Exploring perceptions and attitudes towards teaching and learning manual technical drawing in a digital age

This paper examines the place of manual technical drawing in the 21st century by discussing the perceived value and relevance of teaching school students how to draw using traditional instruments, in a world of computer aided drafting (CAD). Views were obtained through an e-survey, questionnaires and structured interviews. The sample groups represent professional CAD users (e.g. engineers, architects); university lecturers; Technology Education teachers and student teachers; and school students taking Scottish Qualification Authority (SQA) Graphic Communication courses. An analysis of these personal views and attitudes indicates some common values between the various groups canvassed of what instruction in traditional manual technical drafting contributes towards learning. Themes emerge such as problem solving, visualisation, accuracy, co-ordination, use of standard conventions, personal discipline and artistry. In contrast to the assumptions of Prensky's thesis (2001a&b) of digital natives, the study reported in this paper indicate that the school students apparently appreciate the experience of traditional drafting. In conclusion, the paper illustrates the perceived value of such learning in terms of transferable skills, personal achievement and enjoyment

Developing Technology Applications for Improving the Problem-Solving Skills of Middle School Students with Learning Disabilities

The achievement gap in mathematics education continues to be a concern in the United States. Students with disabilities (SWD) are often excluded from the general education curriculum or the least restrictive environment due to their low performance in mathematics and disability-related deficits. Legislative and professional reports have addressed the needs of SWD by promoting evidence-based math interventions using instructional technology. However, the focus of many math interventions with instructional technology has been limited to basic facts instruction or drill-and-practice routines. In this study, I developed a curriculum-based technology tool called Anchored Instruction with Technology Applications (AITA) based on pedagogical concepts of Enhanced Anchored Instruction (EAI). For more than a decade, research has shown EAI to be effective in improving the math achievement of SWD. EAI is based on situated cognition learning theory and combines multimedia-based instruction with hands-on problems in real world contexts. AITA integrates technology applications such as 3D printers with EAI curriculum for improving problem-solving skills of SWD. The study examined differential effects of AITA in resource rooms and inclusive classrooms. Results showed significant improvement in favor of AITA for SWD in both problem-solving and computation performance

Interactive virtual method applied in urban design education. Mixed Approach

La memòria d'aquesta tesi tracta sobre l'ús de la transformació digital en l'ensenyament i els processos de disseny urbà, a través de conceptes innovadors i metodologies pràctiques. L'objectiu és promoure l'ús de tecnologies digitals, en particular per avaluar la inclusió de la realitat virtual en diversos entorns d'ensenyament formals i informals del disseny urbà col·laboratiu, per tal de millorar, accelerar i augmentar el seu impacte social de forma positiva i millorar l'ensenyament universitària ajudant al fet que els estudiants consolidin amb major efectivitat les seves habilitats. Amb les característiques d’un sistema de realitat virtual, podem provar la nostra hipòtesi en funció de demostrar: (1) La implementació d'estratègies virtuals gamificades en el camp del disseny urbà generarà una millora i motivació en la participació ciutadana i dels estudiants, ja que l’entorn és més dinàmic, real i permet un disseny col·laboratiu àgil gràcies a les tecnologies visuals immersives, mentre avaluen críticament el resultat d'un disseny urbà i prenen decisions. (2) L'ús de sistemes virtuals interactius per a la comprensió de l'espai tridimensional millora en els estudiants i professionals la percepció de la comprensió de l'espai, generant major enteniment de les condicions d'ubicació, dimensions i relacions dels espais urbans, i defensar els arguments de projectes urbans i propostes urbanes definides interactivament que proven diverses estratègies d'acció. Per provar les nostres hipòtesis, fem servir un mètode quantitatiu i qualitatiu aplicat en diferents escenaris i als diferents perfils d'usuaris, estudiants, professionals i usuaris finals. Els resultats mostraran que és possible potenciar la transformació digital, millorar la motivació pública, la implicació i la satisfacció en els processos de presa de decisions urbanes, així com complementar l'adquisició de competències urbanes específiques necessàries per a la professió en estudiants d'Arquitectura.La memoria de esta tesis trata sobre el uso de la transformación digital en la enseñanza y los procesos de diseño urbano, a través de conceptos innovadores y metodologías prácticas. El objetivo es promover el uso de tecnologías digitales, en particular para evaluar la inclusión de la realidad virtual en diversos entornos de enseñanza formales e informales del diseño urbano colaborativo, con el fin de mejorarlo, acelerar y aumentar su impacto social positivo y mejorar la enseñanza universitaria ayudando a que los estudiantes consoliden con mayor efectividad sus habilidades. Con las características de un sistema de realidad virtual, podemos probar nuestra hipótesis en función de demostrar: (1) El uso de sistemas virtuales interactivos para la comprensión del espacio tridimensional mejora en los estudiantes y profesionales la percepción de la comprensión del espacio, generando mayor entendimiento de las condiciones de ubicación, dimensiones y relaciones de los espacios urbanos, y defender los argumentos de proyectos urbanos y propuestas urbanas definidas interactivamente que ensayan diversas estrategias de acción. (2) La implementación de estrategias virtuales gamificadas en el campo del diseño urbano generará una mejora y motivación en la participación ciudadana y en los estudiantes, ya que es un entorno de colaboración más dinámico, real y ágil gracias a las tecnologías visuales inmersivas, mientras evalúan críticamente el resultado de un diseño urbano y toman decisiones. Para probar nuestras hipótesis, utilizamos un método cuantitativo y cualitativo aplicado en diferentes escenarios y a diferentes perfiles de usuarios, estudiantes, profesionales y usuarios finales. Los resultados mostrarán que es posible potenciar la transformación digital, mejorar la motivación pública, la implicación y la satisfacción en los procesos de toma de decisiones urbanas, así como complementar la adquisición de competencias urbanas específicas necesarias para la profesión en estudiantes de Arquitectura.The memory of this thesis deals with the use of digital transformation in the teaching and processes of urban design, through innovative concepts and practical methodologies. The objective is to promote the use of digital technologies, in particular, to evaluate the inclusion of virtual reality in various formal and informal teaching environments of collaborative urban design, in order to improve it, speed up, and increase its positive social impact and improve university teaching by helping students consolidate their skills more effectively. With the characteristics of the VR system, we can test our hypothesis based on demonstrating: (1) The use of virtual-interactive systems for the understanding of three- dimensional space improve in students and professionals the perception of the comprehension of the space, generating a greater understanding of the location conditions, dimensions and relationships of urban spaces, and defend the arguments of urban projects and interactively defined urban proposals rehearsing various strategies of action. (2) The implementation of virtual gamified strategies in the field of urban design will generate improvement and motivation in citizen participation and students as it is a more dynamic, real and agile collaborative environment thanks to the immersive visual technologies as they critically evaluate the result of the urban design and make decisions. To validate our hypothesis, we use a quantitative and qualitative method applied in different scenarios and to a different profile of users, students, professionals and end users. The results will show that it is possible to empower digital transformation, to improve public motivation, implication, and satisfaction in urban decision-making processes as well as complementing the improvement of the perception of the comprehension of the space needed for the profession in Architecture students

Makers at School, Educational Robotics and Innovative Learning Environments

This open access book contains observations, outlines, and analyses of educational robotics methodologies and activities, and developments in the field of educational robotics emerging from the findings presented at FabLearn Italy 2019, the international conference that brought together researchers, teachers, educators and practitioners to discuss the principles of Making and educational robotics in formal, non-formal and informal education. The editors’ analysis of these extended versions of papers presented at FabLearn Italy 2019 highlight the latest findings on learning models based on Making and educational robotics. The authors investigate how innovative educational tools and methodologies can support a novel, more effective and more inclusive learner-centered approach to education. The following key topics are the focus of discussion: Makerspaces and Fab Labs in schools, a maker approach to teaching and learning; laboratory teaching and the maker approach, models, methods and instruments; curricular and non-curricular robotics in formal, non-formal and informal education; social and assistive robotics in education; the effect of innovative spaces and learning environments on the innovation of teaching, good practices and pilot projects

Building Conceptual Understandings of Equivalence

The equal sign is prevalent at all levels of mathematics however many students misunderstand the meaning of the equal sign and consider it an operational symbol for the completion of an algorithm (Baroody & Ginsburg, 1983; Rittle-Johnson & Alibali, 1999). Three constructs were studied through the lens of the Developing Mathematical Thinking (Brendefur, 2008), Relational Thinking, Spatial Reasoning and Modes of Representation. A review of literature was conducted to examine the effects of mathematics instruction on the development of students’ conceptual understanding of equivalence through the integration of spatial reasoning and relational thinking. The Developing Mathematical Thinking (DMT) curricular resources integrate Bruner’s enactive, iconic, and symbolic modes of representations (1966), using tasks designed to strengthen students’ spatial reasoning and relational thinking to develop mathematical equivalence. The research question “What is the effect of integrating iconic teaching methodology into mathematics instruction on first grade students’ relational thinking and spatial reasoning performance?” was analyzed to determine whether there was a significant difference in pre-and posttest scores for the two groups. Students were found to have a better opportunity to develop conceptual understanding of mathematics in their early years of school when taught with the progression of EIS, relational thinking and spatial reasoning

Where and how 3D printing is used in teaching and education

The emergence of additive manufacturing and 3D printing technologies is introducing industrial skills deficits and opportunities for new teaching practices in a range of subjects and educational settings. In response, research investigating these practices is emerging across a wide range of education disciplines, but often without reference to studies in other disciplines. Responding to this problem, this article synthesizes these dispersed bodies of research to provide a state‐of‐the‐art literature review of where and how 3D printing is being used in the education system. Through investigating the application of 3D printing in schools, universities, libraries and special education settings, six use categories are identified and described: (1) to teach students about 3D printing; (2) to teach educators about 3D printing; (3) as a support technology during teaching; (4) to produce artefacts that aid learning; (5) to create assistive technologies; and (6) to support outreach activities. Although evidence can be found of 3D printing‐based teaching practices in each of these six categories, implementation remains immature, and recommendations are made for future research and education policy.This work was supported by the Engineering and Physical Sciences Research Council [number EP/K039598/1]

The Impact of Design-Based Modeling Instruction on Seventh Graders\u27 Spatial Abilities and Model-Based Argumentation

Due to the call of current science education reform for the integration of engineering practices within science classrooms, design-based instruction is receiving much attention in science education literature. Although some aspect of modeling is often included in well-known design-based instructional methods, it is not always a primary focus. The purpose of this study was to better understand how design-based instruction with an emphasis on scientific modeling might impact students\u27 spatial abilities and their model-based argumentation abilities. In the following mixed-method multiple case study, seven seventh grade students attending a secular private school in the Mid-Atlantic region of the United States underwent an instructional intervention involving design-based instruction, modeling and argumentation. Through the course of a lesson involving students in exploring the interrelatedness of the environment and an animal\u27s form and function, students created and used multiple forms of expressed models to assist them in model-based scientific argument. Pre/post data were collected through the use of The Purdue Spatial Visualization Test: Rotation, the Mental Rotation Test and interviews. Other data included a spatial activities survey, student artifacts in the form of models, notes, exit tickets, and video recordings of students throughout the intervention. Spatial abilities tests were analyzed using descriptive statistics while students\u27 arguments were analyzed using the Instrument for the Analysis of Scientific Curricular Arguments and a behavior protocol. Models were analyzed using content analysis and interviews and all other data were coded and analyzed for emergent themes. Findings in the area of spatial abilities included increases in spatial reasoning for six out of seven participants, and an immense difference in the spatial challenges encountered by students when using CAD software instead of paper drawings to create models. Students perceived 3D printed models to better assist them in scientific argumentation over paper drawing models. In fact, when given a choice, students rarely used paper drawing to assist in argument. There was also a difference in model utility between the two different model types. Participants explicitly used 3D printed models to complete gestural modeling, while participants rarely looked at 2D models when involved in gestural modeling. This study\u27s findings added to current theory dealing with the varied spatial challenges involved in different modes of expressed models. This study found that depth, symmetry and the manipulation of perspectives are typically spatial challenges students will attend to using CAD while they will typically ignore them when drawing using paper and pencil. This study also revealed a major difference in model-based argument in a design-based instruction context as opposed to model-based argument in a typical science classroom context. In the context of design-based instruction, data revealed that design process is an important part of model-based argument. Due to the importance of design process in model-based argumentation in this context, trusted methods of argument analysis, like the coding system of the IASCA, was found lacking in many respects. Limitations and recommendations for further research were also presented