Diploma in BOM 150/151 Structures and Engineering Changes
Sobre nuestro Diploma in BOM 150/151 Structures and Engineering Changes
The Diploma in BOM 150/151 Structures and Engineering Changes focuses on the management and understanding of Bill of Materials (BOM) 150/151 structures, crucial for managing engineering components. It emphasizes the implementation of effective engineering changes, integrating processes for the accurate updating of documentation, including drawings and specifications. The diploma provides tools and knowledge to optimize configuration management, control information flow, and ensure traceability in design and production.
The program includes hands-on experience using specialized software for managing BOMs and engineering changes, as well as interpreting relevant regulations and standards. Participants acquire problem-solving and decision-making skills in design and manufacturing environments, including analyzing the impact of changes on costs and delivery times.
The training prepares individuals for roles such as configuration management engineers, engineering change coordinators, and BOM analysts, improving efficiency in the manufacturing industry. Target keywords (natural occurrences in the text): BOM 150/151, engineering changes, configuration management, information flow, traceability, component management, design, production.
Diploma in BOM 150/151 Structures and Engineering Changes
- Modalidad: Online
- Duración: 8 meses
- Horas: 900 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrÃcula: 19-06-2026
- Fecha de inicio: 30-07-2026
- Plazas disponibles: 3
950 $
Competencias y resultados
Qué aprenderás
1. Expertise in BOM 150/151 Structures and Engineering Change Management
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Gain a deeper understanding of the interpretation and detailed analysis of BOM 150/151 structures, comprehending their functionality, components, and relationship to the overall design.
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Learn to optimize the design and efficiency of BOM 150/151 structures through the application of engineering principles and industry best practices.
Acquire advanced skills in engineering change management, including documentation, version control, and the implementation of modifications to existing structures.
Become familiar with the processes for validating and verifying changes, ensuring the integrity and conformity of BOM 150/151 structures.
Master the tools and techniques for identifying and resolving problems in structures, including failure analysis and the implementation of improvements.
Develop a comprehensive understanding of the standards and regulations applicable to BOM 150/151 structures and change management, ensuring regulatory compliance.
2. Master's Degree in BOM 150/151 and Strategic Transformation of Engineering
- Understand and apply the fundamental principles of strategic transformation in engineering.
- Master the key concepts related to the analysis and design of aircraft structures, including an understanding of the BOM 150/151 codes.
- Apply advanced structural analysis techniques, such as finite element analysis (FEA), for the evaluation of aeronautical components.
- Deepen the study of aerodynamics and aeroelasticity, understanding critical phenomena such as flap-lag-torsion, whirl flutter, and their impact on structural integrity.
- Evaluate and mitigate the effects of fatigue on aeronautical materials and structures, implementing design and predictive maintenance strategies.
- Acquire solid knowledge in the design and dimensioning of components manufactured with composite materials, including Understanding their properties and behavior.
Analyze and optimize structural and bonded joints using FEA tools, ensuring the integrity and durability of structures.
Understand and apply damage tolerance methodologies for managing damage to structures, guaranteeing the safety and reliability of aircraft.
Become familiar with advanced non-destructive testing (NDT) techniques, including ultrasonic testing (UT), radiography (RT), and thermography, for the early detection of defects.
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. Excellence in BOM 150/151 Structures and Comprehensive Control of Engineering Modifications
4. Excellence in BOM 150/151 Structures and Comprehensive Engineering Change Control
- Master the structure and format of BOM 150/151, ensuring data accuracy and integrity.
- Efficiently manage the BOM lifecycle, from creation to obsolescence, optimizing workflow.
- Implement a robust engineering change control system, including documentation, approval, and traceability.
- Analyze the impact of changes on the overall structure, identifying and mitigating potential risks.
- Utilize specialized software tools for BOM management and change control, improving efficiency.
- Ensure compliance with applicable engineering and technical data management regulations and standards.
- Apply continuous improvement methodologies to optimize BOM processes and change control.
- Collaborate effectively with multidisciplinary teams, including engineering, purchasing, production, and quality.
5. Improvement in BOM 150/151 Structures and Effective Management of Engineering Changes
- Master the fundamentals of BOM 150/151 structures, understanding their architecture and key applications.
- Analyze in depth critical structural elements, including beams, columns, and frames, and their behavior under various loads.
- Apply advanced structural analysis methods to evaluate the strength, stability, and durability of structures.
- Interpret and apply the principles of effective engineering change management in the naval context.
- Manage the change lifecycle, from initial request to implementation and verification.
- Evaluate the impact of changes on the design, fabrication, and performance of naval structures.
- Utilize change management tools and techniques to ensure efficiency and regulatory compliance.
- Understand and apply the principles of structural safety in the design and operation of naval structures.
- Identify and mitigate The risks associated with fatigue, corrosion, and other deterioration factors.
Develop decision-making skills in crisis situations and the resolution of complex problems.
Apply effective communication techniques for collaboration and information sharing in multidisciplinary teams.
Learn to integrate acquired knowledge into the design and management of naval engineering projects.
6. Specialization in BOM 150/151 Structures and Engineering Change Optimization
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.
Para quien va dirigido nuestro:
Diploma in BOM 150/151 Structures and Engineering Changes
Here is the requested information:
- Graduates in Aerospace Engineering, Mechanical Engineering, Industrial Engineering, Automation Engineering, or related fields.
- Professionals in OEM rotorcraft/eVTOL, MRO, consulting, and technology centers.
- Flight Testing, certification, avionics, control, and dynamics seeking specialization.
- Regulators/authorities and UAM/eVTOL professionals requiring compliance skills.
- 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.
1.1 BOM 150/151 Fundamentals: Structure and Purpose
1.2 Key Components of BOM 150/151: Definition and Functions
1.3 Creating and Maintaining BOM 150/151: A Step-by-Step Guide
1.4 Data Management in BOM 150/151: Integration with PLM Systems
1.5 BOM Structure Analysis: Relationships and Dependencies
1.6 Introduction to Change Management in Engineering
1.7 Change Management Process: Identification and Evaluation
1.8 Implementing Changes in BOM 150/151: Control and Monitoring
1.9 Tools and Technologies for Change Management
1.10 Case Study: Practical Application of BOM 150/151 and Change Management
2.2 BOM 250/252 Fundamentals: Structure and Key Components
2.2 Advanced BOM Modeling: Design and Configuration Techniques
2.3 Engineering Change Management: Methodologies and Best Practices
2.4 BOM Integration with PLM Systems: Data Flow and Automation
2.5 Transformation Strategies: Aligning the BOM with Business Objectives
2.6 Change Impact Analysis: Risk and Benefit Assessment
2.7 Optimizing the Change Process: Efficiency and Cost Reduction
2.8 Design for Manufacturing (DFM) and BOM: Production Considerations
2.9 KPIs and Performance Metrics: Measuring and Monitoring Success
2.20 Case Study: BOM Implementation and Continuous Improvement
3.3 Fundamentals of BOM 350/353 Structures: Key Concepts and Terminology
3.2 Engineering Change Management Review: Methodologies and Best Practices
3.3 Impact Identification and Analysis: Evaluating Changes to the BOM
3.4 BOM Configuration: Implementing Changes and Versions
3.5 Version Control: Managing Changes Over Time
3.6 Tools and Software: Applications for BOM Analysis and Management
3.7 Adapting to Change: Strategies for Flexibility and Resilience
3.8 Documentation and Communication: Ensuring Clarity and Traceability
3.9 Case Studies: Analyzing Real-World BOM Change Scenarios
3.30 Evaluation and Continuous Improvement: Performance Metrics and Optimization
4.4 Fundamentals of BOM 450/454 Structures: Types, Components, and Purpose
4.2 Configuring and Creating BOM 450/454: A Step-by-Step Guide
4.3 Engineering Change Management: A Comprehensive Process
4.4 Change Control: Implementing Effective Mechanisms
4.5 Impact of Changes: Assessment and Analysis
4.6 Documentation and Communication: Keys to Success
4.7 Integration with PLM Systems: Optimizing Workflow
4.8 Auditing and Verification: Ensuring Information Integrity
4.9 Tools and Technologies: Real-World Applications
4.40 Case Studies: Change Scenario Analysis
5.5 Introduction to the BOM 550/555 Structure and its Importance
5.5 Types of BOMs: Engineering, Manufacturing, Sales
5.3 Structure and Key Components of the BOM 550/555
5.4 BOM Workflow and its Integration with Other Systems
5.5 Engineering Change Management: Fundamentals
5.6 Documentation and Version Control in Change Management
5.7 Tools and Software for BOM and Change Management
5.8 Case Studies: Implementation of BOM 550/555 and Change Management in Naval Projects
5.9 Regulatory Framework and Relevant Regulations for BOMs and Changes in Naval Engineering
5.50 Best Practices in BOM and Change Management for Operational Efficiency
5.5 Strategies for Engineering Transformation with BOM 550/555
5.5 Aligning the BOM with the Organization’s Strategic Objectives
5.3 Risk and Opportunity Analysis in the Implementation of BOM
5.4 Designing Optimized Processes for BOM Management
5.5 Key Performance Indicators (KPIs) for Measuring BOM Success
5.6 Implementing Agile Methodologies in BOM Management
5.7 Innovation in BOM Management: New Trends and Technologies
5.8 Leadership and Change Management in Engineering Transformation
5.9 Case Studies: Strategic Transformation in Naval Projects
5.50 Knowledge Management and Training in BOM
3.5 Advanced Analysis of the BOM 550/555 Structure
3.5 Identifying and Analyzing Dependencies in the BOM
3.3 Evaluating the Impact of Changes in the BOM
3.4 Adapting to Engineering Changes: Methodology and Tools
3.5 Configuration Management and Version Control
3.6 Integrating the BOM with Enterprise Resource Planning (ERP) Systems
3.7 Root Cause Analysis of Engineering Changes
3.8 BOM Simulations and Testing
3.9 Artificial Intelligence and Predictive Analytics in Change Management
3.50 Case Study: Adapting to Change in Complex Naval Projects
4.5 Comprehensive Control of Engineering Modifications
4.5 Managing the Modification Lifecycle
4.3 Implementing a Robust Change Control System
4.4 Modification Tracking and Traceability Tools
4.5 Risk Management and Mitigation in Modifications
4.6 Communication and Collaboration in Change Management
4.7 Auditing and Reviewing Modifications
4.8 Integration with Quality Management Systems
4.9 Optimizing Modification Processes
4.50 Case Study: Implementing Comprehensive Control in Naval Projects
5.5 Refining the BOM 550/555 Structure
5.5 Advanced BOM Analysis Techniques
5.3 Effective Management of Engineering Changes
5.4 Leadership in Change Management
5.5 Effective Communication in Engineering Projects
5.6 Conflict Resolution in Change Management
5.7 Decision Making in Complex change scenarios
5.8 Time and resource management in change management
5.9 Continuous improvement in BOM and change management
5.50 Case study: Leadership in change management in naval projects
5.50
6.6 Introduction to the BOM 650/656 Structure: Fundamentals and Essential Components
6.2 Principles of Optimization in Engineering: Methodologies and Tools
6.3 Detailed Analysis of the BOM 650/656 Structure: Best Practices for Efficiency
6.4 Change Management in Engineering: Strategies for Process Optimization
6.5 Cost Optimization in the Product Life Cycle: BOM and Change Management
6.6 Automation and Digitization of the BOM 650/656 Structure
6.7 Risk Analysis and Mitigation in Engineering Change Management
6.8 Key Performance Indicators (KPIs) for BOM Optimization
6.9 Case Studies: Practical Application of BOM Optimization in the Shipbuilding Industry
6.60 Future Trends: Innovation in BOM Structures and Change Management
7.7 Introduction to BOM 770/777 Structures and Their Importance
7.2 Principles of Change Management in Engineering
7.3 Structure and Organization of BOM 770/777
7.4 The Change Management Process: Stages and Tools
7.7 Integration of BOM 770/777 and Change Management
7.6 Case Studies: Application in Different Industries
7.7 Relevant Legislation and Regulations for Change Management
7.8 Best Practices in the BOM 770/777 Domain and Change Management
7.9 Risk Analysis and Mitigation in Change Management
7.70 Tools and Technologies for Effective Management
2.7 Foundations of the BOM 770/777 Mastery
2.2 Strategic Approach to Engineering: Overview.
2.3 The Role of BOM 770/777 in Engineering Transformation.
2.4 Designing and Implementing the Transformation.
2.7 Leadership and Change Management in Engineering Projects.
2.6 Evaluating and Measuring Transformation Results.
2.7 Innovation Management in the Context of BOM 770/777.
2.8 Case Study: Transformation of an Engineering Organization.
2.9 Sustainability and Ethics in Transformation.
2.70 Future Trends in BOM 770/777 and Strategy.
3.7 Introduction to In-Depth Analysis of BOM 770/777.
3.2 BOM Structure Analysis Methodologies. 3.3 The Impact of Engineering Changes on the Bill of Materials (BOM)
3.4 Evaluating the Impact on Costs, Schedules, and Quality
3.7 Adapting to Changes: Strategies and Tools
3.6 Configuration Management and Change Control
3.7 Integration with PLM and ERP Systems
3.8 Case Studies: Change Analysis in Projects
3.9 Simulation and Analysis Tools for the BOM
3.70 Process Optimization for Adapting to Changes
4.7 Introduction to Comprehensive BOM Change Control
4.2 Regulatory Framework and Control Standards
4.3 The Change Control Process: Definition and Execution
4.4 Risk Management in BOM Changes
4.7 Documentation and Traceability of Changes
4.6 Tools for Comprehensive Change Control 4.7 Audits and Verification of Change Control.
4.8 Integrating Changes in the Supply Chain.
4.9 Case Studies in Change Control.
4.70 Continuous Improvement and Optimization of Control.
7.7 Fundamentals of Improvement in BOM 770/777.
7.2 The Role of Effective Change Management.
7.3 Leadership in Change Management.
7.4 Communication and Collaboration in the Change Process.
7.7 Strategic Planning for Change Management.
7.6 Implementing Change: Strategies and Tactics.
7.7 Measuring and Evaluating the Success of Change.
7.8 Conflict Resolution and Managing Resistance to Change.
7.9 Tools and Technologies for Change Management. 7.70 Case Studies of Effective Change Management in Projects.
8.8 Fundamental Principles of BOM 850/858 Structures
8.8 Importance of Change Management in Engineering
8.3 In-Depth Analysis of BOM 850/858 Structures
8.4 Strategies for Adapting to Engineering Changes
8.5 Implementing a Comprehensive Change Control System
8.6 Optimizing Engineering Changes for Efficiency
8.7 Effective Management of Engineering Changes
8.8 Advanced Mastery of Engineering Change Dynamics
8.8 Tools and Technologies for Change Management
8.80 Practical Cases and Case Studies on BOM 850/858
8.9
9.9 Introduction to BOM 950/959 Structures and Their Importance
9.9 Fundamentals of Change Management in Engineering
9.3 Creating and Maintaining Efficient BOMs
9.4 Implementing Change Processes
9.5 Tools and Technologies for Change Management
9.6 Case Studies and Real-World Examples
9.9 Strategic Vision of BOM 950/959 Structures
9.9 Aligning BOMs with Business Strategy
9.3 Digital Transformation and Its Impact on Engineering
9.4 Agile Methodologies in BOM Management
9.5 Integrating BOMs with PLM Systems
9.6 Case Studies: Successful Implementation
3.9 In-Depth Analysis of BOM 950/959 Structures
3.9 Identifying and Evaluating the Impacts of Changes
3.3 Adapting BOMs to Different Change Scenarios
3.4 Advanced Data Analysis Techniques in BOMs
3.5 Developing Contingency Plans for Changes
3.6 Practical Exercises in Analysis and Adaptation
4.9 Comprehensive Control of Modifications in BOM 950/959 Structures
4.9 Version and Configuration Management
4.3 BOM Audits and Verification
4.4 Risk Management in the Change Process
4.5 Implementing Change Control Systems
4.6 Case Studies: Modification Control
5.9 Refining BOM 950/959 Structures
5.9 Effective Management of Engineering Changes
5.3 Leadership and Communication in Change Management
5.4 Conflict Resolution and Decision Making
5.5 Continuous Improvement in BOM and Change Processes
5.6 Change Scenario Simulation
6.9 Optimizing BOM Structures 950/959
6.9 Application of Lean Methodologies in BOM Management
6.3 Efficiency Improvement and Cost Reduction
6.4 Automation of Change Processes
6.5 Key Performance Indicators (KPIs) in BOM
6.6 Designing an Optimization Strategy
7.9 Excellence in BOM 950/959 Structures
7.9 Change Engineering: A Holistic Approach
7.3 Integrating Change Engineering into the Product Lifecycle
7.4 Knowledge Management in Change Engineering
7.5 Innovation in BOM and Change Management
7.6 Developing an Excellence Plan
8.9 Dynamics of Changes in BOM 950/959 Structures
8.9 Future Trends in BOM and Change Management
8.3 Artificial Intelligence and its Impact on BOM
8.4 Management 8.5 Resilience and Adaptability in Change Engineering
8.6 Conclusions and Future Perspectives
8.5 Complexity in BOM
8.6 Resilience and Adaptability in Change Engineering
8.7 Conclusions and Future Perspectives
8.1 BOM 150/151 Fundamentals: Structure and Nomenclature
8.2 Change Management: Principles and Best Practices
8.3 Change Implementation: Step-by-Step Process
8.4 Change Integration: Systems and Tools
8.5 Impact Analysis: Effect Assessment
8.6 Change Validation and Verification
8.7 Change Documentation: Records and Control
8.8 Change Communication: Stakeholders and Flows
8.9 Risks and Mitigation: Identification and Response
8.10 Final Project: Practical Application
8.10
- 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.
Proyectos tipo capstones
Admisiones, tasas y becas
- 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.
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