With Model-Based Design, behavioral models are at the center of your development process. How much do you know about applying Model-Based Design to the development of fuel cells?
Take the quiz—just 10 questions—to find out.
Question 1/10
What is Model-Based Design?
Question 2/10
What kind of fuel cell system model can you develop using Model-Based Design?
Question 4/10
After simulating your fuel cell model—with control algorithms and the multidomain physical system—which of the following is NOT true for Model-Based Design?
Question 5/10
Which of the following is NOT a way in which Model-Based Design helps save time and money in developing your fuel cell system project?
Question 6/10
True or False? Model-Based Design supports AUTOSAR-compliant workflows when developing fuel cell systems for automotive applications.
Question 7/10
What can you do with existing C/C++ code—such as control algorithms, device drivers, lookup tables, and generic functions supporting your fuel cell applications—when you adopt Model-Based Design?
Question 8/10
Which of the following model verification activities can be automated for your fuel cell system with Model-Based Design?
Question 9/10
In the process of developing fuel cell systems, Model-Based Design complements and enables Agile development practices, including:
Question 10/10
What types of subsystems can you model with Simscape™ in a fuel cell system?
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Answer Key
- What is Model-Based Design? The systematic use of models throughout the development process, from requirements specification to system operation.
- With Model-Based Design you can develop: i) A detailed fuel cell system that includes a membrane electrode assembly, a multispecies gas network, and a thermal management system; ii) A powertrain model of a fuel cell virtual vehicle that combines a fuel cell, a battery system, and an electric motor; iii) A digital twin of the fuel cell system to monitor key output characteristics and optimize operation
- Using Model-Based Design for fuel cell system simulation helps with: i) Selecting and sizing components of your design; ii) Designing and validating control algorithms for thermal, humidity, and pressure management even before hardware is available; iii) Reducing development time by verifying functionality of controllers and generating optimized code for embedded controllers from simulation models
- After simulating your fuel cell model containing control algorithms and the multidomain physical system, which of the following is NOT true for Model-Based Design? You cannot generate code because Model-Based Design only supports simulations
- Which of the following is NOT a way in which Model-Based Design helps save time and money in developing your fuel cell system project? Providing hardware prototypes that are already built for your project
- Model-Based Design supports AUTOSAR-compliant workflows when developing fuel cell systems for automotive applications.
- What do you do with existing C/C++ code, such as control algorithms, device drivers, lookup tables, and generic functions supporting your fuel cell applications when you adopt Model-Based Design? Existing C/C++ code can be integrated directly in your models for simulation, verification, and code generation
- The following model verification activities can be automated for your fuel cell system with Model-Based Design: i) Requirements traceability; ii) Standards compliance checking; iii) Coverage analysis and test case generation; iv) Design error detection (e.g., dead logic, integer overflow, division by zero)
- In the process of developing fuel cell systems, Model-Based Design complements and enables Agile development practices, including: Continuous integration for automatic testing and verification of models and code
- With Simscape, you can model different subsystems within a fuel cell system. These subsystems include: i) pressure-reducing valve subsystems; ii) recirculation subsystems; iii) coolant tank subsystems; iv) gas channels subsystems
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