Unpacking the Engineering Process: Resourcing Trade Books and Biographies

Interest in engineering education is growing, and libraries are often the hub of science, technology, engineering, and mathematics (STEM) learning activities in schools and communities. To enhance patrons’ experiences, many libraries have incorporated making, maker, and tinkering spaces that support STEM learning and engineering thinking. Making, maker, and tinkering spaces generally include opportunities for patrons to have hands-on experiences with a variety of materials, technology resources, and design challenges that encourage thinking like an engineer. This type of thinking is “goal-oriented thinking that addresses problems and decisions within given constraints by drawing on available resources, both material resources and human capital.” Thinking like an engineer, making, and tinkering are all part of engineering design-based learning.

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THE IMPLEMENTATION OF SCIENCE, TECHNOLOGY, ENGINEERING, AND MATHEMATICS (STEM) LEARNING TO IMPROVE BASIC ASKING SKILLS AND LEARNING ACHIEVEMENTS STUDENTS OF ELEMENTARY SCHOOL

AL-ISHLAH: Jurnal Pendidikan ◽

10.35445/alishlah.v11i2.133 ◽

2019 ◽

Vol 11 (2) ◽

pp. 210

Author(s):

Ilma Aulia Mufidah

Keyword(s):

Student Achievement ◽

Data Collection ◽

Mastery Learning ◽

Learning Activities ◽

Stem Learning ◽

Data Collection Tool ◽

Student Activities ◽

Science Technology ◽

Fourth Grade Students ◽

And Mathematics

This study aims to improve basic questioning skills and student achievement through learning based on science, technology, engineering, and mathematics (STEM). This is a classroom action research that carried out in two cycles, each cycle consisting of two meetings. The subjects of this research were 30 fourth grade students. The data collection tool used evaluation tests, observation sheets for teacher and student activities, and observation sheets for students' basic questioning skills. The results showed that the application of STEM learning can improve students' basic questioning skills from the first cycle with an average of 2.48 to 4.45 in the second cycle. Students' mastery learning presentation also increased every cycle, from 70.44% to 96.66% for science lessons and 78.94% to 96.66% for Indonesian language lessons. The application of STEM-based learning gives good results and learning activities take place actively and pleasantly.

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Penggunaan STEM (Science, Technology, Engineering, and Mathematics) Terintegrasi Pembelajaran berbasis Proyek untuk Mahasiswa

Biosel Biology Science and Education ◽

10.33477/bs.v9i2.1627 ◽

2020 ◽

Vol 9 (2) ◽

pp. 115

Author(s):

Anggi Tias Pratama ◽

Kintan Limiansi ◽

Rizqa Devi Anazifa

Keyword(s):

Data Analysis ◽

Environmental Science ◽

Descriptive Analysis ◽

Biology Education ◽

Project Based Learning ◽

Learning Activities ◽

Student Interest ◽

Stem Learning ◽

Science Technology ◽

And Mathematics

This study provides insights into STEM practices that are integrated with project-based learning. We show that when investigations into student interest and active participation, there are opportunities to experience project-based learning. The sample in the study was 30 students of biology education who attended environmental science lectures. The data analysis was carried out qualitatively with descriptive analysis to see the dominance of learning arrangements, learning activities, and the products of each of these learning settings. Students work on projects using the STEM learning steps. The results show that students can work on projects well, and are able to publish their work on YouTube. Keywords: STEM, Project-Based Learning, Environmental Science

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How STEM Academy Teachers Conceptualize and Implement STEM Education

Journal of Research in STEM Education ◽

10.51355/jstem.2015.8 ◽

2015 ◽

Vol 1 (1) ◽

pp. 45-58

Author(s):

Teruni Lamberg ◽

Nicole Trzynadlowski

Keyword(s):

Elementary Teachers ◽

Stem Education ◽

Teacher Interviews ◽

Science Technology ◽

Hands On ◽

Subject Areas ◽

And Mathematics ◽

K 12 ◽

Reading Activities ◽

Science Activities

STEM (science, technology, engineering and mathematics) education has been gaining increasing nationwide attention. While the STEM movement has ambitious goals for k-12 education, a lack of shared understanding exists of what STEM is as well as how to implement STEM in the elementary classroom. This study investigates how seven elementary teachers in three STEM academy schools conceptualize and implement STEM in their classrooms. Teacher interviews were conducted. The findings reveal that the majority of teachers believe that STEM education involves integrating STEM subject areas. STEM activities consisted of student-led research and reading activities on STEM topics. Two teachers described STEM as involving “hands-on” science activities. Teachers at each STEM academy school conceptualized and implemented STEM differently. How STEM was implemented at each school was based on how teachers interpreted STEM and the resources they had access to. The STEM coaches played a central role in supporting the elementary teachers to plan and implement lessons. Teachers relied on them for ideas to plan and teach STEM lessons. The results of this study indicate that as more schools embrace the STEM movement, a unified understanding and resources are needed to support teachers.

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Implementasi Sains Teknologi Engineering dan Matematika (STEM) berbasis kewirausahaan budidaya lele dumbo dengan media bioflok dan pakan Bungkil Inti Sawit (BIS) di SMP Purnama Pekanbaru

Unri Conference Series: Community Engagement ◽

10.31258/unricsce.1.401-410 ◽

2019 ◽

Vol 1 ◽

pp. 401-410

Author(s):

Yustina Yustina ◽

Nursal Nursal ◽

Indra Suharman ◽

Arif Riandra ◽

Oky Priawan ◽

...

Keyword(s):

Community Service ◽

Palm Kernel ◽

Project Based Learning ◽

Fish Growth ◽

Learning Activities ◽

Economic Data ◽

Growth Data ◽

Operational Costs ◽

Science Technology ◽

And Mathematics

Community Service aims to determine the ability of students in the Implementation of Science Technology Engineering and Mathematics (STEM) Based on Entrepreneurship of Dumbo Catfish Cultivation with Bioflok and Feed Media made by Palm Kernel Oil (BIS). P2M activities are conducted at Pekanbaru Purnama Middle School through Extracurricular learning activities from March to June 2019. Participants are 20 students consisting of 4 groups. The method of using the STEM approach with the Project Based Learning (PjBL) model consists of 3 stages, namely: 1. Preparation: bioflok making training, feed making and seed procurement; 2. Implementation: treatment, maintenance, supervision and collection of growth data, operational costs: 3. Analysis of entrepreneurial economic data and STEM capabilities. Instrument for collecting growth data and operational costs using logbooks and observation sheets. Data on STEM and Entrepreneurship Capabilities using Student Worksheets. Data on fish growth and operational costs, then percentage, were scaled, tabulated and analyzed descriptively. The results of STEM abilities were obtained namely Science ability with a score of 80 (good category); Engineering 50 ability (less category), Technology ability with a score of 60 (sufficient category) and Mathematical ability with a score of 65 (sufficient category). Entrepreneurial economic analysis with a score of 75 (sufficient category) and 50% of participants get a profit of 30% from catfish production within 3 months.

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IMPLEMENTING STEM APPROACH IN KINDERGARDEN

Education and Technologies Journal ◽

10.26883/2010.211.3254 ◽

2021 ◽

Vol 12 (1) ◽

pp. 236-243

Author(s):

Ivelina Velcheva ◽

◽

Kosta Garov ◽

Keyword(s):

Learning Process ◽

Real Life ◽

Learning By Doing ◽

Digital Tools ◽

Research Approach ◽

Stem Learning ◽

Knowledge And Skills ◽

Science Technology ◽

And Mathematics ◽

Kindergarten Curriculum

The following work is devoted to the description of an innovative approach to kindergarten learning through the application of the methods of science, technology, engineering and mathematics, better known as STEM learning. The aim of the work is to increase popularity of the approach and stimulate teachers to implement it more often in the learning process. STEM increases children’s knowledge and skills, thanks to the interdisciplinarity, research approach, learning by playing, learning by doing, project-based and problem-based learning and the opportunity for touching to real-life situations. This paper addresses the main principles of STEM and the possibilities for realization different STEM situations, based on the kindergarten curriculum. Different digital tools are described, like programmable toys and devices and LEGO constructors. Various ideas for conducting experiments are presented, too. They are useful for increasing children’s motivation and interest in the approach. An example version of a plan for work on a STEM project is proposed, which includes the steps for its implementation and which is adapted to the expected learning results in the kindergarten.

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Analysis of the needs of science, technology, engineering and mathematics (STEM) learning instruments on the derivative topic

Journal of Physics Conference Series ◽

10.1088/1742-6596/1460/1/012012 ◽

2020 ◽

Vol 1460 ◽

pp. 012012

Author(s):

R Husna ◽

R Johar ◽

Usman

Keyword(s):

Stem Learning ◽

Science Technology ◽

And Mathematics

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Representation of Industry in Introductory Biology Textbooks: A Missed Opportunity to Advance STEM Learning

CBE—Life Sciences Education ◽

10.1187/cbe.17-03-0057 ◽

2018 ◽

Vol 17 (4) ◽

pp. ar61 ◽

Cited By ~ 2

Author(s):

Sharotka M. Simon ◽

Helen Meldrum ◽

Eric Ndung’u ◽

Fred D. Ledley

Keyword(s):

Text Analysis ◽

Business Practice ◽

Business Practices ◽

Stem Learning ◽

Introductory Biology ◽

Undergraduate Biology ◽

Biology Textbooks ◽

Science Technology ◽

And Mathematics ◽

Missed Opportunity

The majority of students who enroll in undergraduate biology courses will eventually be employed in non-STEM (science, technology, engineering, and mathematics) business occupations. This work explores how representations of industry in undergraduate biology textbooks could impact STEM learning for these students and their ability to apply this learning in their chosen work. We used text analysis to identify passages with references to industry in 29 textbooks. Each passage was categorized for relevance to health or environment, for implied positive or negative connotations, and for descriptions of synergy or conflict between science and industry. We found few passages describing applications of STEM learning in non-STEM business occupations and a paucity of content to support context-based learning for students aiming at business careers. A significant number of passages embodied negative connotations regarding industry. Notable passages highlighted irregular or fraudulent business practices or included simplistic caricatures of business practice. We discuss how the representation of industry in these textbooks may impact student engagement, context-based learning, the ability of students to critically apply STEM learning in industry or business occupations, and heuristics that guide intuitive perceptions about the intersection between science and industry.

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Computational Thinking in K–12

Educational Researcher ◽

10.3102/0013189x12463051 ◽

2013 ◽

Vol 42 (1) ◽

pp. 38-43 ◽

Cited By ~ 637

Author(s):

Shuchi Grover ◽

Roy Pea

Keyword(s):

Computational Thinking ◽

Stem Learning ◽

Policy Makers ◽

Academic Literature ◽

Current State ◽

Science Technology ◽

And Mathematics ◽

K 12

Jeannette Wing’s influential article on computational thinking 6 years ago argued for adding this new competency to every child’s analytical ability as a vital ingredient of science, technology, engineering, and mathematics (STEM) learning. What is computational thinking? Why did this article resonate with so many and serve as a rallying cry for educators, education researchers, and policy makers? How have they interpreted Wing’s definition, and what advances have been made since Wing’s article was published? This article frames the current state of discourse on computational thinking in K–12 education by examining mostly recently published academic literature that uses Wing’s article as a springboard, identifies gaps in research, and articulates priorities for future inquiries.

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Expanding the Boundaries of Informal Education Programs: An Investigation of the Role of Pre and Post-education Program Experiences and Dispositions on Youth STEM Learning

Frontiers in Education ◽

10.3389/feduc.2021.672487 ◽

2021 ◽

Vol 6 ◽

Author(s):

John H. Falk ◽

David D. Meier

Keyword(s):

Outdoor Education ◽

Informal Education ◽

Stem Learning ◽

Education Programs ◽

Stem Programs ◽

Science Technology ◽

How People Learn ◽

And Mathematics ◽

Almost All

For generations educators have been supporting children and youth’s science, technology, engineering, and mathematics (STEM) learning through informal education programming. Such programming includes a wide variety of outdoor education programs, camp programs, and increasingly targeted STEM programs run afterschool, on weekends, and over the summer months. However, despite the positive impacts these programs have, few would argue that these programs could not be improved or be designed to better meet the needs of a broader and more diverse population of learners. Arguably, one major flaw in how most educators have approached the design and improvement of these programs—a flaw that permeates almost all informal STEM education efforts–is that either explicitly or implicitly, the focus of educators has been exclusively on what happens during the program itself. Superficially this seems reasonable. After all, the time children/youth are within the temporal and physical boundaries of the program, class, or museum is the time when educators have maximal control over events. However, given what is known about how people learn (National Academies of Sciences, 2018), we argue that this long-standing approach needs to be reconsidered.

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A Study of Disposition, Engagement, Efficacy, and Vitality of Teachers in Designing Science, Technology, Engineering, and Mathematics Education

Frontiers in Psychology ◽

10.3389/fpsyg.2021.661631 ◽

2021 ◽

Vol 12 ◽

Author(s):

Pei-Yi Lin ◽

Ching Sing Chai ◽

Morris Siu-Yung Jong

Keyword(s):

Secondary Teachers ◽

Stem Education ◽

Structural Equation ◽

Learning Activities ◽

Equation Modeling ◽

Positive Perception ◽

Lesson Design ◽

Science Technology ◽

E Learning ◽

And Mathematics

This study proposes and tests a theoretical model of how perceptions of disposition, engagement, and efficacy of teachers for science, technology, engineering, and mathematics (STEM) e-learning can predict their sense of vitality when they designed STEM education. Upon the proposition, we developed and validated an instrument for examining the relationships between these variables. The participants were 122 secondary teachers of STEM education from Hong Kong. The instrument included four design aspects as follows: (i) disposition, (ii) lesson design engagement, (iii) efficacy for designing STEM e-learning, and (iv) vitality of teachers after attending a series of STEM professional development activities. To analyze the relationships among the variables, partial least squares structural equation modeling was employed. The disposition of teachers predicted lesson design engagement and both of these factors, in turn, predicted efficacy for designing STEM e-learning. In other words, if teachers have a high proposition toward designing learning activities, their engagement in the lesson design process may enhance their capacities in designing and implementing such activities. Also, the disposition of teachers and lesson design engagement predicted their vitality, revealing that well-suited STEM teachers should not only be able to design a STEM curriculum but also have a positive perception of STEM education.

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