RTOS Avionics Course
About ourRTOS Avionics Course
The RTOS in Avionics course focuses on the design, implementation, and certification of real-time operating systems (RTOS) in critical aviation applications. Topics explored include embedded architectures, task scheduling, inter-process communication (IPC), and compliance with standards such as DO-178C. The course prepares participants to develop safe and reliable software for flight control units (FCUs), navigation systems, and other critical aeronautical applications.
The program includes hands-on exercises and case studies to master the use of RTOS development and debugging tools in simulation and real-hardware environments. Participants learn to optimize the performance and reliability of embedded software, ensuring safety and compliance with aerospace industry regulations.
The training focuses on the software architecture and communication protocols used in modern avionics.
Target keywords (natural occurrences in the text): RTOS, avionics, DO-178C, embedded software, real-time systems, aviation safety, FCU, task scheduling, IPC.
RTOS Avionics Course
- Modalidad: Online
- Duración: 4 meses
- Horas: 300 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrícula: 30-05-2026
- Fecha de inicio: 02-07-2026
- Plazas disponibles: 3
575 $
Competencies and outcomes
What you will learn
1. Development and Optimization of RTOS for Avionic Systems
- Apply the knowledge acquired in practical design and development projects for RTOS systems for avionics.
Understand the architecture and fundamental principles of Real-Time Operating Systems (RTOS).
Master programming and software development techniques for specific RTOSs, adapted to the demands of avionics.
Learn to optimize RTOS performance in avionics environments, considering efficiency, reliability, and safety.
Study the communication protocols and hardware interfaces used in avionics systems, and how to integrate them with RTOSs.
Analyze the certification and regulatory compliance requirements for RTOSs in the aerospace industry.
Develop skills for troubleshooting and debugging RTOS systems in simulation and real-world hardware environments.
Explore emerging trends in RTOSs for avionics, including the use of multicore systems and the integration of artificial intelligence.
2. RTOS Mastery in Avionics: Design, Implementation, and Performance
- Understand the architecture and fundamental principles of Real-Time Operating Systems (RTOS) applied to avionics.
- Analyze the characteristics of aviation-specific RTOSs, including their task management, scheduling, synchronization, and inter-process communication.
- Design and implement embedded systems based on RTOSs for critical avionics applications, such as flight control, navigation, and engine management.
- Evaluate the performance of RTOSs in avionics environments, considering factors such as latency, response time, and energy efficiency.
- Use development and simulation tools for programming, debugging, and testing RTOS applications in avionics.
- Apply security and reliability techniques to protect RTOS systems against failures, errors, and cyberattacks.
- Integrate RTOS systems with avionics hardware and software, including sensors, actuators, displays, and other systems.
- Adapt and optimize RTOS systems to meet the requirements of aeronautical industry regulations and standards, such as DO-178C.
- Diagnosticate and troubleshoot RTOS-related issues in avionics, including programming errors, resource conflicts, and performance bottlenecks.
- Stay up-to-date with the latest trends and advancements in RTOS technology for avionics, including new operating systems, development tools, and design methodologies.
Communication.
3. Comprehensive user-oriented design and validation (from modeling to manufacturing)
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
4. Implementation and Configuration of RTOS in Aviation Systems
4. Implementation and Configuration of RTOS in Aviation Systems
- Understand the fundamentals of Real-Time Operating Systems (RTOS).
- Analyze the architecture and key components of RTOS.
- Study the differences between RTOS and conventional operating systems.
- Explore the specific requirements of RTOS in aviation.
- Become familiar with aerospace industry standards for RTOS.
- Learn about task scheduling and resource management in RTOS.
- Configure RTOS for critical avionics applications.
- Implement communication protocols in RTOS for aviation systems.
- Manage synchronization and interrupt control in RTOS.
- Apply debugging and testing techniques to RTOS systems.
- Analyze the safety and reliability of RTOSs in aviation.
- Implement fault detection and management mechanisms in RTOSs.
- Study the design and implementation of embedded systems based on RTOSs.
- Learn to optimize the performance of RTOSs for aviation.
- Explore the use of RTOSs in different avionics systems (flight control, navigation, etc.).
1. Analysis and Programming of RTOS in Aviation
## What Will You Learn in RTOS Analysis and Programming in Aviation?
- Understand the structure and function of Real-Time Operating Systems (RTOS) in critical aeronautical environments.
- Analyze the specific challenges of aviation, such as high availability, safety, and predictability, that influence RTOS design.
- Master RTOS programming techniques, including task management, synchronization, inter-process communication, and interrupt handling.
- Apply RTOS development and debugging tools for the creation and testing of aeronautical applications.
- Study and understand the safety and certification standards (DO-178C, etc.) required for aviation software development and how they relate to RTOS.
- Learn how to optimize RTOS performance in terms of latency, determinism, and resource utilization, which are critical in aeronautical applications.
- Explore examples of RTOS in use in aviation, such as VxWorks, Integrity, or FreeRTOS, and understand their advantages and disadvantages.
Develop skills for the design, implementation, and validation of embedded systems based on RTOS for aeronautical applications.
Analyze and solve specific problems related to the integration of RTOS with aeronautical hardware.
Acquire knowledge about future trends in RTOS for aviation, such as distributed real-time computing and embedded artificial intelligence.
6. Integration and Testing of RTOS in Aviation: From Concept to Implementation
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
Who our [course/program] is aimed at:
RTOS Avionics Course
- Engineers with degrees in Aerospace, Mechanical, Electronics, Automation, or related fields.
- Technical personnel from aircraft OEMs, MROs, aeronautical consulting firms, and research centers.
- Professionals in areas such as Flight Testing, Aeronautical Certification, Avionics, Systems Control, and Flight Dynamics.
- Officials and specialists from regulatory authorities, as well as professionals involved in UAM/eVTOL projects interested in regulatory compliance (compliance).
Recommended Requirements: Prior knowledge of aerodynamics, control systems, and aircraft structures; proficiency in English (B2/C1). Bridging tracks are available.
- Standards-driven curriculum: you will work with CS-27/CS-29, DO-160, DO-178C/DO-254, ARP4754A/ARP4761, ADS-33E-PRF from the first module.
- Accreditable laboratories (EN ISO/IEC 17025) with rotor bench, EMC/Lightning pre-compliance, HIL/SIL, vibrations/acoustics.
- Evidence-oriented TFM: safety case, test plan, compliance dossierand operational limits.
- Mentored by industry: teachers with experience in rotorcraft, tiltrotor, eVTOL/UAM and flight test.
- Flexible modality (hybrid/online), international cohorts and support from SEIUM Career Services.
- Ethics and security: safety-by-design approach, cyber-OT, DIH and compliance as pillars.
Module 1 — Aviation RTOS Architecture and Design
1. Fundamental Concepts of Aviation RTOS
2. RTOS Architecture: Core, Scheduler, and Services
3. Embedded Systems Design for Aviation
4. Selection and Evaluation of Aviation RTOS
5. Software Development Life Cycle for RTOS
6. Development and Debugging Tools for RTOS
7. Real-Time and Determinism Considerations
8. Designing Interfaces and Drivers for Specific Hardware
9. Security and Protection in Aviation RTOS
10. Examples of RTOS Applications in Aeronautical Systems
2. Introduction to RTOS Architecture and its Importance in Avionics
3. RTOS Selection: Criteria and Considerations for Aviation Applications
4. RTOS Design: Structure, Components, and Design of Avionics Systems
5. RTOS Implementation: Programming, Configuration, and Hardware Deployment
6. RTOS Performance Optimization: Analysis Techniques and Tools
7. Task Management and Synchronization in RTOS: Prioritization and Control
8. RTOS Interrupt and Event Handling: Safe and Efficient Design
9. RTOS Testing and Debugging: Functionality and Robustness Verification
20. RTOS Safety Considerations: Certification and Regulatory Compliance
22. Case Studies: Real-World Applications of RTOS in Avionics Systems
3.3 Introduction to RTOS Architecture: Fundamentals and Key Concepts
3.2 Structure and Components of an RTOS: Kernel, Scheduler, Memory
3.3 Design of Critical Avionics Systems: Requirements and Considerations
3.4 Critical Avionics Applications: Flight Control, Navigation, Communication
3.5 Selecting the Appropriate RTOS: Criteria and Decision Factors
3.6 Hardware-Software Architecture: Interaction and System Design
3.7 Resource Management in RTOS: Tasks, Threads, Priorities
3.8 Communication and Synchronization: Semaphores, Mutexes, Queues
3.9 Interrupt Handling: Design and Implementation in RTOS
3.30 Performance Analysis and Optimization: Response Times, Latency
4.4 Introduction to RTOSs: Concepts and Fundamentals
4.2 RTOS Selection: Criteria and Considerations
4.3 System Design: Architecture and Software Design
4.4 RTOS Implementation: Configuration and Code Development
4.5 Hardware Integration: Interfaces and Controllers
4.6 Task Management: Creation, Scheduling, and Synchronization
4.7 Inter-Task Communication: Messages, Semaphores, and Mutexes
4.8 Interrupt Handling: Priority and Treatment
4.9 Testing and Debugging: Strategies and Tools
4.40 Security and Robustness: Design Considerations
5. Development of RTOS for Avionics Systems
5. Structure and Optimization of RTOS in Aviation Systems
3. RTOS Design for Critical Avionics Applications
4. Configuration and Applications of RTOS in Aviation
5. Programming and Analysis of RTOS for Aviation
6. Testing and Execution of RTOS in Avionics
7. Verification and Security of RTOS in Avionics
8. Applications and Testing of Advanced RTOS Programming in Avionics
6.6 Fundamentals of RTOS Integration in Avionics
6.2 Testing Strategies for RTOS Systems in Aviation
6.3 Tools and Development Environments for RTOS Integration
6.4 Integrating RTOS with Avionics-Specific Hardware
6.5 RTOS Software and Hardware Integration Testing
6.6 Verification and Validation of RTOS for Regulatory Compliance
6.7 Simulation and Emulation in RTOS Testing
6.8 Troubleshooting and Debugging in RTOS Integration
6.9 RTOS Test Documentation and Reporting
6.60 Case Studies of RTOS Integration and Testing in Aviation
7.7 RTOS Fundamentals: Concepts and Principles
7.2 RTOS Architecture for Avionics: Key Components
7.3 RTOS Design for Aeronautical Applications: Requirements and Constraints
7.4 Software Development in RTOS: Tools and Techniques
7.7 Real-Time Systems: Task Planning and Management
7.6 RTOS Debugging and Testing: Strategies and Tools
7.7 Communication Systems in RTOS: Protocols and Standards
7.8 RTOS Security and Reliability: Design Considerations
2.7 RTOS Optimization Strategies: Performance and Efficiency
2.2 Code Optimization: Techniques and Best Practices
2.3 Memory Optimization: Management and Efficient Use
2.4 Runtime Optimization: Analysis and Tuning
2.7 Optimization Tools: Profiling and Performance Analysis
2.6 Optimization for Specific Platforms: Hardware Considerations
2.7 Power Management in RTOS: Design and Configuration
2.8 Performance Testing and Optimization Validation
3.7 RTOS Architecture for Critical Systems: Design and Functionality
3.2 Security Models in RTOS: Implementation and Evaluation
3.3 Redundant Systems and Fault Tolerance: Design and Configuration
3.4 Design for Aeronautical Certification: Standards and Regulations
3.7 Critical Real-Time Systems: Analysis and Design
3.6 User Interface in RTOS: Design and Development
3.7 Data Protection and Security in RTOS
3.8 Case Studies: RTOS Architectures in Avionics
4.7 Selecting the Appropriate RTOS: Criteria and Considerations
4.2 RTOS Configuration: Parameters and Options
4.3 RTOS Implementation in Hardware: Interface and Drivers
4.4 Software Integration in RTOS: Development and Testing
4.7 Integration Testing: Verification and Validation
4.6 Implementation and Configuration Tools
4.7 File Systems and Storage in RTOS
4.8 Documentation and Technical Support for RTOS
7.7 Requirements Analysis: Specifications and Design
7.2 Software Design: Architecture and Modularity
7.3 Task and Process Scheduling: Implementation and Management
7.4 Interrupt Scheduling: Handling and Optimization
7.7 Inter-Task Communication Scheduling
7.6 Performance Analysis: Measurement and Evaluation
7.7 Debugging and Troubleshooting
7.8 Implementation of Communication Protocols
6.7 Hardware and Software Integration: Approaches and Methodologies
6.2 Unit Testing: Verification of Individual Components
6.3 Integration Testing: Verification of Interaction Between Modules
6.4 System Testing: Validation of the Complete System
6.7 Performance Testing: Evaluation of System Performance
6.6 Security Testing: Verification of System Security
6.7 Test Report Generation: Documentation and Analysis
6.8 Testing and Certification Methodologies in Avionics
7.7 Code Verification: Techniques and Tools
7.2 Static Code Analysis: Error and Vulnerability Detection
7.3 Security Testing: Fault Detection and Prevention
7.4 Security Systems in RTOS: Design and Implementation
7.7 RTOS Certification: Standards and Processes
7.6 Security Requirements Verification
7.7 Security Policy Implementation
7.8 Risk Analysis and Mitigation in RTOS
8.7 Advanced Programming: Concepts and Techniques
8.2 Code Optimization: Advanced Techniques
8.3 Memory Management: Advanced Strategies
8.4 Task Scheduling: Algorithms and Configuration
8.7 Performance Testing: Measurement and Evaluation
8.6 Advanced Debugging: Tools and Techniques
8.7 Specific Real-Time Applications: Examples
8.8 Implementing Case Studies: Real-World Applications
8.8 Introduction to RTOS: Fundamental Concepts and Applications in Aviation
8.8 RTOS Architecture: Structure, Components, and Internal Operation
8.3 Real-Time Systems: Characteristics and Challenges in Aviation
8.4 RTOS Development: Tools, Languages, and Methodologies
8.5 RTOS Design: Specific Considerations for Avionics Systems
8.6 Performance Optimization: Techniques and Strategies
8.7 RTOS and Security: Data Integrity and Protection
8.8 Testing and Validation: Ensuring Quality and Reliability
8.8 RTOS Design Fundamentals for Avionics
8.8 Resource Optimization: Memory, Processor, and Power
8.3 Concurrent Programming: Threads, Tasks, and Synchronization
8.4 Task Scheduling: Algorithms and Strategies
8.5 Performance Analysis: Latency, Jitter, and Response Times
8.6 Debugging Techniques: Tools and Methodologies
8.7 Code Optimization: Efficiency and Performance
8.8 Case Studies: Practical Examples of Optimization
3.8 RTOS Architecture: Requirements for Critical Applications
3.8 Designing Fault-Tolerant Systems: Redundancy and Resilience
3.3 Certification and Regulatory Compliance: DO-878C and Related Standards
3.4 Design for Security: Protection Against Faults and Attacks
3.5 Interprocess Communication: Messaging and Synchronization
3.6 Exception Handling: Error Detection and Response
3.7 Risk Analysis: Threat Identification and Mitigation
3.8 Case Studies: RTOS Architectures in Critical Systems
4.8 RTOS Selection: Criteria and Key Factors
4.8 Installation and Configuration: Development Environment and Tools
4.3 Kernel Configuration: Tasks, Interrupts, and Timers
4.4 Peripheral Configuration: Communication and Sensors
4.5 Software Integration: Drivers and Libraries
4.6 Configuration Testing: Verification and Validation
4.7 Documentation and Manuals: Implementation Guides
4.8 Troubleshooting: Error Detection and Correction
5.8 Requirements Analysis: Specifications and Design
5.8 Programming Languages: C, C++, and Assembly
5.3 Task Scheduling: Code Design and Development
5.4 Interrupt Handling: Routines and Priorities
5.5 Synchronization and Communication: Semaphores, Mutexes, and Queues
5.6 Controller Programming: Sensors and Actuators
5.7 Debugging and Testing: Tools and Techniques
5.8 Case Studies: Analysis and Programming of Examples
6.8 Hardware and Software Integration
6.8 Test Design: Strategies and Methodologies
6.3 Unit Testing: Verification of Individual Components
6.4 Integration Testing: Interaction Between Modules
6.5 System Testing: Performance and Functionality
6.6 Security Testing: Integrity and Protection
6.7 Test Automation: Tools and Techniques
6.8 Reporting and Analysis: Results and Conclusions
7.8 Verification Implementation: Standards and Norms
7.8 Verification Techniques: Static and Dynamic Analysis
7.3 Security Testing: Vulnerability Verification
7.4 Fault Analysis: Fault Design and Testing
7.5 Code Verification: Review and Auditing
7.6 Certification: Processes and Documentation
7.7 Secure System Design: Mitigation Strategies
7.8 Case Studies: Implementation and Verification in Systems
8.8 Performance Optimization: Advanced Techniques
8.8 Low-Level Programming: Direct Hardware Access
8.3 Embedded System Design: Advanced Architectures
8.4 Real-Time Programming: Advanced Strategies
8.5 Profiling Tools: Analysis and Optimization
8.6 Performance Testing: Strategies and Methodologies
8.7 Software Development: Methodologies Agile
8.8 Case studies: Advanced application programming
9.9 Introduction to RTOS systems and their application in aeronautics.
9.9 Key components of the RTOS architecture.
9.3 Comparison of different RTOS architectures.
9.4 Design of embedded systems with RTOS.
9.5 Design considerations for avionics applications.
9.6 Selecting the appropriate RTOS for specific applications.
9.7 Case studies: RTOS architectures in current aeronautical systems.
9.8 Testing and validation of the RTOS architecture.
9.9 Future of RTOS architectures in aviation.
9.9 RTOS design principles in avionics.
9.9 Task planning and management in RTOS.
9.3 Synchronization and communication between tasks.
9.4 Optimizing RTOS performance.
9.5 Performance metrics and evaluation.
9.6 Strategies for handling interruptions. 9.7 Analysis of RTOS Performance Case Studies
9.8 Tools and Techniques for Performance Analysis
9.9 Continuous Performance Improvement in RTOS Systems
3.9 Identification of Critical Applications in Avionics
3.9 Safety and Reliability Requirements in RTOS Systems
3.3 Implementation of Safety Mechanisms in RTOS
3.4 Design of Redundant and Fault-Tolerant Systems
3.5 Verification and Validation of Critical Systems
3.6 Case Studies of Critical RTOS Systems in Aviation
3.7 Safety Regulations and Standards in RTOS
3.8 Certification of Critical Systems
3.9 Trends in RTOS Development for Critical Applications
4.9 Selecting the Appropriate RTOS for an Avionics System
4.9 Basic and Advanced RTOS Configuration
4.3 Customizing the RTOS for Specific Requirements 4.4 Configuring tasks, queues, semaphores, and other components.
4.5 Designing communication interfaces.
4.6 Configuration and development tools.
4.7 Practical configuration examples on different platforms.
4.8 Memory and resource management in RTOS.
4.9 Troubleshooting and debugging in RTOS environments.
5.9 Requirements analysis and software design in RTOS.
5.9 Programming languages and development tools.
5.3 Task scheduling and process management.
5.4 Implementing synchronization and communication between tasks.
5.5 Programming device drivers.
5.6 Debugging strategies and unit testing.
5.7 Using simulators and emulators.
5.8 Performance analysis and code optimization.
5.9 Best practices for programming in RTOS environments.
6.9 RTOS Integration Process in Avionics Systems
6.9 Unit and Integration Testing Techniques
6.3 Functional and Performance Testing
6.4 Security and Robustness Testing
6.5 Test Scenario Design
6.6 Testing and Debugging Tools
6.7 Test Automation
6.8 Documentation and Results Reporting
6.9 RTOS System Certification and Validation
7.9 Design of Secure Systems in RTOS
7.9 Implementation of Security Measures
7.3 Verification and Validation Techniques
7.4 Risk Analysis and Mitigation
7.5 RTOS Security Certification
7.6 Security Testing and Vulnerability Analysis
7.7 Security Management in the Software Development Lifecycle
7.8 Avionics Security Standards and Regulations
7.9 Implementation of efficient systems in RTOS.
8.9 Code and performance optimization.
8.9 Advanced programming techniques.
8.3 Use of analysis and optimization tools.
8.4 Implementation of memory management techniques.
8.5 Design of complex real-time systems.
8.6 Implementation of distributed systems.
8.7 Performance analysis and fine-tuning.
8.8 Optimization case studies in avionics applications.
8.9 Advanced development and debugging tools.
9.9 RTOS applications in flight control systems.
9.9 Engine management systems.
9.3 Navigation and communication systems.
9.4 Visualization and monitoring systems.
9.5 Testing and simulation of RTOS systems.
9.6 Development of avionics applications using RTOS.
9.7 Real-world application case studies.
9.8 Future trends in the use of RTOS in aviation.
9.9 Design considerations for different aircraft types.
9.90 Market outlook and job opportunities.
1. RTOS Architecture for Avionics: Fundamentals and Critical Applications
2. Implementing RTOS in Avionics: System Configuration and Design
3. Analyzing RTOS in Aviation: Programming and Software Design
4. Integrating and Testing RTOS in Aviation: From Concept to Execution
5. Verifying RTOS in Avionics: Implementation Safety and Efficiency
6. Advanced Optimization of RTOS for Avionics: Programming and Testing
7. Designing and Optimizing RTOS for Avionic Systems: Performance and Reliability
8. Mastering RTOS in Avionics: Design, Implementation, and Evaluation
9. Validating RTOS for Avionics: Testing and Certification
10. Final Project: Designing, Implementing, and Testing an Avionic RTOS
- Hands-on methodology: test-before-you-trust, design reviews, failure analysis, compliance evidence.
- Software (depending on licenses/partners): MATLAB/Simulink, Python (NumPy/SciPy), OpenVSP, SU2/OpenFOAM, Nastran/Abaqus, AMESim/Modelica, acoustics tools, planning toolchains DO-178C.
- SEIUM Laboratories: scale rotor bench, vibrations/acoustics, EMC/Lightning pre-compliance, HIL/SIL for AFCS, data acquisition with strain gauging.
- Standards and compliance: EN 9100, 17025, ISO 27001, GDPR.
Capstone-type projects
Admissions, fees, and scholarships
- Profile: Background in Computer Engineering, Mathematics, Statistics, or related fields; practical experience in NLP and valued information retrieval systems.
- Documentation: Updated CV, academic transcript, SOP/statement of purpose, project examples or code (optional).
- Process: Application → Technical evaluation of profile and experience → Technical interview → Review of case studies → Final decision → Enrollment.
- Fees:
- Single payment: 10% discount.
- Payment in 3 installments: No fees; 30% upon registration + 2 equal monthly payments of the remaining 35%.
Monthly payment: available with a 7% commission on the total; annual review.
Scholarships: based on academic merit, financial need, and promoting inclusion; agreements with companies in the sector for partial or full scholarships.
See “Calendar & Calls for Applications,” “Scholarships & Grants,” and “Fees & Financing” in the SEIUM mega-menu.
Do you have any questions?
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F. A. Q
Frequently asked questions
Yes, we have international certification
Yes: experimental models, real data, applied simulations, professional environments, real case studies.
It is not mandatory. We offer leveling tracks and tutoring.
Completely. It covers e-propulsion, integration, and emerging regulations (SC-VTOL).
Recommended. There are also internal challenges and consortiums.
Yes. Online/hybrid modality with planned labs and visa support (see “Visa & Residence”).