Design state exploration applied to the development of a remote lab for projectile launch experiments

This paper describes the application of Design State Exploration techniques in the development of a remote lab for projectile motion experiments. The application was enabled by the existence of two independent teams: one composed of a series of internships that started first and another with two grantees that started a few months later. The paper presents evidence on how this approach provided gains in the development process conducted by the second team that benefited from design state exploration studies performed by the first team. This particular aspect is highlighted in relation to the work already presented in the 10th Remote Engineering and Virtual Instrumentation (REV) conference.

Academic effectiveness of VISIR remote lab in analog electronics

The effectiveness of VISIR is compared to other experimentation activities under the point of view presented by the professor Soysal in 2000. Advantages and limitations are discussed in terms of equipment availability, infrastructure cost, and contribution to various elements of experimental learning.

Remote lab experiments: opening possibilities for distance learning in engineering fields

Remote experimentation laboratories are systems based on real equipment, allowing students to perform practical work through a computer connected to the internet. In engineering fields lab activities play a fundamental role. Distance learning has not demonstrated good results in engineering fields because traditional lab activities cannot be covered by this paradigm. These activities can be set for one or for a group of students who work from different locations. All these configurations lead to considering a flexible model that covers all possibilities (for an individual or a group). An inter-continental network of remote laboratories supported by both European and Latin American institutions of higher education has been formed. In this network context, a learning collaborative model for students working from different locations has been defined. The first considerations are presented.

Using remote labs in education: two little ducks in remote experimentation

A book about remote labs and engineering education begs to begin with the question, “Why do engineering programs include lab work?” Although this may seem like a given and not worth discussing, whenever we’re faced with innovative ideas, it’s important to “put everything on the table” in order to reassess its value to our program or goals. What is it about lab work that is of value to students? Are there elements of traditional labs that we could let go of? Are there elements that we don’t want to lose? These questions can help us to clarify how and why labs are integrated into an engineering education program.

WebLabs in education

Remote Labs are an emergent educational resource in Engineering, which addresses the remote delivery of practical contents, i. e. remote experiments, through the web. This resource may either be used as a support for e-learning courses in Engineering or Science, in the cases where on-campus lab work is not possible, or as a complement to face-to-face lab classes, allowing the students to repeat a given experiment on a remote fashion, without time restrictions.

Using remote lab networks to provide support to public secondary school education level

The advantages of networking are widely known in many areas (from business to personal ones). One particular area where networks have also proved their benefits is education. Taking the secondary school education level into account, some successful cases can be found in literature. In this paper we describe a particular remote lab network supporting physical experiments accessible to students of institutions geographically separated. The network architecture and application examples of using some of the available remote experiments are illustrated in detail.

Remote and mobile experimentation: pushing the boundaries of an ubiquitous learning place

Concepts like E-learning and M-learning are changing the traditional learning place. No longer restricted to well-defined physical places, education on Automation and other Engineering areas is entering the so-called ubiquitous learning place, where even the more practical knowledge (acquired at lab classes) is now moving into, due to emergent concepts such as Remote Experimentation or Mobile Experimentation. While Remote Experimentation is traditionally regarded as the remote access to real-world experiments through a simple web browser running on a PC connected to the Internet, Mobile Experimentation may be seen as the access to those same (or others) experiments, through mobile devices, used in M-learning contexts. These two distinct client types (PCs versus mobile devices) pose specific requirements for the remote lab infrastructure, namely the ability to tune the experiment interface according to the characteristics (e.g. display size) of the accessing device. This paper addresses those requirements, namely by proposing a new architecture for the remote lab infrastructure able to accommodate both Remote and Mobile Experimentation scenarios.

Optimization process of polyester polymer mortars modified with recycled GFRP waste aggregates – application of factorial experiment design-

Glass fibre-reinforced plastics (GFRP), nowadays commonly used in the construction, transportation and automobile sectors, have been considered inherently difficult to recycle due to both: cross-linked nature of thermoset resins, which cannot be remolded, and complex composition of the composite itself, which includes glass fibres, matrix and different types of inorganic fillers. Presently, most of the GFRP waste is landfilled leading to negative environmental impacts and supplementary added costs. With an increasing awareness of environmental matters and the subsequent desire to save resources, recycling would convert an expensive waste disposal into a profitable reusable material. There are several methods to recycle GFR thermostable materials: (a) incineration, with partial energy recovery due to the heat generated during organic part combustion; (b) thermal and/or chemical recycling, such as solvolysis, pyrolisis and similar thermal decomposition processes, with glass fibre recovering; and (c) mechanical recycling or size reduction, in which the material is subjected to a milling process in order to obtain a specific grain size that makes the material suitable as reinforcement in new formulations. This last method has important advantages over the previous ones: there is no atmospheric pollution by gas emission, a much simpler equipment is required as compared with ovens necessary for thermal recycling processes, and does not require the use of chemical solvents with subsequent environmental impacts. In this study the effect of incorporation of recycled GFRP waste materials, obtained by means of milling processes, on mechanical behavior of polyester polymer mortars was assessed. For this purpose, different contents of recycled GFRP waste materials, with distinct size gradings, were incorporated into polyester polymer mortars as sand aggregates and filler replacements. The effect of GFRP waste treatment with silane coupling agent was also assessed. Design of experiments and data treatment were accomplish by means of factorial design and analysis of variance ANOVA. The use of factorial experiment design, instead of the one factor at-a-time method is efficient at allowing the evaluation of the effects and possible interactions of the different material factors involved. Experimental results were promising toward the recyclability of GFRP waste materials as polymer mortar aggregates, without significant loss of mechanical properties with regard to non-modified polymer mortars.

Longshore Transport Estimation on Ofir Beach in Northwest Portugal: Sand-Tracer Experiment

This work aims to shed some light on longshore sediment transport (LST) in the highly energetic northwest coast of Portugal. Data achieved through a sand-tracer experiment are compared with data obtained from the original and the new re-evaluated longshore sediment transport formulas (USACE Waterways Experiment Station’s Coastal Engineering and Research Center, Kamphuis, and Bayram bulk formulas) to assess their performance. The field experiment with dyed sand was held at Ofir Beach during one tidal cycle under medium wave-energy conditions. Local hydrodynamic conditions and beach topography were recorded. The tracer was driven southward in response to the local swell and wind- and wave-induced currents (Hsb=0.75mHsb=0.75m, Tp=11.5sTp=11.5s, θb=8−12°θb=8−12°). The LST was estimated by using a linear sediment transport flux approach. The obtained value (2.3×10−3m3⋅s−12.3×10−3m3⋅s−1) approached the estimation provided by the original Bayram formula (2.5×10−3m3⋅s−12.5×10−3m3⋅s−1). The other formulas overestimated the transport, but the estimations resulting from the new re-evaluated formulas also yield approximate results. Therefore, the results of this work indicated that the Bayram formula may give satisfactory results for predicting the longshore sediment transport on Ofir Beach.

Plano estratégico “Empowering Lab ESEIG”

Os jovens ao longo do seu percurso escolar têm aspirações e expetativas elevadas quanto ao valor de empregabilidade dos diplomas a que tiveram acesso em todos os graus de ensino. Contudo, no recente contexto de crise económica, essas aspirações e expetativas socialmente nutridas pela escola e pela família têm sido em grande medida frustradas pelas crescentes dificuldades que os jovens portugueses de hoje têm vivido nos seus processos de inserção profissional. A nível individual, um jovem que passe um longo período inativo tem grandes probabilidades de sofrer de baixa autoestima, exclusão social ou de um “wage scar”, isto é, de no futuro ter um rendimento abaixo do rendimento médio de pessoas com formação e experiência equivalentes além de desenvolverem uma atitude passiva e falta de participação social, o que no longo prazo acaba por ter implicações negativas para a sociedade como um todo. Conscientes desta realidade e sabendo que as incubadoras de negócios podem transmitir confiança à comunidade financeira e apoiar as startups, promovendo uma cultura de empreendedorismo e agindo como um catalisador para o desenvolvimento de estruturas de suporte de negócios mais amplas, partimos para o estudo da incubação de negócios com o intuito de traçar um plano estratégico para a Escola Superior de Estudos Industriais e de Gestão (ESEIG) que permitisse desenvolver a cultura empreendedora da sua comunidade e por esta via dar o seu contributo para a resolução da crise económica que o país atravessa. Começamos por fazer um enquadramento teórico da incubação de negócios e rapidamente percebemos que, sendo a ESEIG uma instituição de ensino superior, era importante incluir no estudo os conceitos de empreendedorismo e inovação e perceber ao nível teórico como funciona a relação Universidade-Empresa. De seguida, fomos para o “terreno” e percebemos que a solução para este desafio passaria por capacitar os alunos da ESEIG com as competências empresariais e empreendedoras necessárias para o desenvolvimento de qualquer empreendimento autonomamente. Faltava agora perceber qual a melhor forma de concretizar este ambicioso objetivo. Após um pouco mais de estudo, percebemos que, a paixão está no centro de empreendedorismo juntamente com outras dimensões afetivas e emocionais e pode estimular a criatividade e o reconhecimento de novos padrões de informação fundamental para a descoberta e exploração de oportunidades promissoras. Por sua vez, a alegria local (escolas, cidades, regiões, países) está associada a uma maior atividade empreendedora, o humor e sentimentos positivos, bem como a satisfação de vida geram efeitos benéficos, como melhor desempenho nas tarefas e produtividade, evolução na carreira e sucesso pessoal e maior propensão para assumir riscos. Percebemos então que é necessário desenvolver uma cultura de positividade, pelo que, sugerimos a implementação do novo quadro conceptual PROSPER (Positivity; Relationships; Outcomes; Strengths; Purpose; Engagement; Resilience) que tem o potencial de ser usado como uma ferramenta organizacional para a implementação dos sete principais componentes de bem-estar. Cientes de que o objetivo final é aumentar a intenção empreendedora dos estudantes, bem como o número efetivo de empreendedores, definimos como objetivos, promover o valor do empreendedorismo na criação de oportunidades e no desenvolvimento das competências dos estudantes (Engaging), fornecer aos estudantes oportunidades de aprendizagem empresarial (Empowering) e apoiar os estudantes na criação e no desenvolvimento de negócios (Equipping). Neste sentido, sugerimos diversas ações que materializam estes objetivos. Para finalizar, utilizamos um Lean Canvas com o intuito de concretizar a nossa proposta estratégica para ESEIG, que culmina com a criação do Empowering Lab ESEIG.