Diploma in Aerodynamic Morphologies and Brand Signature
Sobre nuestro Diploma in Aerodynamic Morphologies and Brand Signature
The Diploma in Aerodynamic Morphologies and Branding explores the design and optimization of shapes in the field of aeronautics, using advanced computational simulation (CFD) and computer-aided design (CAD) tools to improve the aerodynamic performance and efficiency of aircraft. It focuses on the creation of airfoils, fairings, and other surfaces, considering aspects such as drag, lift, and stability. It includes the application of topological optimization techniques and airflow analysis to achieve innovative and efficient designs. The diploma program also addresses the importance of brand identity in design, studying how visual elements and aesthetics contribute to brand identity and differentiation in the aeronautical market. Students learn to integrate functionality and aesthetics, considering design trends and corporate image. This training prepares students for roles such as aerodynamic designers, surface design engineers, and aeronautical aesthetics specialists, providing skills for developing aircraft with high performance and a strong visual identity.
Target keywords (naturally occurring in the text): aerodynamic design, CFD simulation, CAD design, airfoils, topology optimization, branding, aeronautical aesthetics, visual identity, aeronautical diploma.
Diploma in Aerodynamic Morphologies and Brand Signature
- 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
995 $
Competencias y resultados
Qué aprenderás
1. Aerodynamic Analysis and Brand Signature Design
Here is the requested content, respecting the provided specifications:
**What will you learn? Aerodynamic Analysis and Brand Signature Design**
- Understand and apply advanced aerodynamic principles.
- Evaluate and optimize aircraft shape and structure to reduce aerodynamic drag.
- Design and analyze the brand signature, including its impact on image and positioning.
2. Advanced Rotor Modeling and Performance Optimization
- Master the analysis of rotor dynamics, including complex couplings such as flap-lag-torsion, crucial for stability and performance.
- Evaluate and mitigate the risk of phenomena such as whirl flutter, ensuring structural integrity and operational safety.
- Understand and apply fatigue analysis techniques, essential for the service life and durable design of components.
- Design and dimension rotor structures using advanced composite materials, optimizing the strength-to-weight ratio.
- Apply finite element (FE) methods for the design of composite laminates, joints, and bonded joints, achieving accurate modeling.
- Implement damage mitigation strategies tolerance, allowing for the detection and assessment of damage, thus extending the lifespan of components.
Use Non-Destructive Testing (NDT) techniques, including UT (ultrasound), RT (radiography), and thermography, for inspection and quality control.
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. Aerodynamic Design and Analysis of Rotors and Brand Signature Evaluation
- Master the principles of aerodynamic rotor design, including understanding lift, drag, and airflow.
- Delve into the analysis of rotor aerodynamics, with particular attention to the factors that influence performance and efficiency.
- Evaluate brand signature, understanding how rotor designs contribute to brand identity and positioning.
- Understand key aspects of rotor design, such as material selection, blade shape, and rotor configuration.
- Analyze the aerodynamic forces acting on rotors, including thrust, torque, and bending forces.
- Apply aerodynamic simulation software to predict rotor performance and optimize design.
- Evaluate the impact of environmental conditions, such as wind speed and temperature, on rotor performance.
- Investigate
- Understand noise and vibration reduction techniques in rotors, improving efficiency and comfort.
- Identify and analyze rotor failure modes, such as fatigue, corrosion, and erosion.
- Apply design methodologies for rotor durability and service life, including the selection of resistant materials and wear protection.
- Develop strategies for evaluating and analyzing brand signature in rotor designs, considering aspects such as aesthetics, functionality, and innovation.
5. Aerodynamic Design of Rotors and Evaluation of Identification Signature
5. Aerodynamic Design of Rotors and Identification Signature Evaluation
- Master the analysis of flap-lag-torsion couplings, essential for rotor stability and control.
- Understand and evaluate whirl flutter phenomena, crucial for structural and operational safety.
- Study fatigue, a determining factor in the service life and reliability of rotating components.
- Learn to dimension laminated structures in composites, optimizing strength and weight.
- Design and analyze joints and bonded joints using the finite element (FE) method.
- Implement damage tolerance strategies to ensure structural integrity.
- Apply non-destructive testing techniques (NDT), including UT/RT/thermography, for flaw detection.
6. Rotor Simulation: Modeling, Performance, and Signature Analysis
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 Aerodynamic Morphologies and Brand Signature
- Graduates in Aerospace Engineering, Mechanical Engineering, Industrial Engineering, Automation Engineering, or related fields.
- Professionals from OEM rotorcraft/eVTOL, MRO, consulting, and technology centers.
- Flight test engineers, specialists in aeronautical certification, avionics, flight control, and flight dynamics seeking advanced specialization.
- Aeronautical regulators/authorities and professionals involved in the development and operation of UAM/eVTOL who need to acquire specific competencies in compliance and current regulations.
- 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.
2.1 Aerodynamic Fundamentals: Review of key concepts.
2.2 Rotor Theory: Finite Element Modeling (FEM) and CFD simulation.
2.3 Aerodynamic Design: Airfoil selection and rotor configuration.
2.4 Performance Optimization: Analysis of aerodynamic efficiency.
2.5 Introduction to Signatures: Principles of brand signatures.
2.6 Signature Reduction Methods: Techniques for minimizing detection.
2.7 Signature Modeling: Modeling tools and techniques.
2.8 Signature Design: Design strategies and considerations.
2.9 Case Studies: Practical examples of signature design.
2.10 Evaluation: Analysis and validation of designs.
2.2 Fundamentals of rotational aerodynamics: rotor element theory, impulse moment theory.
2.2 Rotor blade modeling: geometry, airfoils, chord distribution.
2.3 Rotor modeling methods: rotor element theory, vortex theory, CFD.
2.4 Rotor performance simulation: thrust, power, efficiency, stall analysis.
2.5 Rotor performance optimization: blade design, airfoil selection, pitch control.
2.6 Sensitivity analysis and optimization: optimization techniques, experimental design.
2.7 Low-signature rotor design: noise reduction, radar reduction.
2.8 Rotor materials and manufacturing: material selection, manufacturing processes.
2.9 Validation and verification: wind tunnel testing, flight testing.
2.20 Case study: application of learned techniques to a specific rotor design.
3.3 eVTOL and UAM: Electric Propulsion, Multiple Rotors
3.2 Emerging Certification Requirements (SC-VTOL, Special Conditions)
3.3 Energy and Thermal in E-Propulsion (Batteries/Inverters)
3.4 Design for Maintainability and Modular Swaps
3.5 LCA/LCC in Rotorcraft and eVTOL (Footprint and Cost)
3.6 Operations & Vertiports: Airspace Integration
3.7 Data & Digital Thread: MBSE/PLM for Change Control
3.8 Tech Risk and Readiness: TRL/CRL/SRL
3.9 IP, Certifications, and Time-to-Market
3.30 Case Clinic: Go/No-Go with Risk Matrix
4.4 Fundamental Concepts of Rotor Aerodynamics and Blade Design
4.2 Rotor Modeling and Numerical Simulation (CFD and BEM)
4.3 Rotor Performance and Efficiency Analysis
4.4 Aerodynamic Design of Rotors Optimized for Low Noise and Vibration
4.5 Signature Reduction Techniques
4.6 Methodology for Evaluating the Signature
4.7 Sensitivity Analysis and Design Optimization
4.8 Practical Applications and Case Studies
4.9 Integrating Aerodynamics and Signature into Design
4.40 Design for Rotor Manufacturing and Testing
5.5 Fundamental Concepts of Rotational Aerodynamics
5.5 Blade Element and Momentum Theory
5.3 Introduction to Rotor Regulation and Control
5.4 Flow Structure in Rotors
5.5 Wakeflow Effects and Their Impact on Performance
5.6 Helicopter Stability and Control
5.7 Basic Principles of Rotor Design
5.8 Introduction to Performance and Efficiency Metrics
5.5 Finite Sheet Modeling and Vorticity Methods
5.5 Boundary Element Methods for Rotor Analysis
5.3 Introduction to Rotor Design Optimization
5.4 Blade Geometry Optimization
5.5 ​​Rotor Control Techniques for Performance Optimization
5.6 Sensitivity and Robustness Analysis in Rotor Design
5.7 Transient Flow Modeling and Instability Effects
5.8 Rotor-Wake Interaction Modeling
3.5 Computational Fluid Dynamics (CFD) Simulation for Rotors
3.5 Element Simulation Methods Finite Element Analysis (FEA) in Rotors
3.3 Rotor Control System Simulation
3.4 Rotor System Configuration Optimization
3.5 Rotor System Performance Simulation
3.6 System Stability and Control Analysis
3.7 Propulsion System Design and Performance Evaluation
3.8 Noise and Vibration Simulation in Rotating Systems
4.5 Aerodynamic Design of Rotor Airfoils
4.5 Rotor Plant Selection and Design
4.3 Blade Geometry Design
4.4 Aerodynamic Performance Analysis
4.5 Flight Characteristic Evaluation
4.6 Stability and Control Analysis
4.7 Signature Reduction Techniques
4.8 Rotor Design and Analysis under Specific Flight Conditions
5.5 Rotor Blade Design for Performance Optimization
5.5 ​​Rotor Signature Modeling
5.3 Rotor Signature Reduction Techniques
5.4 Rotor Signature Evaluation
5.5 ​​Noise and Vibration Analysis
5.6 Design Optimization to Minimize Detection
5.7 Design and Analysis Under Different Flight Conditions
5.8 Design for Manufacturing and Maintenance
6.5 Rotor Modeling Using Different Numerical Methods
6.5 Rotor Performance Simulation Under Various Conditions
6.3 Rotor Signature Analysis
6.4 Techniques for Reducing the Rotor Signature
6.5 Rotor Noise Simulation
6.6 Rotor Vibration Simulation
6.7 Rotor Performance Analysis Under Different Operating Scenarios
6.8 Integrating Simulation into the Design Process
7.5 Aerodynamic Design of Rotors
7.5 Rotor Modeling and Simulation
7.3 Rotor Performance Analysis
7.4 Rotor Signature Analysis
7.5 Rotor Design Optimization Techniques
7.6 Rotor Noise and Vibration Simulation
7.7 Integrating Design, Simulation, and Analysis
7.8 Applications in the Aerospace Industry
8.5 Aerodynamic Analysis of Rotors
8.5 Rotor Modeling
8.3 Characterization of the distinctive signature
8.4 Signature reduction techniques
8.5 Noise and vibration analysis
8.6 Rotor design optimization
8.7 Integration of analysis into design
8.8 Applications in the aviation industry
6.6 Introduction to Rotor Modeling and Aerodynamic Principles
6.2 Numerical Simulation: CFD and BEM Methods Applied to Rotors
6.3 Performance Modeling: Lift, Drag, and Power Analysis
6.4 Signature Analysis: Acoustic, Radar, and Infrared
6.5 Rotor Design and Optimization for Signature Reduction
6.6 Simulation Tools: Software and Methodologies
6.7 Case Studies: Application of Simulation in Different Configurations
6.8 Validation and Verification of Simulation Results
6.9 Impact of Flight Conditions on the Rotor Signature
6.60 Strategies for Signature Mitigation in Rotor Design
7.7 Fundamentals of Rotational Aerodynamics: Key Principles and Concepts
7.2 Introduction to the Navier-Stokes Equations Applied to Rotors
7.3 Blade Element Theory and Flow Modeling
7.4 Control and Stability of Rotary Aircraft
7.7 Rotor Design: Parameters and Initial Considerations
7.6 Introduction to Air Regulations and Standards
7.7 Safety Principles in Aircraft Design
7.8 Rotor Design Examples and Applications
7.9 Case Studies: Rotor Design Examples
7.70 Rotor Performance Evaluation
2.7 Advanced Rotor Modeling Methods: CFD and BEM
2.2 Rotor Design Optimization: Algorithms and Strategies
2.3 Rotor-Wake Interaction Modeling
2.4 Rotor Dynamics and Vibration Analysis
2.7 Airfoil Design and Optimization
2.6 Finite Element Analysis (FEA) Methods
2.7 Complex Flow Simulation Turbulence
2.8 Rotor Performance Analysis and Optimization
2.9 Optimization Metrics and Objective Functions
2.70 Case Studies: Examples of Rotor Optimization
3.7 Introduction to Rotating Systems Simulation
3.2 Modeling Propulsion and Control Systems
3.3 Simulation of Rotating Components and Subsystems
3.4 Analysis of Rotor-Flower Airframe Interaction
3.7 Rotating Systems Optimization Techniques
3.6 Simulation of Flight Scenarios and Maneuvers
3.7 Performance and Energy Efficiency Analysis
3.8 Design and Simulation of Flight Control Systems
3.9 Case Studies: System Simulation and Optimization
3.70 System Risk and Reliability Assessment
4.7 Aerodynamic Design of Rotors: Methods and Tools
4.2 Analysis of Airflow Around Blades
4.3 Blade Design: Profile and Geometry Selection
4.4 Acoustic Signature Design: Noise Reduction
4.7 Radar and Visual Signature Analysis
4.6 Evaluation of Rotor stability and control
4.7 Performance analysis under different conditions
4.8 Rotor design and analysis in the naval context
4.9 Case studies: Rotor design and analysis
4.70 Implementation of advanced technologies
7.7 Rotor and component modeling
7.2 Rotor design for signature reduction
7.3 Acoustic signature evaluation techniques
7.4 Radar and visual signature analysis
7.7 Design of rotors with low detectability
7.6 Integration of stealth materials and technologies
7.7 Rotor performance evaluation under stealth
7.8 Case studies: Design for reduced signature
7.9 Impact of operating conditions on the signature
7.70 Strategies for signature optimization
6.7 Rotor performance modeling and simulation
6.2 Acoustic signature simulation
6.3 Radar signature modeling
6.4 Visual signature analysis
6.7 Flight scenario simulation
6.6 Rotor design for signature reduction Signature
6.7 Signature Evaluation Under Different Conditions
6.8 Comparison of Simulation Techniques
6.9 Case Studies: Performance and Signature Analysis
6.70 Simulation-Based Design Optimization
7.7 Aerodynamic Design and Rotor Modeling
7.2 Rotor Performance Simulation
7.3 Acoustic Signature Analysis
7.4 Radar Signature Simulation
7.7 Visual Signature Evaluation
7.6 Design of Rotors with Low Detectability
7.7 Integration of Different Simulations
7.8 Case Studies: Design, Simulation, and Analysis
7.9 Analysis of the Impact of Flight Conditions
7.70 Design Optimization Strategies
8.7 Advanced Aerodynamic Analysis of Rotors
8.2 Modeling of Rotors and Their Components
8.3 Acoustic Signature Characterization
8.4 Radar Signature Analysis
8.7 Visual Signature Evaluation
8.6 Integration of Multiple Signature Analyses
8.7 Case Studies: Signature Characterization
8.8 Impact of Environmental Conditions on The signature
8.9 Design strategies to minimize the signature
8.70 Advanced analysis and modeling techniques
8.70
8.8 Fundamentals of Aerodynamic Rotor Analysis
8.8 Moment Blade Theory and Blade Elements
8.3 Rotor Wake Modeling and Impact
8.4 CFD Methods for Rotor Analysis
8.5 Rotor Design: Airfoil Selection
8.6 Radar and Acoustic Signature Evaluation
8.7 Signature Reduction Techniques
8.8 Simulation Software and Analysis Tools
8.8 Conceptual Design and Optimization of Rotors
8.80 Applications on Naval Platforms
8.9
9.9 Principles of Aerodynamics Applied to Rotors
9.9 Blade Element and Flow Theory
9.3 Blade Section Design and Airfoil Selection
9.4 Computational Flow Analysis (CFD) Techniques
9.5 Brand Signature Fundamentals and Signature Reduction
9.6 Design for Low Observability: Radar, Acoustics, and Infrared
9.7 Brand Signature Simulation Techniques
9.9 Mathematical Modeling of Rotors
9.9 Blade Element Methods (BEM) and Blade Moment Theory
9.3 Parametric Design and Rotor Optimization
9.4 Sensitivity Analysis and Experimental Design
9.5 Optimization Methods: Genetic Algorithms and Gradient-Based Methods
9.6 Performance Optimization: Thrust, Power, and Efficiency
9.7 Rotor Stability and Control Analysis
3.9 Systems Modeling Aerospace Rotors
3.9 Multibody Dynamic Simulation
3.3 Control Systems Integration
3.4 Systems Optimization Methods
3.5 Realistic Flight Scenario Simulation
3.6 Transient Response and Stability Analysis
3.7 Model Validation and Verification
4.9 Aerodynamic Design of Rotors
4.9 Computational Flow Analysis (CFD) for Rotors
4.3 Signature Evaluation Techniques
4.4 Radar and Acoustic Simulation
4.5 Signature Reduction and Stealth Design
4.6 Comparative Design and Signature Analysis
4.7 Case Studies: Military and Civil Applications
5.9 Principles of Aerodynamic Design of Rotors
5.9 Selection and Design of Airfoils
5.3 Evaluation of the Identifying Signature: Radar, Acoustics, and Infrared
5.4 Modeling Techniques Signature
5.5 Design for Signature Reduction
5.6 Trade-off Analysis between Performance and Signature
5.7 Systems Integration and Conceptual Design
6.9 Rotor Modeling for Simulation
6.9 Flow Simulation Methods
6.3 Performance Analysis: Thrust, Power, Efficiency
6.4 Signature Simulation: Radar, Acoustics, and Infrared
6.5 Signature Sensitivity Analysis to Design Parameters
6.6 Validation of Simulation Models
6.7 Case Studies: Specific Applications
7.9 Detailed Aerodynamic Design of Rotors
7.9 Rotor Modeling for Simulation
7.3 Computational Flow Simulation (CFD)
7.4 Performance Analysis and Signature Evaluation
7.5 Signature Reduction Strategies
7.6 Design Iteration and Optimization
7.7 Presentation of Results and Conclusions
8.9 Analysis Rotor Aerodynamics
8.9 Flow Modeling and Simulation
8.3 Distinctive Signature Characterization: Radar, Acoustics, and Infrared
8.4 Signature Reduction Techniques
8.5 Data Analysis and Simulation Results
8.6 Comparative Study of Different Designs
8.7 Final Report and Conclusions
1. Aerodynamic Analysis and Brand Signature Design: Fundamentals of rotational aerodynamics.
2. Advanced Rotor Modeling and Performance Optimization: Rotor component design and performance.
3. Simulation and Optimization of Aerospace Rotating Systems: Computational flow and rotor simulation.
4. Aerodynamic Rotor Design and Analysis and Brand Signature Evaluation: Aerodynamic signature analysis.
5. Aerodynamic Rotor Design and Signature Evaluation: Rotor design for noise reduction.
6. Rotor Simulation: Modeling, Performance, and Signature Analysis: Rotor design optimization.
7. Aerodynamic Rotor Design: Modeling, Simulation, and Signature Analysis: Systems integration and design considerations.
8. Aerodynamic Rotor Analysis, Modeling, and Signature Characterization: Case study and final project presentation.
- 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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