Desarrollo y evaluación de competencias genéricas en los títulos de grado.

Los nuevos títulos de grado en la Universidad española generados a raíz del proceso de Bolonia,inciden en una nueva dimensión: las competencias genéricas que deben adquirir los estudiantes universitarios. Pero ¿cómo armonizar el desarrollo y evaluación de dichas competencias con la actual actividad docente? En este trabajo se expone un modelo que permite la citada armonización con un mínimo de “ruido” y de esfuerzo complementario por parte de los docentes. En el modelo propuesto primero se hace una selección y una ordenación de las competencias que se quieren incorporar en un plan de estudios. Se hace una proyección de las competencias en los cuatrimestres y asignaturas del plan de estudios. La introducción de las competencias en las asignaturas asignadas se hace a través del diseño de actividades de formación, desarrollo y evaluación de la competencia. La segunda componente del modelo propuesto tiene por objeto coordinar las acciones que implementen la transversalidad de las competencias bajo desarrollo tanto en espacio como en tiempo. Por último, existen un conjunto de actividades destinadas a realizar el control de calidad del proceso propuesto. Este modelo se está implementado en las dos titulaciones de grado impartidas por la Escuela Universitaria de Informática de la Universidad Politécnica de Madrid durante el curso 2012/13. La coordinación se ha mostrado especialmente difícil dado la falta de experie ncia y el desconocimiento en este campo y las reticencias de algunos docentes a implicarse en este proceso. El modelo demuestra varias bondades: flexibilidad, aplicabilidad, extensibilidad, universalidad,globalidad y economía. ABSTRACT: The new degrees in Spanish University, generated as a result of the Bologna process, affect a new dimension: the generic competences to be acquired by university students. But, how can we harmonize the development and evaluation of these competencies with current teaching? This paper presents a model that allows the aforementioned harmonization with minimal "noise" and additional effort on the part of teachers. The proposed model first makes a selection and organization of competences that are to be incorporated into a curriculum. The following is a projection of competences in the semesters and curriculum subjects. The introduction of competences in the subjects assigned is carried out by designing activities of training, development and assessment. The second component of the proposed model is focused on coordinating actions to implement the transverse character of competences in both space and time. Finally, there are a set of activities to perform quality control of the proposed process. This model is being implemented in two degree taught by the School of Computer Science at the Universidad Politécnica de Madrid during the year 2012/13. Coordination has been particularly difficult given the lack of experience and lack of knowledge in this field and the reluctance of teachers to engage in this process.

Physics and Mathematics in the Engineering Curriculum: Correlation with Applied Subjects

This paper presents a study in which the relationship between basic subjects (Mathematics and Physics) and applied engineering subjects (related to Machinery, Electrical Engineering, Topography and Buildings) in higher engineering education curricula is evaluated. The analysis has been conducted using the academic records of 206 students for five years. Furthermore, 34 surveys and personal interviews were conducted to analyze the connections between the contents taught in each subject and to identify student perceptions of the correlation with other subjects or disciplines. At the same time, the content of the different subjects have been analyzed to verify the relationship among the disciplines.Aproper coordination among subjects will allow students to relate and interconnect topics of different subjects, even with the ones learnt in previous courses, while also helping to reduce dropout rates and student failures in successfully accomplishing the different courses.

Simulation of academic performance rates, estimation of indicators of subjects and of a complete degree

The purpose of this paper is to present a program written in Matlab-Octave for the simulation of the time evolution of student curricula, i.e, how students pass their subjects along time until graduation. The program computes, from the simulations, the academic performance rates for the subjects of the study plan for each semester as well as the overall rates, which are a) the efficiency rate defined as the ratio of the number of students passing the exam to the number of students who registered for it and b) the success rate, defined as the ratio of the number of students passing the exam to the number of students who not only registered for it but also actually took it. Additionally, we compute the rates for the bachelor academic degree which are established for Spain by the National Quality Evaluation and Accreditation Agency (ANECA) and which are the graduation rate (measured as the percentage of students who finish as scheduled in the plan or taking an extra year) and the efficiency rate (measured as the percentage of credits which a student who graduated has really taken). The simulation is done in terms of the probabilities of passing all the subjects in their study plan. The application of the simulator to Polytech students in Madrid, where requirements for passing are specially stiff in first and second year subjects, is particularly relevant to analyze student cohorts and the probabilities of students finishing in the minimum of four years, or taking and extra year or two extra years, and so forth. It is a very useful tool when designing new study plans. The calculation of the probability distribution of the random variable "number of semesters a student has taken to complete the curricula and graduate" is difficult or even unfeasible to obtain analytically, and this is even truer when we incorporate uncertainty in parameter estimation. This is why we apply Monte Carlo simulation which not only provides illustration of the stochastic process but also a method for computation. The stochastic simulator is proving to be a useful tool for identification of the subjects most critical in the distribution of the number of semesters for curriculum vitae (CV) completion and subsequently for a decision making process in terms of CV planning and passing standards in the University. Simulations are performed through a graphical interface where also the results are presented in appropriate figures. The Project has been funded by the Call for Innovation in Education Projects of Universidad Politécnica de Madrid (UPM) through a Project of its school Escuela Técnica Superior de Ingenieros Industriales ETSII during the period September 2010-September 2011.