Competencies and objectives

 

Course context for academic year 2025-26

La asignatura de Ampliación de Métodos Matemáticos para la Ingeniería Aeroespacial es una asignatura obligatoria de seis créditos ECTS que se imparte en el primer semestre del segundo curso del Grado en Ingeniería Aeroespacial.

Junto con las asignaturas Fundamentos Matemáticos de la Ingeniería 1, Fundamentos Matemáticos de la Ingeniería 2 y Métodos Matemáticos de la Ingeniería Aeroespacial conforma los contenidos matemáticos impartidos en el grado.

La parte fundamental de los contenidos de la asignatura quedan incluidos en la disciplina de las ecuaciones diferenciales. Las ecuaciones diferenciales aparecen en el contexto de la ingeniería aeroespacial, lo que confiere a la asignatura de Ampliación de Métodos Matemáticos un papel clave en la formación de futuros ingenieros aeroespaciales.

Para el desarrollo normal de la asignatura se recomienda haber cursado con aprovechamiento las asignaturas de Fundamentos Matemáticos de la Ingeniería 1 y 2, y Métodos Matemáticos de la Ingeniería Aeroespacial.

 

 

Learning outcomes / Course competencies (verified by ANECA in official undergraduate and Master’s degrees) for academic year 2025-26

Transversal Competences

  • CT02 : Utilizar de forma habitual las herramientas informáticas, así como las tecnologías de la información y las comunicaciones, en todo su desempeño profesional.

 

General Competences

  • CG01 : Capacity for the design, development and management in the field of aeronautical engineering, in accordance with the knowledge acquired as established in section 5 of the order CIN/308/2009, of 9 February, aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructures, air navigation infrastructures and any space, traffic and air transport management system.
  • CG02 : Planning, drafting, direction and management of projects, calculations and manufacturing in the field of aeronautical engineering, in accordance with the knowledge acquired in accordance with section 5 of order CIN/308/2009, of 9 February, aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructures, air navigation infrastructures and any space, traffic and air transport management system.
  • CG03 : Installation, operation and maintenance in the field of aeronautical engineering, in accordance with the knowledge acquired as established in section 5 of the order CIN/308/2009, of 9 February, of aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructures, air navigation infrastructures and any space, traffic and air transport management system.
  • CG04 : Verification and Certification in the field of aeronautical engineering, in accordance with the knowledge acquired as established in section 5 of order CIN/308/2009, of 9 February, on aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructures, aeronautical infrastructures and any space, traffic and air transport management system.
  • CG05 : Ability to carry out activities of design, technical management, expertise, drafting of reports, opinions, and technical advice in tasks related to Aeronautical Technical Engineering, exercise of genuinely aerospace technical functions and positions.
  • CG06 : Ability to participate in flight test programmes to collect data on take-off distances, climb rates, stall speeds, manoeuvrability and landing capabilities.
  • CG07 : Capacity to analyse and assess the social and environmental impact of technical solutions.

 

Specific Competences

  • CE01 : Ability to solve mathematical problems that may arise in engineering and aptitude to apply knowledge of: linear algebra; geometry; differential geometry; differential and integral calculus; differential equations and partial derivatives; numerical methods; numerical algorithms; statistics and optimisation.

 

Basic Competences

  • CB1 : That students have demonstrated possession and understanding of knowledge in an area of study that builds on the foundation of general secondary education, and is usually at a level that, while relying on advanced textbooks, also includes some aspects that involve knowledge from the cutting edge of their field of study.
  • CB5 : That students have developed those learning skills necessary to undertake further studies with a high degree of autonomy.

 

 

 

Learning outcomes (Training objectives)

  • Use the language of Mathematics applied to the resolution of mathematical problems in Aerospace Engineering.
  • Apply the fundamental elements of line and surface integrals and the integral theorems of Vector Calculus.
  • Use different methods to determine the properties of numerical, power and Fourier series and their associated developments.
  • Calculate the solutions of linear differential equations and systems of analytical and numerical differential equations by means of the most widespread methods of resolution.
  • Illustrate the application of some basic methods in the analytical and numerical solution of partial differential equations.

 

 

Specific objectives stated by the academic staff for academic year 2025-26

No data

 

 

General

Code: 33810
Lecturer responsible:
Martínez Belda, María del Carmen
Credits ECTS: 6,00
Theoretical credits: 0,00
Practical credits: 2,40
Distance-base hours: 3,60

Departments involved

  • Dept: Applied Mathematics and Aerospace Engineering
    Area: Applied Mathematics
    Theoretical credits: 0
    Practical credits: 2,4
    This Dept. is responsible for the course.
    This Dept. is responsible for the final mark record.

Study programmes where this course is taught