A framework for adaptive e-learning for continuum mechanics and structural analysis

This paper presents a project for providing the students of Structural Engineering with the flexibility to learn outside classroom schedules. The goal is a framework for adaptive E-learning based on a repository of open educational courseware with a set of basic Structural Engineering concepts and fundamentals. These are paramount for students to expand their technical knowledge and skills in structural analysis and design of tall buildings, arch-type structures as well as bridges. Thus, concepts related to structural behaviour such as linearity, compatibility, stiffness and influence lines have traditionally been elusive for students. The objective is to facilitate the student a teachinglearning process to acquire the necessary intuitive knowledge, cognitive skills and the basis for further technological modules and professional development in this area. As a side effect, the system is expected to help the students improve their preparation for exams on the subject. In this project, a web-based open-source system for studying influence lines on continuous beams is presented. It encompasses a collection of interactive user-friendly applications accessible via Web, written in JavaScript under JQuery and Dygraph Libraries, taking advantage of their efficiency and graphic capabilities. It is performed in both Spanish and English languages. The student is enabled to set the geometric, topologic, boundary and mechanic layout of a continuous beam. While changing the loading and the support conditions, the changes in the beam response prompt on the screen, so that the effects of the several issues involved in structural analysis become apparent. This open interaction with the user allows the student to simulate and virtually infer the structural response. Different levels of complexity can be handled, whereas an ongoing help is at hand for any of them. Students can freely boost their experiential learning on this subject at their own pace, in order to further share, process, generalize and apply the relevant essential concepts of Structural Engineering analysis. Besides, this collection is being added to the "Virtual Lab of Continuum Mechanics" of the UPM, launched in 2013 (http://serviciosgate.upm.es/laboratoriosvirtuales/laboratorios/medios-continuos-en-construcci%C3%B3n)

Espacios de aprendizaje experimental en escuelas de arquitectura. Una lectura a través de conceptos propios de ciencias del aprendizaje. Seis casos de estudio.

El objetivo principal que este trabajo ha perseguido tiene que ver, primero, con reconocer la arquitectura como una disciplina intensamente ligada con la realidad (espacial, constructiva, económica) para después reivindicar una docencia de la misma que busque trabar lazos más estrechos con la experiencia directa del aprendizaje. A lo largo de la primera parte del trabajo se proponer un enfoque que identifica como próximas las bases del llamado “aprendizaje experimental” con la forma de pensar que trata de transmitirse respecto al concepto de “proyectar” en nuestras escuelas. Acordada esta relación de proximidad entre el aprendizaje experimental y el aprendizaje de proyectos se da un paso más allá: la bibliografía propia de las ciencias del aprendizaje señala los rasgos que caracterizan a los espacios donde tiene lugar este aprendizaje experimental. Esta información se ha confrontado con seis ejemplos en el panorama contemporáneo de las escuelas de arquitectura que, pensábamos, podían responder a la definición de “espacios de aprendizaje experimental”. Una vez descritos se ha hecho una lectura crítica de cada uno respecto a las características descritas por las ciencias del aprendizaje. Como resultado de estas lecturas críticas podemos concluir una serie de puntos que pueden caracterizar al espacio de aprendizaje experimental en la escuela de arquitectura de cara al futuro. The main objective that this work has pursued was, first, to recognize architecture as a discipline strongly linked with reality (spatial, constructive, economic) and then claim a teaching of it to seek closer ties lock experience direct learning. Throughout the first part of the paper is to propose an approach that identifies it as coming bases called “experiential learning” with the way of thinking that is transmitted on the concept of “project” in our schools. Agreed this close relationship between experiential learning and project learning goes a step further: the bibliography own learning sciences highlights the features that characterize the spaces where this experiential learning occurs. This information has been confronted with six examples in contemporary landscape architecture schools, we thought, could fall within the definition of “experimental learning spaces”. Having described has become a critical reading of each with respect to the characteristics described by the learning sciences. As a result of these critical readings can conclude a number of points that can characterize the space of experiential learning in the school of architecture facing the future.