Relatório de estágio

O presente relatório espelha o processo de desenvolvimento e aprendizagem da mestranda no âmbito das unidades curriculares Prática Pedagógica Supervisionada em Educação Pré-Escolar e no 1.º ciclo do Ensino Básico, integradas no Mestrado em Educação Pré-Escolar e Ensino do 1.º Ciclo do Ensino Básico. Enquanto futura profissional de educação, os saberes adquiridos e mobilizados ao longo das Práticas Pedagógicas Supervisionadas e da sua formação inicial foram imprescindíveis para uma ação educativa sustentada tanto para os momentos de estágio como para a sua prática futura. O quadro teórico que sustentou a sua ação permitiu-lhe o desenvolvimento da sua pessoalidade na forma de pensar e agir no contexto, com vista a uma melhor prática educativa. A metodologia de investigação-ação teve também um papel preponderante no processo de aprendizagem da mestranda. Esta metodologia é cíclica e integra as fases da observação, planificação, ação, avaliação e reflexão. Esta metodologia possibilitou à mestranda a planificação da sua ação educativa de forma intencional, de acordo com as especificidades dos dois grupos de crianças com que contactou diariamente nos diferentes contextos. Assim, a formanda procurou desenvolver as suas competências profissionais tendo por base a perspetiva holística e construtivista da educação – a criança no cerne do seu processo de ensino e aprendizagem – adotando, para isso, uma atitude indagadora, investigadora, reflexiva e crítica, com vista à melhoria das suas práticas. Através de processos reflexivos e colaborativos, esta formação permitiu à mestranda a construção de um perfil profissional duplo constituindo-se assim como o primeiro passo para a sua formação/aprendizagem ao longo da vida da mestranda.

E-Learning as a shared service in shared services centers

Book Subtitle International Conference, CENTERIS 2010, Viana do Castelo, Portugal, October 20-22, 2010, Proceedings, Part II

Reverse problem-based learning - a case study with a Braille machine

Engineering Education includes not only teaching theoretical fundamental concepts but also its verification during practical lessons in laboratories. The usual strategies to carry out this action are frequently based on Problem Based Learning, starting from a given state and proceeding forward to a target state. The possibility or the effectiveness of this procedure depends on previous states and if the present state was caused or resulted from earlier ones. This often happens in engineering education when the achieved results do not match the desired ones, e.g. when programming code is being developed or when the cause of the wrong behavior of an electronic circuit is being identified. It is thus important to also prepare students to proceed in the reverse way, i.e. given a start state generate the explanation or even the principles that underlie it. Later on, this sort of skills will be important. For instance, to a doctor making a patient?s story or to an engineer discovering the source of a malfunction. This learning methodology presents pedagogical advantages besides the enhanced preparation of students to their future work. The work presented on his document describes an automation project developed by a group of students in an engineering polytechnic school laboratory. The main objective was to improve the performance of a Braille machine. However, in a scenario of Reverse Problem-Based learning, students had first to discover and characterize the entire machine's function before being allowed (and being able) to propose a solution for the existing problem.

Design a computer programming learning environment for Massive Open Online Courses

Teaching and learning computer programming is as challenging as difficult. Assessing the work of students and providing individualised feedback to all is time-consuming and error prone for teachers and frequently involves a time delay. The existent tools and specifications prove to be insufficient in complex evaluation domains where there is a greater need to practice. At the same time Massive Open Online Courses (MOOC) are appearing revealing a new way of learning, more dynamic and more accessible. However this new paradigm raises serious questions regarding the monitoring of student progress and its timely feedback. This paper provides a conceptual design model for a computer programming learning environment. This environment uses the portal interface design model gathering information from a network of services such as repositories and program evaluators. The design model includes also the integration with learning management systems, a central piece in the MOOC realm, endowing the model with characteristics such as scalability, collaboration and interoperability. This model is not limited to the domain of computer programming and can be adapted to any complex area that requires systematic evaluation with immediate feedback.