Model Based Development -Mbd- For Automotive Using Simulink
Published 2/2023
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.66 GB | Duration: 4h 49m
Published 2/2023
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.66 GB | Duration: 4h 49m
To be Model Based Engineer
What you'll learn
0. Understand what is model based development in automotive industry
1. Navigate the Simulink Environment
1.1 Understand the Simulink interface
1.2 Add blocks and run a model
2. Simulink Solvers
2.1 Understand Simulink solvers and their role in model simulation
2.2 Compare variable and fixed step solvers
2.3 Determine which solver is appropriate for embedded systems
3. Basic Libraries
3.1 Recognize key blocks in each library
3.2 Analyze block parameters and their effects on behavior
3.3 Simulate each block with different inputs
4. Code Generation
4.1 Generate C code for individual blocks and block combinations
4.2 Understand the generated code and files
4.3 Analyze how block parameters impact the generated code
5. Custom Libraries
5.1 Create and reuse custom libraries in different models
6. MATLAB Function in Simulink
6.1 Insert and create MATLAB functions within a model
7. Real-World Application: Wiper System Controller
7.1 Implement, simulate and generate code for the Wiper System Controller project
Requirements
Basic Knowledge of MATLAB
Description
Model-based development (MBD) is an innovative approach to designing complex systems, such as software applications, control systems, and embedded systems. This methodology involves using models to represent different aspects of the system, such as its behavior, functionality, and structure. By creating and manipulating these models, developers can design, and simulate the system in a controlled and efficient manner.In this course, you will gain a deep understanding of the fundamentals of MBD and develop the skills necessary to succeed in this exciting field. You will start by learning the basic concepts and principles that underlie MBD, including the different types of models and their applications. You will also explore the various tools and techniques used in MBD, such as implementation and simulation.By the end of the course, you will have developed a deep understanding of the MBD process and acquired the practical skills to create and deploy models that meet industry standards and requirements. You will be well-prepared to join the MBD field and contribute to the development of complex systems that are efficient, reliable, and cost-effective.Whether you're a student, engineer, or researcher, this course will provide you with the knowledge and skills you need to succeed in the exciting and rapidly-evolving field of MBD. You'll be able to leverage your newfound expertise to design, implement, and test complex systems in a way that maximizes efficiency, quality, and performance.In addition to providing you with a strong foundation in MBD, this course is also designed to prepare you for the job market and for company interviews. By completing the course, you will gain a competitive edge and be well-prepared to enter the job market in the MBD field.
Overview
Section 1: Introduction
Lecture 1 Course Introduction
Lecture 2 MBD in ASpice V-model
Section 2: Simulink Environment
Lecture 3 Simulink Interface
Section 3: Simulink Solvers
Lecture 4 Solvers
Section 4: Sources Library
Lecture 5 Constant Block
Lecture 6 Ramp Block
Lecture 7 Input Block
Lecture 8 Step Block
Lecture 9 Clock Block
Lecture 10 Signal Builder Block
Section 5: Accessing Variables
Lecture 11 Accessing Variables - Model Explorer
Section 6: Data Types in Simulink
Lecture 12 Data Type Conversion
Section 7: Simple Code Generation
Lecture 13 Code Generation - How to generate Code
Lecture 14 Code Generation - Understand generated code
Section 8: Math Operations Library
Lecture 15 "Add", "Product", "Divide", "Gain" Blocks
Lecture 16 "Abs", "Sign", "Sqrt", "Minmax", "Sine Wave Function", "Math Function" Blocks
Section 9: Logic and bit Operations Library
Lecture 17 "Compare To Constant", "Compare To Zero", "Logical Operator" Blocks
Lecture 18 "Bitwise Operator", "Relational Operator" Blocks
Section 10: Discrete Library
Lecture 19 "Unit Delay" Block
Section 11: Discontinuities Library
Lecture 20 "PWM", "Saturation" Blocks
Section 12: Signal Routing Library
Lecture 21 "Mux", "Demux" Blocks
Lecture 22 "Goto", "From" Blocks
Lecture 23 "Switch" Block
Lecture 24 "Merge" Block
Section 13: Lookup Tables Library
Lecture 25 "1-D Lookup Table" Block Simulation
Lecture 26 "1-D Lookup Table" Block Code Generation
Section 14: Ports & Subsystems Library - Subsystems Masks
Lecture 27 "Subsystem" Block
Lecture 28 Subsystems Masks
Lecture 29 "Enable" and "Enabled Subsystem" blocks
Lecture 30 "Function-Call Generator" and "Function-Call Subsystem" Blocks
Lecture 31 "Trigger" and "Triggered Subsystem" Blocks
Lecture 32 "If" and "If Action Subsystem" Blocks
Lecture 33 "Switch Case" and "Switch Case Action Subsystem" Blocks
Section 15: Custom Library
Lecture 34 Custom Library
Section 16: MATLAB Function inside Simulink
Lecture 35 "MATLAB Function" Block
Section 17: Automotive Project - Wiper System Application
Lecture 36 Project - Project and Requirements Description
Lecture 37 Project - Method 1 - Model Implementation
Lecture 38 Project - Method 1 - Code Generation
Lecture 39 Project - Method 2 - Model Implementation
Lecture 40 Project - Method 2 - Code Generation
Undergraduate and graduate students seeking a model-based development engineering position,Embedded software engineers who want to work on the application layer using the model-based development approach,Software engineers who want to work in the automotive industry using the model-based development approach