This course is targeted at both design and verification engineers. The assignments enable students to participate in thought-provoking and practical lab sessions that will be executed from scratch with instructor guidance. The course is strongly recommended for every electronic and electrical core domain student.
What Will You Learn?
Participants will gain expertise in Modelling Digital blocks using Verilog and its functional Simulation. At the end of the course, with mini/major project execution will help industry-ready coding techniques to get job placements as a Digital design/Verification Engineer.
Key highlights
Learn Verilog from Scratch
Design Digital Circuits
Verification Techniques
Simulation and Debugging
Certification
Program Outline
Introduction to VLSI, ASIC, and FPGA Flow
Digital design stages and Verilog program structure
Combinational and sequential circuit design in Verilog
State machine design and verification concepts
Low power techniques
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
This course introduces System Verilog and its enhancements over Verilog HDL, highlighting features like constrained stimuli, object-oriented programming, and functional coverage assertions. It combines the verification capabilities of HVL with Verilog's simplicity for a unified platform. The internship focuses on leveraging these features to build robust and efficient digital systems.
What Will You Learn?
The objectives of functional verification include ensuring design correctness. Participants will create test cases for assigned modules and a verification environment using OOPs and classes in System Verilog. They'll demonstrate randomization, analyze functional coverage, and use assertions to correct simulation behavior, ensuring thorough verification of the design under test (DUT).
Key highlights
Explore System Verilog
Design and Verification
Simulation and Debugging Techniques
Object-Oriented Programming (OOP)
Certification
Program Outline
Design Verification Process: Verilog test bench fundamentals
Introduction to System Verilog: Data types and control statements
Advanced Concepts: Functions, tasks, arrays, and queues
Object-Oriented Programming (OOP) in System Verilog
Test Bench Architecture: Randomization, assertions, and AHB SRAM design
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
In this course, you will learn the importance of synthesis and timing analysis, as well as how to perform timing analysis on combinational and sequential circuits. You'll explore strategies to enhance the speed of logic circuits. This internship will guide you through essential concepts and methodologies, equipping you with the skills to create high-performance logic circuits.
What Will You Learn?
Static Timing Analysis is a crucial step in the ASIC design flow, ensuring that the design meets timing requirements. By performing this analysis, designers can confirm that the circuit operates at the required clock frequency without setup and hold time violations.
Key highlights
Introduction to Static Timing Analysis
Floorplan and Power Plan, Routing
Clock Tree Synthesis
Delay Calculation and Timing Paths
Timing Constraints and Modes
Program Outline
Introduction to VLSI: ASIC and FPGA design flow
Synthesis Inputs: Cadence Genus flow overview
Logic and Physical Synthesis: Floorplanning and power planning
Static Timing Analysis (STA): Introduction and Tempus flow
Clock Tree Synthesis: Timing constraints, exceptions, and sign-off checks
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
Physical design involves creating the layout of an IC, and this course will guide you through the flow from netlist to GDSII. In this internship, you'll explore the entire physical design process, starting from the netlist obtained from synthesis. You'll gain detailed insights and skills to design layouts that meet high standards of performance and manufacturability.
What Will You Learn?
Physical design is based on a netlist, the outcome of the synthesis process. Key steps include floor planning, power planning, placement of logical cells, scan chain reordering, clock tree synthesis, routing, and ECO. Throughout this process, it's essential to meet area, timing, power, and design constraints.
Key highlights
Introduction to Physical Design
Floor Planning
Clock Tree Synthesis
Simulation and Debugging Techniques
Certification and Technical Support
Program Outline
Introduction to Physical Design: Overview and importance
PD Flow Stages: Data preparation and floorplanning
Placement and Clock Tree Synthesis
Routing and Physical Verification: Ensuring design integrity
Post-Layout Analysis: Static timing, parasitic extraction, and case study
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
This course provides a clear understanding of RF and Antenna fundamentals, emphasizing hands-on design and visualization. It covers essential electromagnetics and wave behavior in various mediums. Participants will learn key principles and practical aspects, preparing them for real-world applications.
What Will You Learn?
Participants will gain practical insights into the EM field using ANSYS HFSS for analyzing EM wave parameters. By the end of the internship, they'll understand electromagnetics theory and its applications. They'll also gain hands-on experience in designing and analyzing systems, making this an excellent opportunity for future careers in electromagnetics.
Key highlights
Comprehensive Exploration of electromagnetics theory and applications
Hands-on Experience in designing and analyzing electromagnetic systems
Understanding of Electromagnetic Interference and compatibility
Collaboration on projects and simulations
Strong Foundation in electromagnetics principles and applications
Program Outline
Fundamentals of Electromagnetics: Theory and applications
Electrostatics and Magnetostatics: Basic concepts and applications
Time-Varying Fields: Principles and significance of Maxwell's equations
Electromagnetic Wave Propagation: Theory and applications
Transmission Line and Waveguide Theory: Microwave components and mode conversions
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
This course clarifies fundamental concepts in RF component design and parameter analysis, focusing on the scattering matrix, insertion loss, and reflection loss. It enhances participants' knowledge in microwave engineering and filter design. By completing the course, participants will build a solid foundation in RF principles and learn to evaluate RF component performance. This knowledge is valuable for careers in telecommunications, wireless systems, radar, and other RF-related fields.
What Will You Learn?
Participants will get some ideas related to the Rf component and filter practical design approach. Hands on ANSYS HFSS tool can learn and simulate component and extract basic parameter analysis of S matrix and reflection analysis.
Key highlights
Comprehensive Exploration of RF component modeling and simulation
Hands-on Experience with HFSS software for design and analysis
Practical Projects focused on RF component design and simulation
Mentorship from experienced professionals in the field
Enhanced Technical Skills in RF modeling and simulation using HFSS
Program Outline
Rectangular and Circular Waveguide Analysis
Power Divider and CPW Design
Hybrid Coupler and Bandpass Filter Design
Directional Coupler and Magic Tee
Strip Line and Microstrip Line: Isolators, Circulators, and Faraday Rotation
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
This module covers the basics of antenna parameters and types. Using ANSYS, participants gain practical experience in antenna modeling and post-processing analysis. The internship provides insights into antenna behavior and performance, allowing users to visualize and analyze key parameters such as gain, radiation pattern, bandwidth, and impedance matching.
What Will You Learn?
Participants will gain clarity on antenna parameters and design approaches. Using ANSYS HFSS, they will learn to simulate various antennas and analyze key parameters like return loss, resonant frequency, and gain. This internship aims to provide a comprehensive understanding of antenna design principles and the practical application of simulation tools.
Hands-on Experience with HFSS for modeling and analysis
Collaboration with industry professionals
Practical Skills Development in antenna modeling
Knowledge Enhancement in wireless communication and related fields
Program Outline
Introduction to Antenna Parameters
HFSS Fundamentals: FEM, MOM, geometry, and material assignment
Reconfigurable Antennas: Concepts and applications
Types of Antennas: Dipole, slot, fractal, horn, helical, and reflector
Antenna Arrays: Design and applications
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
This module helps participants understand the basics of antenna parameters and types. It emphasizes using ANSYS for antenna modeling and post-processing analysis. Participants will gain the knowledge and skills to evaluate antenna performance and make informed design decisions. This internship provides valuable insights into effective antenna work.
What Will You Learn?
Participants will gain clarity on antenna parameters and design approaches. Using ANSYS HFSS, they will simulate various antennas and analyze key parameters like return loss, resonant frequency, and gain. This internship aims to provide a comprehensive understanding of antenna design principles and the practical application of simulation tools.
Key highlights
In-depth Exploration of antenna design, fabrication, and testing
Hands-on Experience with industry-standard software tools
Practical Knowledge of fabrication processes and materials
Skill Development in antenna development and testing
Career Preparation in antenna design and fabrication
Program Outline
Antenna Optimization and Radar Cross Section Analysis
Metamaterial Concepts: Design of split ring resonators
Frequency Selective Structures and their applications
Antenna Design: Dual band for mobile and wearable devices
Measurement Techniques: Fabrication and testing using anechoic chambers
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
IoT is a transformative technology connecting everyday objects like appliances and cars to the internet, enabling seamless communication between people, processes, and devices. Utilizing low-cost computing, cloud services, and big data, physical items can share and collect data with minimal human input, merging the physical and digital worlds.
What Will You Learn?
The program covers the fundamentals of IoT, including the four layers of architecture: hardware, software, networking, and cloud platforms. Participants will explore application areas, case studies, and opportunities in IoT, along with various tools and technologies.
Key highlights
Hands-on Experience with virtual IoT projects
Guidance and Mentorship from industry professionals
Enhanced Employability in the IoT field
Immersive Learning in a rapidly evolving industry
Practical Skills Development for real-world applications
Program Outline
Introduction to IoT: Success stories and architecture layers
Basic Electronics: Overview of sensors and signals
Microcontroller Concepts: Introduction to Arduino and its coding
NodeMCU with Blynk: Weather station project and mobile device control
Raspberry Pi: Integration, CLI usage, and running web applications for sensor logging
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
The growing number of devices in IoT networks generates overwhelming data. Traditional data management systems struggle with "big data" demands. The true value of IoT lies in the insights and services enabled by this data. To be useful, the data must be organized and controlled effectively.
What Will You Learn?
This program introduces βData Science and Analytics for IoT.β You'll learn to collect and analyze sensor data, focusing on data processing and machine learning algorithms for predictive analytics. The course covers an introduction to machine learning and Python, along with exploring various analytical tools and technologies.
Key highlights
Comprehensive Learning of IoT data analytics techniques
Hands-on Experience with IoT datasets
Guidance and Mentorship from experienced professionals
Enhancement of Technical Skills in IoT data management
Career Preparation for IoT analytics and data sciences
Program Outline
Introduction to IoT and Analytics: Context and reference architecture
IoT Data Overview: Use cases and data processing
Introduction to Machine Learning: Python basics for ML
IoT Analytics: Data science life cycle and KPIs
Data Analytics Techniques: Descriptive, inferential, predictive, exploratory, and prescriptive analytics
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
Ansys Mechanical is a top finite element solver that enhances modeling with structural, thermal, and nonlinear capabilities. Its user-friendly interface allows engineers to quickly solve complex problems and make informed design decisions. The platform offers customizable automation and robust solvers for efficient analysis of multiple scenarios.
What Will You Learn?
The internship focuses on Ansys Mechanical, an integrated platform for finite element analysis (FEA) in structural, thermal, and vibration applications. Candidates will explore analysis tools, application areas, and case studies, while also learning about opportunities in the analysis field and Ansys' product portfolio.
Key highlights
Structural Engineering Analysis
Thermal Analysis Capabilities
Acoustics Simulation
Linear Solvers
Certification
Program Outline
Introduction to Ansys and SpaceClaim Direct Modeler (SCDM)
SpaceClaim Modeling Techniques
Component Translations, Rotations, and Assembly Operations
Boolean Operations and Repair & Prepare Tools
Transfer to Workbench, Drafting, and Project Work Solutions
Note: All enrolled participants will receive two months of unlimited access to the session recordings. You can revisit and watch the content as many times as you like during this period to enhance your learning experience!
Product Development Simulation using Ansys SpaceClaim & Mechanical
About The Course
Ansys Mechanical is a premier finite element solver for structural, thermal, and nonlinear analysis, featuring an intuitive interface for quick and reliable results. It enables efficient customization and automation of solutions for complex engineering problems. Ideal for informed design decisions across multiple scenarios.
What Will You Learn?
The internship focuses on Ansys Mechanical, an integrated platform for finite element analysis (FEA) in structural, thermal, and vibration studies. It offers a complete suite of tools, from geometry preparation to advanced physics integration. Candidates will explore application areas, case studies, and opportunities within the analysis field, gaining insights into Ansys products and their portfolio.
Simulation for Analyst using Ansys SpaceClaim & Ansys Mechanical
About The Course
Ansys Mechanical is a top-tier finite element solver for structural, thermal, acoustic, transient, and nonlinear modeling. Its intuitive interface allows engineers to quickly and confidently solve complex structural problems, facilitating better design decisions through customizable and automated finite element analysis (FEA).
What Will You Learn?
The internship emphasizes Ansys Mechanical as an integrated platform for structural, thermal, and vibration analysis. Participants will explore a full range of analysis tools, from geometry preparation to advanced physics integration, while focusing on application areas and case studies, along with opportunities in the analysis field.
