Enhancing the Main Characteristics of Active Methodologies: A Case with Micro Flip Teaching and Teamwork

All active methodologies have common objectives and processes. Their mission is to ensure that students participate actively in the learning process, cooperating with other students, reflecting, making decisions and creating knowledge. For this purpose, groups that work in a timely manner to carry out an activity or in a more stable way through work teams are usually formed. In both cases, active learning takes place within the groups. This work proposes fostering an active inter-team learning; that is, forming a meta-team where active learning takes place. The aim is checking if students who follow an active methodology, have the active habit; that is, if the work teams share knowledge among themselves and use it to improve their own knowledge. The proposed model contains a virtual layer that all teams can access, making possible the cooperation, the creation of new knowledge, reflection and decision making. This model is applicable to any active methodology and the proposed model has been applied to the Micro Flip Teaching methodology. This quasi experimental research methodology, based on quantitative and qualitative assessment, shows how the work teams, in an Engineering context, in this case, use this virtual layer and how that use impacts the academic performance of their members. Another conclusion of this work is that feedback must be included in active methodologies

Active Peer-Based Flip Teaching: An Active Methodology Based on RT-CICLO

[EN]The RT-CICLO model (real time – collective intelligence applied to a cooperative learning with a social base) is based on generalist processes identified in main active methodologies. This model has been developed as a general model. Therefore, it could be applicable to any active methodology. The main characteristic of the RT-CICLO method is not only to foster active learning, but also to enable students to acquire active skills. In this chapter, the RT-CICLO model is applied to a flip teaching methodology throughout all its phases (lesson at home and homework in the classroom). The main results are obtained in two steps. The first step confirms that students acquire active skills. The second one explores the impact of knowledge creation by students as a way to get feedback and to use the created knowledge as a learning object. It should be highlighted that students’ perceptions are positive using this approac

APFT: Active peer-based Flip Teaching

The Flip Teaching model1 (the lesson at home, the homework in class) has been used to actively engage students in their learning process during the lectures. In this method, passive learning (the lesson) is transferred to homework and the activity (exercises, debates, collaborative learning, etc.) to the class. More advanced Flip Teaching models carry out an intermediate phase in which the students can actively participate "at home", such as Micro Flip Teaching model. This model proposes an on-line activity composed by the learning of the lesson and the realization of an individual micro-activity on the same and then, in class, work on the obtained results in the micro-activity. In this work, the Micro Flip Teaching model has been adapted to carry out the online activity in a collaborative way in work teams. The main novelty of this proposal is that the active participation of the students generates resources that can be used as didactic material in future editions of the subject. To evaluate the impact of this proposal, an experimental group has been established that used resources generated by students from previous subject editions, while the control group used only resources generated by the teacher. The research shows that the resources generated by students are equally effective than those generated by teachers

Improving the Quality of Technology-Enhanced Learning for Computer Programming Courses

Teaching computing courses is a major challenge for the majority of lecturers in Libyan higher learning institutions. These courses contain numerous abstract concepts that cannot be easily explained using traditional educational methods. This paper describes the rationale, design, development and implementation stages of an e-learning package (including multimedia resources such as simulations, animations, and videos) using the ASSURE model. This training package can be used by students before they attend practical computer lab sessions, preparing them by developing technical skills and applying concepts and theories presented in lecture through supplementary study and exercises

Flipped Learning 4.0. An extended flipped classroom model with Education 4.0 and organisational learning processes

This article integrates two visions on the creation of knowledge by students: an academic vision where the person who creates knowledge uses high-level cognitive abilities and, therefore, acquires deeper learning, and an organisational learning vision, where the creation of knowledge adds value to the organisation and the individuals who work in this matter. It starts from a validated flipped classroom model and then adds procedures and cycles of knowledge that make it an active methodology, in such a way that it simultaneously supports organisational learning, using cooperative competencies characteristic of Education 4.0. This proposed hybrid model has been applied online during confinement due to the COVID-19 pandemic and, subsequently, in dual mode (students partly in person and the rest online at the same time) and face-to-face mode. The evidence of this research shows that the creation of knowledge by the students, cooperatively and with an organisational learning perspective, has repercussions for improvements in their academic performance by producing deeper learning. In addition, the development of cooperative skills is observed to create and manage a large amount of helpful knowledge for them and other students in their learning process

New Online Teaching Mode of Higher Education with Information Technology

In this article, the current situation of online teaching of higher education in the information age was briefly described, and the characteristics of MOOC and SPOC was also analyzed and compared to propose and construct a new mode of post-MOOC online education based on "autonomous learning - collaborative learning – mixed learning and learning "SCH-SPOC teaching model; and taking the teaching of engineering graphics course exploration as an example, demonstrated the resource-sharing individualized learning mode, while co-teaching collaborative learning mode and flip classroom mixed learning The significance of the new model is to gradually break the traditional pattern of "full house"

The Boston University Photonics Center annual report 2013-2014

This repository item contains an annual report that summarizes activities of the Boston University Photonics Center in the 2013-2014 academic year. The report provides quantitative and descriptive information regarding photonics programs in education, interdisciplinary research, business innovation, and technology development. The Boston University Photonics Center (BUPC) is an interdisciplinary hub for education, research, scholarship, innovation, and technology development associated with practical uses of light.This annual report summarizes activities of the Boston University Photonics Center in the 2013–2014 academic year.This has been a good year for the Photonics Center. In the following pages, you will see that the center’s faculty received prodigious honors and awards, generated more than 100 notable scholarly publications in the leading journals in our field, and attracted $14.5M in new research grants and contracts this year. Faculty and staff also expanded their efforts in education and training, through National Science Foundation–sponsored sites for Research Experiences for Undergraduates and for Teachers. As a community, we hosted a compelling series of distinguished invited speakers, and emphasized the theme of Innovations at the Intersections of Micro/Nanofabrication Technology, Biology, and Biomedicine at our annual Future of Light Symposium. We took a leadership role in running national workshops on emerging photonic fields, including an OSA Incubator on Controlled Light Propagation through Complex Media, and an NSF Workshop on Noninvasive Imaging of Brain Function. Highlights of our research achievements for the year include a distinctive Presidential Early Career Award for Scientists and Engineers (PECASE) for Assistant Professor Xue Han, an ambitious new DoD-sponsored grant for Multi-Scale Multi-Disciplinary Modeling of Electronic Materials led by Professor Enrico Bellotti, launch of our NIH-sponsored Center for Innovation in Point of Care Technologies for the Future of Cancer Care led by Professor Cathy Klapperich, and successful completion of the ambitious IARPA-funded contract for Next Generation Solid Immersion Microscopy for Fault Isolation in Back-Side Circuit Analysis led by Professor Bennett Goldberg. These three programs, which represent more than$20M in research funding for the University, are indicative of the breadth of Photonics Center research interests: from fundamental modeling of optoelectronic materials to practical development of cancer diagnostics, from exciting new discoveries in optogenetics for understanding brain function to the achievement of world-record resolution in semiconductor circuit microscopy. Our community welcomed an auspicious cohort of new faculty members, including a newly hired assistant professor and a newly hired professor (and Chair of the Mechanical Engineering Department). The Industry/University Cooperative Research Center—the centerpiece of our translational biophotonics program—continues to focus on advancing the health care and medical device industries, and has entered its fourth year of operation with a strong record of achievement and with the support of an enthusiastic industrial membership base

The Boston University Photonics Center annual report 2013-2014

This repository item contains an annual report that summarizes activities of the Boston University Photonics Center in the 2013-2014 academic year. The report provides quantitative and descriptive information regarding photonics programs in education, interdisciplinary research, business innovation, and technology development. The Boston University Photonics Center (BUPC) is an interdisciplinary hub for education, research, scholarship, innovation, and technology development associated with practical uses of light.This annual report summarizes activities of the Boston University Photonics Center in the 2013–2014 academic year.This has been a good year for the Photonics Center. In the following pages, you will see that the center’s faculty received prodigious honors and awards, generated more than 100 notable scholarly publications in the leading journals in our field, and attracted $14.5M in new research grants and contracts this year. Faculty and staff also expanded their efforts in education and training, through National Science Foundation–sponsored sites for Research Experiences for Undergraduates and for Teachers. As a community, we hosted a compelling series of distinguished invited speakers, and emphasized the theme of Innovations at the Intersections of Micro/Nanofabrication Technology, Biology, and Biomedicine at our annual Future of Light Symposium. We took a leadership role in running national workshops on emerging photonic fields, including an OSA Incubator on Controlled Light Propagation through Complex Media, and an NSF Workshop on Noninvasive Imaging of Brain Function. Highlights of our research achievements for the year include a distinctive Presidential Early Career Award for Scientists and Engineers (PECASE) for Assistant Professor Xue Han, an ambitious new DoD-sponsored grant for Multi-Scale Multi-Disciplinary Modeling of Electronic Materials led by Professor Enrico Bellotti, launch of our NIH-sponsored Center for Innovation in Point of Care Technologies for the Future of Cancer Care led by Professor Cathy Klapperich, and successful completion of the ambitious IARPA-funded contract for Next Generation Solid Immersion Microscopy for Fault Isolation in Back-Side Circuit Analysis led by Professor Bennett Goldberg. These three programs, which represent more than$20M in research funding for the University, are indicative of the breadth of Photonics Center research interests: from fundamental modeling of optoelectronic materials to practical development of cancer diagnostics, from exciting new discoveries in optogenetics for understanding brain function to the achievement of world-record resolution in semiconductor circuit microscopy. Our community welcomed an auspicious cohort of new faculty members, including a newly hired assistant professor and a newly hired professor (and Chair of the Mechanical Engineering Department). The Industry/University Cooperative Research Center—the centerpiece of our translational biophotonics program—continues to focus on advancing the health care and medical device industries, and has entered its fourth year of operation with a strong record of achievement and with the support of an enthusiastic industrial membership base

The Implementation of Flipped Classroom Teaching Mode in Basic English Teaching for Tibetan College Students

For Tibetan college students to learn English, code-switching hinders them because Tibetan, Chinese, as well as English, form a trilingual environment for language learning. To improve such situation, this article studies the implementation of flipped classroom mode which can innovate the traditional teaching mode by fully highlighting the students’ subjectivity as well as stimulating the students’ initiative and enthusiasm

Design and Analysis of Project-driven Flipping Classroom Teaching Cases

"Web Design and Production" is a strong practical computer science foundation course. The concept, ideas and techniques of web front-end development have an important impact on the follow-up courses. The paper compares and analyzes the reform in current teaching methods of the course, and proposes a project-driven flipping classroom teaching method, which rationally decomposes and reorganizes the curriculum knowledge system, and divides the curriculum content into several modules. Meanwhile, each module is driven by a project, mixing problem-based teaching methods, task-driven methods and flipping classroom teaching methods. The paper clarifies pre-class, in-class, and after-school tasks. Knowing the project tasks before class, understanding the knowledge and skills needed for the design project, using the micro-curriculum resources to learn and practice knowledge autonomously; detecting the learning effect of knowledge in the class, solving the problems in the self-learning, and apply the learned knowledge to the actual project development by the way of group collaboration in order to promote internalization and application of knowledge, when encountering new problems, teachers not only explain new knowledge to help students continue to implement the project, but also promptly recorded the completion of the project of the group collaboration; After class, teachers summarize questions, build a knowledge system, and guide students to complete extended design of project. In this way, students\u27 practical application ability, project development ability, self-learning ability and creative ability can be improved. This article also provides specific instructional design cases based on the  "Web Page Layout and Beautification" module and provides specific teaching design cases