Las Infraestructuras de Datos Espaciales (IDE) como un recurso educativo TIC . Estrategias de formación y difusión para el profesorado de la Educación Secundaria Obligatoria

Desde mediados de los 90, gracias a las posibilidades de la World Wide Web, se liberó la cartografía de su dependencia del medio físico, posibilitando el acceso y visualización de millones de mapas almacenados en formatos gráficos a través de Internet. En este contexto, el papel de la Información Geográfica (IG) en la vida cotidiana adquirió relevancia en la medida que el acceso a la misma resultaba cada vez más fácil gracias a múltiples herramientas y aplicaciones para distribuir y acercar los mapas en distintos formatos a la sociedad en general. Sin embargo, dado que esa información enseguida pasaba a estar desactualizada, surgió una demanda desde distintos ámbitos (seguridad, medio ambiente transporte, servicios, etc.) y de la sociedad en general para disponer de la información más actual. Como respuesta a esta demanda, surgen las iniciativas denominadas Infraestructuras de Datos Espaciales (IDE). Estas iniciativas, mediante la acción coordinada de un conjunto de tecnologías, estándares, normas y políticas, brindan la posibilidad a los usuarios de acceder, a través de Internet, a IG actualizada producida por instituciones y organismos oficiales, en un marco colaborativo y sustentada en una estructura organizativa. En este contexto, el ámbito educativo no ha permanecido ajeno representando uno de los espacios más propicios para la difusión de las potencialidades y usos de las IDE. En esta tesis se propone la utilización de las IDE en el contexto educativo, específicamente en la Educación Secundaria Obligatoria (ESO). Utilizar las IDE en el contexto educativo implica asignarle un papel en el proceso de enseñanza-aprendizaje y en el marco de esta tesis se presentan los fundamentos teóricos que permiten afirmar que las IDE son un re-curso educativo que responde a las características de las Tecnologías de la Información y la Comunicación (TIC). Esto se explicita a través de un concepto más amplio que hemos denominado “recurso educativo TIC”. En este contexto se analizan las posibilidades que ofrece las IDE para alcanzar los objetivos de aprendizaje de asignaturas de la ESO relacionadas con IG y se identifican contenidos susceptibles de ser abordados utilizándolas. Por otra parte, atendiendo al modelo educativo del aprendizaje basado en competencias, se exponen las posibilidades y potencialidades que ofrecen las IDE para desarrollar la competencia digital. Una vez planteado el marco teórico se desarrollaron dos estrategias de formación y difusión de las IDE orientadas al profesorado de la ESO. En primer lugar, utilizando el Modelo de Diseño Instruccional ADDIE, se diseñaron, desarrollaron, implementaron y evaluaron tres cursos e-learning para el profesorado de ESO de las asignaturas Ciencias Sociales, Ciencias de la Naturaleza y Tecnología. En segundo lugar, con objetivo de complementar los resultados obtenidos de los cursos e-learning, se realizó una actividad en dos Institutos de Educación Secundaria orientada a difundir las IDE. La puesta en práctica de estas estrategias ofreció al profesorado la información necesaria sobre qué son las IDE y proporcionó ejemplos concretos de uso de las mismas en su asignatura, permitiéndoles disponer de los conocimientos e información para emitir una valoración sobre las posibilidades que ofrecen las IDE como un recurso educativo TIC. Since about the middle of the 1990 decade, owing to the potential of the World Wide Web, cartography freed itself from its dependence on its physical support, enabling the access and visualisation of millions of maps stored in graphical formats through the Internet. In this context, the role of Geographic Information (GI) in daily life became relevant in as much as its access turned out to be ever easier due to multiple tools and applications to distribute and bring maps in different formats closer to society in general. Yet, since the information available often became outdated, a demand for updated information arose from different specific fields (security, environment, transport, services, etc.) and from the general public. As a response to this demand, the so-called Spatial Data Infrastructure (SDI) initiatives arose which, through the coordinated action of a set of technologies, stan-dards, and policies, enabled users to access updated GI created by organisations and official institutions, through the Internet, within a cooperative framework and an organisational structure. In this context the educational world has not remained aloof, since it represented one of the most propitious scope for the dissemination of the potentials and uses of SDI. In this thesis the utilization of SDI in the educational context is proposed, specifically in the Spanish Compulsory Secondary Education (Educación Secundaria Obligatoria – ESO). This utilization implies assigning SDI a role in the teaching-learning process; here the theo-retical foundation is presented which allows asserting that SDI is an educational resource fitting in with the characteristics of the Information and Communication Technologies (ICT). This is made explicit by means of a broader concept we have called “ICT educa-tional resource”. The possibilities offered by SDI to reach the objective of learning ESO subjects related to GI are analyzed, and contents apt to be addressed by using them are identified. On the other hand, attending to the educational model of learning based on competences, the possibilities and potentials the SDI offer to develop the digital compe-tence are exposed. After having set forth the theoretical frame, two strategies of training and dissemination of SDI were developed, oriented to the ESO teaching staff. First, using the ADDIE Instruc-tional Design Model, three learning courses were designed, developed, implemented and evaluated for the ESO teaching staff in the subjects of Social Sciences, Natural Sciences and Technology. In the second place, with the purpose of supplementing the results ob-tained from the e-learning courses, an activity was carried out in two High Schools, ori-ented to disseminate the SDI. The implementation of these strategies offered the teaching staff the needed information concerning the SDI and provided specific instances of utilisa-tion thereof in their subject, thus enabling them to acquire the knowledge and information to issue an assessment of the possibilities the SDI offer as an ICT educational resource

Lacunarity of the Spatial Distributions of Soil Types in Europe.

Lacunarity as a means of quantifying textural properties of spatial distributions suggests a classification into three main classes of the most abundant soils that cover 92% of Europe. Soils with a well-defined self-similar structure of the linear class are related to widespread spatial patterns that are nondominant but ubiquitous at continental scale. Fractal techniques have been increasingly and successfully applied to identify and describe spatial patterns in natural sciences. However, objects with the same fractal dimension can show very different optical properties because of their spatial arrangement. This work focuses primary attention on the geometrical structure of the geographical patterns of soils in Europe. We made use of the European Soil Database to estimate lacunarity indexes of the most abundant soils that cover 92% of the surface of Europe and investigated textural properties of their spatial distribution. We observed three main classes corresponding to three different patterns that displayed the graphs of lacunarity functions, that is, linear, convex, and mixed. They correspond respectively to homogeneous or self-similar, heterogeneous or clustered and those in which behavior can change at different ranges of scales. Finally, we discuss the pedological implications of that classification.

Outreach Testing of Ancient Astronomy

This work is an outreach approach to an ubiquitous recent problem in secondary-school education: how to face back the decreasing interest in natural sciences shown by students under ‘pressure’ of convenient resources in digital devices/applications. The approach rests on two features. First, empowering of teen-age students to understand regular natural events around, as very few educated people they meet could do. Secondly, an understanding that rests on personal capability to test and verify experimental results from the oldest science, astronomy, with simple instruments as used from antiquity down to the Renaissance (a capability restricted to just solar and lunar motions). Because lengths in astronomy and daily life are so disparate, astronomy basically involved observing and registering values of angles (along with times), measurements being of two types, of angles on the ground and of angles in space, from the ground. First, the gnomon, a simple vertical stick introduced in Babylonia and Egypt, and then in Greece, is used to understand solar motion. The gnomon shadow turns around during any given day, varying in length and thus angle between solar ray and vertical as it turns, going through a minimum (noon time, at a meridian direction) while sweeping some angular range from sunrise to sunset. Further, the shadow minimum length varies through the year, with times when shortest and sun closest to vertical, at summer solstice, and times when longest, at winter solstice six months later. The extreme directions at sunset and sunrise correspond to the solstices, swept angular range greatest at summer, over 180 degrees, and the opposite at winter, with less daytime hours; in between, spring and fall equinoxes occur, marked by collinear shadow directions at sunrise and sunset. The gnomon allows students to determine, in addition to latitude (about 40.4° North at Madrid, say), the inclination of earth equator to plane of its orbit around the sun (ecliptic), this fundamental quantity being given by half the difference between solar distances to vertical at winter and summer solstices, with value about 23.5°. Day and year periods greatly differing by about 2 ½ orders of magnitude, 1 day against 365 days, helps students to correctly visualize and interpret the experimental measurements. Since the gnomon serves to observe at night the moon shadow too, students can also determine the inclination of the lunar orbital plane, as about 5 degrees away from the ecliptic, thus explaining why eclipses are infrequent. Independently, earth taking longer between spring and fall equinoxes than from fall to spring (the solar anomaly), as again verified by the students, was explained in ancient Greek science, which posited orbits universally as circles or their combination, by introducing the eccentric circle, with earth placed some distance away from the orbital centre when considering the relative motion of the sun, which would be closer to the earth in winter. In a sense, this can be seen as hint and approximation of the elliptic orbit proposed by Kepler many centuries later.