Intel Quartus, helping students understand how HDL code is transformed into gate-level representations. By combining theoretical understanding with hands- on lab exercises, this module equips students with the core skills needed to design and verify digital circuits in real-world embedded or FPGA-based systems.

This module focuses on the end-to-end process of Printed Circuit Board (PCB) design using industry-standard Electronic Design Automation (EDA) tools. It is designed to equip learners with the practical knowledge and technical skills required to create functional PCB layouts, from schematic capture to fabrication-ready designs.

This module provides a comprehensive introduction to Computer-Aided Design (CAD) specifically for mechanical engineering applications. It aims to develop foundational skills in 2D drafting and 3D modeling, using industry-standard CAD software. Learners will gain the ability to design, visualize, and modify mechanical components and assemblies digitally.

This module introduces the essential concepts of Computer-Aided Manufacturing (CAM) and the practical skills required to create and optimize CNC (Computer Numerical Control) toolpaths. It bridges the gap between digital design and physical manufacturing, focusing on how CAD models are translated into machine instructions for various machining operations.

This module explores the principles and practices of Hardware-Software Co-Design, a multidisciplinary approach used to develop embedded systems by concurrently designing the hardware and software components. It is especially important in applications where performance, power efficiency, and tight integration between hardware and software are critical.

This module serves as the culmination of the training program, focusing on real-world industry applications of embedded systems, CAD/CAM, and EDA tools. It emphasizes hands-on project work, encouraging learners to integrate their acquired skills into a mini project that reflects current industry practices and challenges.

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