Diploma in SIL/HIL: Plant Integration and Control
About us Diploma in SIL/HIL: Plant Integration and Control
The Diploma in SIL/HIL: Plant Integration and Control explores the design and validation of control systems in SIL (Software-in-the-Loop) and HIL (Hardware-in-the-Loop) simulation environments. The program focuses on the application of these methodologies to test and validate complex systems, such as those used in the automotive and aerospace industries, integrating plant control and its modeling. Advanced simulation tools and dynamic systems control techniques are included, enabling software and hardware verification in a simulated environment, with an emphasis on functional safety and performance optimization. Hands-on experience is provided in the use of SIL/HIL equipment, and industrial automation, control system design, and sensor and actuator integration are addressed. The diploma program prepares professionals for roles in control engineering, embedded systems development, and complex systems validation, familiarizing them with standards such as ISO 26262 and others related to system safety. Emphasis is placed on the ability to analyze and solve problems in complex control systems and improve the efficiency and reliability of those systems.
Target keywords (naturally occurring in the text): SIL, HIL, plant control, simulation, embedded systems, industrial automation, functional safety, system validation, ISO 26262.
Diploma in SIL/HIL: Plant Integration and Control
- Format: Online
- Duration: 8 months
- Hours: 900 H
- Language: ES / EN
- Credits: 60 ECTS
- Registration date: 04-07-2026
- Strat date: 14-08-2026
- Available places: 4
1.750 $
Competencias y resultados
Qué aprenderás
1. SIL/HIL Domain: Integration, Plants, and Control for Advanced Systems
Para quien va dirigido nuestro:
Diploma in SIL/HIL: Plant Integration and Control
9.9 Legal and Regulatory Framework in the Naval Industry
9.9 Introduction to Rotor Modeling: Fundamentals and Principles
9.3 Types of Rotors: Design, Materials, and Applications
9.4 Mathematical Modeling of Rotors: Equations and Key Variables
9.5 Modeling Software: Specialized Tools and Platforms
9.6 Rotor Design: Geometric and Aerodynamic Considerations
9.7 Modeling Methodology: Efficient Steps and Strategies
9.8 Rotor Model Validation and Verification
9.9 Applications of Rotor Modeling in the Naval Sector
9.90 Case Studies: Rotor Modeling in Different Naval Scenarios
9.9 Rotor Performance Principles: Efficiency and Power
9.9 Evaluation Parameters: Thrust, Speed, and Fuel Consumption
9.3 Evaluation Techniques: Bench Testing and Simulation
9.4 Performance Data Analysis: Interpretation and Conclusions
9.5 Factors Affecting the Performance: Design and Operation
9.6 Performance Optimization: Strategies and Tools
9.7 Performance Evaluation Under Real-World Conditions: Challenges
9.8 Design for Efficiency: Integration in Naval Systems
9.9 Risk Assessment: Performance and Safety Analysis
9.90 Case Studies: Performance Evaluation in Different Rotors
3.9 Introduction to SIL/HIL Analysis: Concepts and Applications
3.9 Integration of Control Systems in SIL/HIL Environments
3.3 Design and Simulation of Naval Control Systems
3.4 Controllers: Types, Functions, and Settings
3.5 SIL/HIL Testing: Methodologies and Protocols
3.6 Control Implementation: Strategies and Techniques
3.7 Verification and Validation of Control Systems
3.8 Fault Analysis: Detection and Mitigation
3.9 Applications of SIL/HIL Analysis in Naval Systems
3.90 Case Studies: Control Analysis in Naval Scenarios
4.9 Introduction to SIL/HIL Simulation of Dynamic Plants
4.9 Modeling Dynamic Plants: Components and Systems
4.3 Real-Time Simulation: Requirements and Techniques
4.4 Hardware Integration in the Loop (HIL)
4.5 Scenario Simulation: Operating Conditions and Failures
4.6 Results Analysis: Interpretation and Optimization
4.7 Design of Control Systems for Dynamic Plants
4.8 Testing and Validation of Simulated Systems
4.9 Applications in Naval Propulsion and Control Systems
4.90 Practical Cases: Simulation of Dynamic Plants in SIL/HIL
5.9 Rotor Optimization: Objectives and Strategies
5.9 Optimal Design: Design Parameters and Variables
5.3 Optimization Tools: Algorithms and Software
5.4 Multi-objective Optimization: Considerations and Techniques
5.5 Analysis Performance: Metrics and Evaluation
5.6 Design for Energy Efficiency
5.7 Optimization for Different Naval Applications
5.8 Sensitivity and Robustness of the Optimized Design
5.9 Integration with SIL/HIL Systems
5.90 Case Studies: Rotor Optimization in Different Scenarios
6.9 Introduction to Rotorcraft Evaluation in SIL/HIL
6.9 Detailed Rotorcraft Modeling: Components and Systems
6.3 Integration of Flight Control Systems
6.4 Flight Simulation: Scenarios and Conditions
6.5 SIL/HIL Testing: Methodologies and Evaluation Protocols
6.6 Simulation Data Analysis: Interpretation and Conclusions
6.7 Performance and Safety Evaluation
6.8 Validation of Models and Systems
6.9 Applications in Rotorcraft Design and Development
6.90 Case Studies: Rotorcraft Evaluation in SIL/HIL
7.9 SIL/HIL Environments: Configuration and Components
7.9 Rotor Modeling: Adaptation for SIL/HIL
7.3 Integration of the Rotor Model into the SIL/HIL System
7.4 Real-Time Simulation: Challenges and Solutions
7.5 Design of Control Systems for SIL/HIL
7.6 Validation and Verification of the Model in the SIL/HIL Environment
7.7 Results Analysis: Interpretation and Optimization
7.8 Design Considerations for SIL/HIL
7.9 Applications in Naval Design and Development
7.90 Case Studies: Rotor Modeling in SIL/HIL Environments
8.9 Rotor Performance in SIL/HIL: Parameters and Metrics
8.9 Real-Time Performance Evaluation
8.3 Performance Optimization in SIL/HIL Environments
8.4 Sensitivity and Robustness Analysis
8.5 Integration with Systems Control
8.6 Design for Efficiency: Design Considerations
8.7 System Validation and Verification
8.8 Failure Simulation and Risk Analysis
8.9 Applications in Naval Systems
8.90 Case Studies: Performance Evaluation in SIL/HIL
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