Engineering Education towards sustainability: approaches for institutionalization and teaching implementation : Second International Conference on Engineering Education for the 21st Century – ICEE21C 2019

199 p.The Second International Conference On Engineering Education For The Twenty-First Century (Bilbao-Spain, 4 and 5 July 2019) has been co-organized by the University of the Basque Country (UPV-EHU) and the Universitat Jaume I in Castelló (UJI), and has continued the debate started two years ago in Castelló de la Plana, where the central theme of the conference was "New Competences in the Area of Sustainability and University Social Responsibility". The central theme of this second international conference has been "Engineering Education towards Sustainability: Approaches for Institutionalization and Teaching Implementation". In a world deluged by social realities, change is an absolute necessity. Such change has found its way to European Higher Education Area, affected teaching objectives, pedagogies, and knowledge transmission. With the mission to help learners to create their capability profiles, this change visualizes graduates who can be absorbed easily by ever-evolving industries. To this aim, new active learning methodologies and Information and Communication Technologies (ICT) have been introduced and applied. These changes started to appear in classrooms in the era that also fosters social values such as Sustainable Development Goals and Conscious Social Responsibilities more than ever, striving to build an equitable world

Engineering Education towards sustainability: approaches for institutionalization and teaching implementation : Second International Conference on Engineering Education for the 21st Century – ICEE21C 2019

199 p.The Second International Conference On Engineering Education For The Twenty-First Century (Bilbao-Spain, 4 and 5 July 2019) has been co-organized by the University of the Basque Country (UPV-EHU) and the Universitat Jaume I in Castelló (UJI), and has continued the debate started two years ago in Castelló de la Plana, where the central theme of the conference was "New Competences in the Area of Sustainability and University Social Responsibility". The central theme of this second international conference has been "Engineering Education towards Sustainability: Approaches for Institutionalization and Teaching Implementation". In a world deluged by social realities, change is an absolute necessity. Such change has found its way to European Higher Education Area, affected teaching objectives, pedagogies, and knowledge transmission. With the mission to help learners to create their capability profiles, this change visualizes graduates who can be absorbed easily by ever-evolving industries. To this aim, new active learning methodologies and Information and Communication Technologies (ICT) have been introduced and applied. These changes started to appear in classrooms in the era that also fosters social values such as Sustainable Development Goals and Conscious Social Responsibilities more than ever, striving to build an equitable world

Exploring 21st Century Learning in Virginia Secondary School Technology and Engineering Classrooms: A Hermeneutic Phenomenological Study

The purpose of this phenomenological study was to examine how integrative STEM teachers utilize the Standards for Technological and Engineering Literacy (STEL) to foster and assess 21st-century learning in technology and engineering classes at multiple Virginia public secondary schools. The theory guiding this study was Kolb’s experiential learning theory, which integrates nine learning theories into an innovative cyclical learning process that is like the engineering design loop. This hermeneutic phenomenology included 15 Virginia technology and engineering schoolteachers (Grades 6-12) who purposefully taught multiple academic disciplines and utilized the eight practices of the STEL in the context of their curriculum to foster 21st-century learning. Data collection included individual interviews, journal prompts, and physical artifacts (lesson plans, assessment tools, etc.). Data were entered into the Delve data analysis software and were analyzed using Van Manen’s hermeneutic phenomenological theory for common themes regarding the fostering and assessment of 21st-century literacy. The themes extracted from the data included measuring 21st-century learning, developing 21st-century curriculum, and the eight practices of technology and engineering educators: creativity, collaboration, communication, critical thinking, optimism, attention to ethics, systems thinking, and making and doing. The findings indicated that integrative STEM methodology, multidisciplinary instruction, and the eight practices of the STEL fostered 21st-century learning. This study’s significance was to add to the available literature on integrative STEM education and the STEL fostering 21st-century learning

Video and image systems engineering education for the 21st century

Includes bibliographical references.We are developing a new graduate program at Purdue in Video and Image Systems Engineering (VISE). The project is comprised of three parts: a new curriculum centered around a degree option in VISE to be earned as part of the Masters or Ph.D. degrees; a state-of-the-art lecture/laboratory facility for instruction, laboratory experiments, and project and homework activities in VISE courses; and enhancement of existing courses and development of new courses in the VISE area.Supported by an Image Systems Engineering Grant from Hewlett-Packard Company

ExpeditionWorkshed: Engineering education for the 21st century

The Expedition Workshed is an internet based application that carries a wide range of high quality, free-to-use material that will help in the education of engineers. This paper explores the current challenges facing those involved in the education of civil and structural engineers. It goes on to describe how the Workshed sets out to help address those challenges. Among other things the role of interactive online structural models is described along with the development of a new structural modelling application “Catastrophe”. The paper concludes with some observations about the success of the initiative to date, as well as setting out the next steps that we plan to take

Educating the chemical engineer of the future

Edmond Byrne argues that sustainability needs to quickly become the context for 21st century chemical engineering education to enable engineers be fit for purpose to address significant challenges ahead. He provides some suggestions for helping achieve this

ROBOTICS COMPETITION-BASED LEARNING FOR 21ST CENTURY STEM EDUCATION

This article proposes the Robotics Competition-based Learning (R-CBL) in the 21st century learning environment to integrate Science, Technology, Engineering, and Mathematics (STEM) education. This study has an attempt to highlight the connections between the STEM disciplines as well as the integration of 21st-century competencies to spark students’ interest towards the STEM. The problem statement revealed in this article is Malaysia may soon experience a serious human capital deficiency in the STEM field. Thus, it is important to practice a new pedagogy for 21st century integrated STEM education. The objectives of this study is to investigate the effectiveness of R-CBL to increase students’ interest towards STEM in “Robot Olympics Malaysia 2018”. The finding in this research shows the educational robotics as the digital tool can promote STEM learning among secondary school students. In conclusion, by practising Robotics Competition-based Learning in 21st century STEM classroom, learners are expected to have attentiveness in the integrated STEM curriculum. The implication of this pedagogy is to bridge the gap between the expected curriculums, written curriculum, and taught the curriculum. Keywords: robotics, competition, STEM education, 21st centur

The Future - Engineering Education for the 21st Century

http://deepblue.lib.umich.edu/bitstream/2027.42/88241/1/2003_Engineering_at_Michigan4.pd

Towards a new pedagogy for engineering education in the 21st century

There have been many advances over the past four or five decades in understanding brain architecture, and how the process of learning aligns with this architecture. One of the more interesting results has been that of John Sweller [1] and his theory of cognitive load. Sweller identifies the task of learning as effecting change in long-term memory. This long-term memory is, in his view, almost limitless. The problem lies in working, or short-term memory, which has a bottleneck of around five items. Any instructional mode which places too many items into working memory will be, at best, inefficient, and at worse, pointless. It is interesting to note that over the same decades new instructional modes, such as Problem-Based Learning (PBL) have become popular [2]. Sweller, and others such as Paul Kirschner [3], argue that PBL cannot work as advertised, as the student is faced with too high a cognitive load; they can either learn how to solve the problem, or learn the underlying concepts, but not both. This paper outlines the theoretical background to this issue, and presents an intervention undertaken over the last decade in TU DUBLIN to devise new instructional modes which take account of cognitive load problems, whilst maintaining some of the advantages and benefits of PBL. This intervention initially followed the ideas of Louis Bucciarelli [4] of MIT on open design in Engineering education but was later adjusted to take into account the ideas of Kirschner on minimizing cognitive load in developing problem-solving skills

Engineering Design: The Great Integrator

There is much support in the research literature and in the standards for the integration of engineering into science education, particularly the problem solving approach of engineering design. Engineering design is most often represented through design-based learning. However, teachers often do not have a clear definition of engineering design, appropriate models for teaching students, or the knowledge and experience to develop integrative learning activities. The purpose of this article is to examine definitions of engineering design and how it can be utilized to create a transdisciplinary approach to education to advance all students’ general STEM literacy skills and 21st century cognitive competencies. Suggestions for educators who incorporate engineering design into their instruction will also be presented