Extending STEM Education to Engineering Programs at the Undergraduate College Level

Zaher, Ashraf A.; Damaj, Issam

doi:10.3991/ijep.v8i3.8402

Cited by 18 publications

(15 citation statements)

References 9 publications

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“…We realized program of education of future green engineers for improving curriculum system and strengthening the practice of green engineering education which was based on the experience of scientists [19,22,25] and included:…”

Section: Program Of Education Of Future Green Engineersmentioning

confidence: 99%

Education of Future Green Engineers for Achieving Sustainable Development in Green Manufacturing Industry

et al. 2021

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The article is devoted to education of future green engineers for achieving sustainable development in green manufacturing industry. It outlines that green engineering is an important industry which aim is to reduce consumption, to save resources, and to achieve sustainable development in manufacturing. Green manufacturing puts forward new requirements for the training future green engineers. The article reveals the concepts of educating future green engineers. Specifical attention is paid to the improvement of the teaching system training of future green engineers, strengthening the teaching staff, changing the teaching mode, strengthening teaching practice and practical training for achieving teaching goals. The authors conclude that it is necessary to clarify the goals of training of future green engineers, and to establish reform the teaching content of green engineering course.

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Section: Program Of Education Of Future Green Engineersmentioning

confidence: 99%

Education of Future Green Engineers for Achieving Sustainable Development in Green Manufacturing Industry

et al. 2021

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“…According to Zaher and Damaj (2018), STEM curriculum mainly focuses on addressing "facts and problems" by giving well-known and clear solutions rather than orienting students to seek a variety of solutions. Therefore, to deal with these issues, Pringle et al (2015) propose that technology-supported collaborative learning be promoted to make students ready for the 21 st century working environment in STEM areas.…”

Section: Current Debates Surrounding Stem Steam and Streammentioning

confidence: 99%

The Transformation from STEM to STREAM Education at Engineering and Technology Institutions of Higher Education

2021

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The scope of STEM based academic programs such as engineering and technology education should be widened to include Science, Technology, Reading, Engineering, Arts and Mathematics (STREAM) to enable future STEM graduates to be able to respond to the rapid changes of IR 4.0 and be ready for STEM based professions of the 21st century. A STREAM based curriculum for STEM focused programs will promote 21st century skills including collaboration, communication, creativity and critical thinking. STREAM has been gaining much popularity globally, given its ability to provide opportunities for learners to develop 21st century skills and the 4Cs necessary to strive in the future workplace. In this paper, we provide a succinct review of current debates surrounding this issue, drawing upon examples from across the globe, in Malaysia and Vietnam.

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“…As stated by Coffland and Xie [1], the gap between course materials and students' real-life mathematical experiences, the scattering of knowledge in different courses, and the lack of mathematics applications to other subjects all hinder the learning of students [2][3] [4]. The emerging trends in data science, machine learning, and artificial intelligence also impel teachers to make corresponding changes in mathematics education [5] [6]. Several experiments and improvements are thus carried out, including integrated curriculum, multidisciplinary programs [7], collaborative learning [8], blended learning [9], and capstone courses [10].…”

Section: Introductionmentioning

confidence: 99%

Enriching Undergraduate Mathematics Curriculum with Computer Science Courses

Kao

2021

Int. J. Eng. Ped.

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Traditional mathematics curriculum faces several issues nowadays. The gap between course materials and students’ real-life mathematical experiences, the scattering of knowledge in different courses, and the lack of mathematics applications to other subjects all hinder the learning of students. The emerg-ing trends in data science, machine learning, and artificial intelligence also impel higher education to enrich and refine mathematics education. In order to better incubate students for future, the experience of enriching undergrad-uate mathematics curriculum with computer science courses is introduced in this study. The curriculum is designed and implemented for students who major in applied mathematics to better stimulate the learning, participation, exercise, and innovation. It provides students with comprehensive theoretical and practical knowledge for the challenges and industrial requirements now-adays. Evaluations, major findings, and lessons learned from three refined courses are discussed for more insight into the following deployment and re-finement of the curriculum.

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Extending STEM Education to Engineering Programs at the Undergraduate College Level

Cited by 18 publications

References 9 publications

Education of Future Green Engineers for Achieving Sustainable Development in Green Manufacturing Industry

Education of Future Green Engineers for Achieving Sustainable Development in Green Manufacturing Industry

The Transformation from STEM to STREAM Education at Engineering and Technology Institutions of Higher Education

Enriching Undergraduate Mathematics Curriculum with Computer Science Courses

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