Examining the Quality of Technology Implementation in STEM Classrooms: Demonstration of an Evaluative Framework

Parker, Caroline E.; Stylinski, Cathlyn; Bonney, Christina Rhee; Schillaci, Rebecca Seston; McAuliffe, Carla

doi:10.1080/15391523.2015.999640

Cited by 17 publications

(11 citation statements)

References 48 publications

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“…The idea of employing TPACK for the study of STEM education has been proposed and tested in limited contexts. Parker et al investigated science teachers' quality of technology use with reference to the Next Generation Science Standards and found that high-quality use was limited [19]. Yildrim and Sidekli employed the TPACK framework in preservice teacher development by integrating technology in teaching mathematics in the context of STEM education [33].…”

Section: Learning By Designing To Develop Teachers' Tpackmentioning

confidence: 99%

“…Nonetheless, when STEM education is anchored with engineering design challenges, students will encounter authentic engineering problems, which will require them to use ICT as a productive, collaborative, and cognitive tool to help them gather, synthesize, model, and construct the knowledge needed [30]. This could address the problems reported earlier about teachers not using ICT as a cognitive tool to engender 21st century student-centered learning [19,27,28]. In addition, the latest advanced technologies, such as 3D printing, micro-computers, and block-based coding environments afford teachers and students ample opportunities to compute and make functional prototypes [40].…”

Section: Interdisciplinary Stem and Tpackmentioning

confidence: 99%

“…In addition, TPACK and STEM are both crucial to developing students' 21st century capacities [17,43]. Parker et al associated teachers' TPACK with STEM and argued that these two fields of study need to be integrated [19]. While the blend of the two areas involves five elementary forms of knowledge (STEM subject knowledge plus pedagogical knowledge) that will interact in a complex manner, the foregoing argument shows that the concurrent development could be an outcome.…”

Section: Interdisciplinary Stem and Tpackmentioning

confidence: 99%

“…It contributes to the current research on STEM education by drawing on the notion of TPACK as a possible framework to map out the knowledge that the preservice teachers need. While the TPACK framework has been employed in the context of STEM education research [1,19], whether and how it may foster preservice teachers' capacity for ICT integration and STEM education has apparently not been reported. Given preservice teachers' crowded curriculum, a study addressing these two teacher capacities may offer new insights into the restructuring of sustainable teacher education.…”

Section: Introductionmentioning

confidence: 99%

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Indonesian Science, Mathematics, and Engineering Preservice Teachers’ Experiences in STEM-TPACK Design-Based Learning

2020

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This paper presents Indonesian preservice teachers’ experiences in designing a Science Technology Engineering and Mathematics-Technological Pedagogical Content Knowledge (STEM-TPACK) learning website. The framework of TPACK was expanded to include all STEM subjects for the synthesis of the theoretical/design framework. The STEM-TPACK framework is further epitomized as a replicable website to support preservice teachers in designing STEM lesson activities. The framework is also employed to examine preservice teachers’ efficacies and experiences in learning how to design the learning website. Thirty-seven second- and third-year Indonesian preservice teachers from science, mathematics, computer science, and engineering backgrounds formed interdisciplinary groups to design the STEM-TPACK website based on the current secondary school curricula. Data were collected from TPACK-STEM questionnaires, interviews, reflective journals, and observation. The preservice teachers’ efficacy for their STEM-TPACK developed significantly, with large effect sizes, after they co-designed the websites. The results also indicate that the preservice teachers faced challenges in communicating their discipline-based content knowledge when developing the STEM projects. Contextualizing and connecting their content knowledge with real-world design challenges was also difficult for them. Consequently, the preservice teachers realized that teaching is a complex matter, especially when they need to integrate the different disciplines for STEM education. However, this was viewed in a positive light for professional development. This study implies that preservice teachers may benefit from learning by design, employing the TPACK framework in the social setting of interdisciplinary STEM communities.

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Section: Learning By Designing To Develop Teachers' Tpackmentioning

confidence: 99%

Section: Interdisciplinary Stem and Tpackmentioning

confidence: 99%

Section: Interdisciplinary Stem and Tpackmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Indonesian Science, Mathematics, and Engineering Preservice Teachers’ Experiences in STEM-TPACK Design-Based Learning

2020

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“…The Protocol builds on a published theoretical framework that consists of four dimensions: technology type, science and engineering practices (SEPs), student-centered teaching, and relevance to students' lives (Parker, Stylinski, Bonney, Schillaci & McAuliffe 2015). These dimensions are critical to highquality technology integration, and their inclusion in our observation protocol supports the instrument's content validity.…”

Section: Theoretical Foundation Of the Protocolmentioning

confidence: 99%

Measuring Quality Technology Integration in Science Classrooms

et al. 2019

Self Cite

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Researchers, evaluators, and practitioners need tools to distinguish between applications of technology that support, enhance, and transform classroom instruction and those that are ineffective or even deleterious. Here we present a new classroom observation protocol designed specifically to capture the quality of technology use to support science inquiry in high school science classrooms. We iteratively developed and piloted the Technology Observation Protocol for Science (TOP-Science), building directly on our published framework for quality technology integration. Development included determining content and face validity, as well as the calculation of reliability estimates across a broad range of high school science classrooms. The resulting protocol focuses on the integration of technology in classrooms on three dimensions: science and engineering practices, student-centered teaching, and contextualization. It uses both quantitative coding and written descriptions of evidence for each code; both are synthesized in a multi-dimensional measure of quality. Data are collected and evaluated from the perspective of the teacher's intentions, actions, and reflections on these actions. This protocol fills an important gap in understanding technology's role in teaching and learning by doing more than monitoring technology's presence or absence, and considering its integration in the context of the Next Generation Science Standards science and engineering practices. Its applications include research, evaluation, and potentially peer evaluation.

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Factors that foster and deter STEM professional development among teachers

et al. 2020

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The present study seeks to identify teachers' perceptions regarding STEM teaching professional development and to identify the factors that facilitate or hinder the success of teachers' professional development. The participants of the study were 35 teachers. A qualitative approach was used for data collection by conducting semistructured interviews with 11 teachers out of 35. All the participants were involved in the three focus group sessions. The findings of the study revealed that teachers have various perceptions toward the STEM professional development based on their experience, knowledge, and skills. Moreover, the study revealed different factors influencing STEM professional development among teachers including personal characteristics and internal factors including attitudes and beliefs toward STEM professional development activities, and teachers' capacity. Also, external factors such as design of the training program, availability of training material, and timing of training. The findings of the study could benefit the decision‐makers to be aware about these factors that influence professional development and the teachers' needs.

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Examining the Quality of Technology Implementation in STEM Classrooms: Demonstration of an Evaluative Framework

Cited by 17 publications

References 48 publications

Indonesian Science, Mathematics, and Engineering Preservice Teachers’ Experiences in STEM-TPACK Design-Based Learning

Indonesian Science, Mathematics, and Engineering Preservice Teachers’ Experiences in STEM-TPACK Design-Based Learning

Measuring Quality Technology Integration in Science Classrooms

Factors that foster and deter STEM professional development among teachers

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