BOARD # 75: One Teacher’s Experience Adapting an Innovative, Flexible Computer Vision Curriculum in a Middle School Science Classroom

Christine Wusylko; Rachel Still; Pavlo Antonenko; Brian Abramowitz; Jeremy A. Magruder Waisome; Victor Perez; STEPHANIE KILLINGSWORTH

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Conference: 2025 ASEE Annual Conference & Exposition
Location: Montreal, Quebec, Canada
Publication Date: June 22, 2025
Start Date: June 22, 2025
End Date: August 15, 2025
Conference Session: Computers in Education Division (COED) Poster Session (Track 1.A)
Tagged Division: Computers in Education Division (COED)
Page Count: 12
Permanent URL: https://peer.asee.org/55891

Paper Authors

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Christine Wusylko University of Florida

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Christine a postdoctoral fellow at the University of Florida. She draws on over 10 years of experience teaching science and technology across grade levels K-16, to produce useful and usable knowledge, which is both driven by problems of practice and is theoretically grounded. Her research and development program is centered on helping young people develop AI and STEM literacy in authentic learning environments.

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Rachel Still University of Florida

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Pavlo Antonenko

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Pavlo "Pasha" Antonenko is an Associate Professor of Educational Technology at the University of Florida. His interests focus on the design of technology-enhanced learning environments and rigorous mixed-method research on the effective conditions for tec

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Brian Abramowitz University of Florida

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Brian Abramowitz is a coordinator for the Scientist in Every Florida School program at the University of Florida. His research interests center around the implementation of AI in K-12 classrooms.

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Jeremy A. Magruder Waisome University of Florida orcid.org/0000-0002-8710-2637

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Dr. Jeremy A. Magruder Waisome is the Thomas O. Hunter Rising Star Assistant Professor in the Engineering Education Department at the University of Florida (UF). Her research focuses on self-efficacy and critical mentorship in engineering and computing. She is passionate about broadening participation and leveraging evidence-based approaches to improve the engineering education environment for minoritized individuals.

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Victor Perez

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STEPHANIE KILLINGSWORTH University of Florida

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Abstract

Artificial intelligence (AI) is predicted to be one of the most disruptive technologies in the 21st century (Păvăloaia & Necula, 2023), and to prepare all young people to live and work in an AI infused world, many are calling on teaching CS and AI across grade bands (Committee on STEM Education, 2018). However, this presents many challenges particularly in supporting teachers to integrate concepts that they were not taught in their preservice education (Gatlin, 2023) or don’t have clear connections to K-12 core standards. Further, most AI educational interventions utilize LLMs or chatbots. Computer vision is an underexplored, underutilized, and accessible way to introduce young people to CS and AI. To help support teachers to integrate CS and AI into their instruction, our interdisciplinary team of paleontologists, natural history museum educators, computer science engineers, and educational technology researchers designed and developed an innovative, flexible computer vision curriculum for science teachers. The curriculum called [TITLE] is funded by [blinded for review; award number] and blends CS and paleontology as middle school students build and evaluate their own computer vision model used to classify fossil shark teeth.The curriculum consists of five, flexible modules aligned with national and [STATE] science standards. These modules include an introduction to AI, classifying shark teeth and data, training and evaluating machine learning models, identifying bias in datasets, and building a machine learning model. Teachers choose whether to teach these modules in sequence or in isolation, and we encourage teachers to change and adapt these modules to their own teaching styles and students’ learning needs. [TITLE] is implemented as a three year project, and is currently in year three of implementation. To date, we have partnered with 57 teachers, 597 students, and 47 schools. In this paper, we showcase one 7th grade science teacher and describe the implementation choices and changes she made for her own classroom and students’ needs. The purpose of this paper is to explore how one teacher adapted this curriculum to her own classroom, and describe successes and challenges which can be applied to others wishing to design and develop similar curricula. The data we report on include teacher reflections, the changes she made to the modules, researcher observations of implementation, student achievement pre and post tests, document analysis of student work, and students’ science related attitudes before and after the modules. This teacher used the curriculum at the beginning of Fall 2024 to teach the Nature of Science standards. She taught one module per day, in sequence and chose to emphasize data science, curation, and bias. As one example, this teacher was very intentional about exploring and comparing the quality of data curated by citizen scientists and scientific institutions, and helping students understand how data quality influenced their computer vision model. When creating their own computer vision learning models, students recognized that “clear images” and “many images” were needed for accurate models. Many students recognized that AI models were only as good as the data used to build the model, with one student saying AI may have “trouble generating answers for people. If you give limited answers or bad pictures of descriptions.” Students' achievement and science related attitudes are currently being assessed and analyzed, and more details will be shared during the full paper. While curricular interventions using chatbots and LLMs have a growing literature base, curricula for young people on building and using computer vision models is sparse. A more robust description on our innovative computer vision curriculum, the curriculum modifications made by the teacher, data analysis, results and implications will be given in the full paper and the presentation.

Citation
Format

Wusylko, C., & Still, R., & Antonenko, P., & Abramowitz, B., & Waisome, J. A. M., & Perez, V., & KILLINGSWORTH, S. (2025, June), BOARD # 75: One Teacher’s Experience Adapting an Innovative, Flexible Computer Vision Curriculum in a Middle School Science Classroom Paper presented at 2025 ASEE Annual Conference & Exposition , Montreal, Quebec, Canada . https://peer.asee.org/55891

TY  - CPAPER
AB  - Artificial intelligence (AI) is predicted to be one of the most disruptive technologies in the 21st century (Păvăloaia &amp;amp; Necula, 2023), and to prepare all young people to live and work in an AI infused world, many are calling on teaching CS and AI across grade bands (Committee on STEM Education, 2018). However, this presents many challenges particularly in supporting teachers to integrate concepts that they were not taught in their preservice education (Gatlin, 2023) or don’t have clear connections to K-12 core standards. Further, most AI educational interventions utilize LLMs or chatbots. Computer vision is an underexplored, underutilized, and accessible way to introduce young people to CS and AI.
To help support teachers to integrate CS and AI into their instruction, our interdisciplinary team of paleontologists, natural history museum educators, computer science engineers, and educational technology researchers designed and developed an innovative, flexible computer vision curriculum for science teachers. The curriculum called [TITLE] is funded by [blinded for review; award number] and blends CS and paleontology as middle school students build and evaluate their own computer vision model used to classify fossil shark teeth.The curriculum consists of five, flexible modules aligned with national and [STATE] science standards. These modules include an introduction to AI, classifying shark teeth and data, training and evaluating machine learning models, identifying bias in datasets, and building a machine learning model. Teachers choose whether to teach these modules in sequence or in isolation, and we encourage teachers to change and adapt these modules to their own teaching styles and students’ learning needs.
	[TITLE] is implemented as a three year project, and is currently in year three of implementation. To date, we have partnered with 57 teachers, 597 students, and 47 schools. In this paper, we showcase one 7th grade science teacher and describe the implementation choices and changes she made for her own classroom and students’ needs. The purpose of this paper is to explore how one teacher adapted this curriculum to her own classroom, and describe successes and challenges which can be applied to others wishing to design and develop similar curricula. The data we report on include teacher reflections, the changes she made to the modules, researcher observations of implementation, student achievement pre and post tests, document analysis of student work, and students’ science related attitudes before and after the modules.
	This teacher used the curriculum at the beginning of Fall 2024 to teach the Nature of Science standards. She taught one module per day, in sequence and chose to emphasize data science, curation, and bias. As one example, this teacher was very intentional about exploring and comparing the quality of data curated by citizen scientists and scientific institutions, and helping students understand how data quality influenced their computer vision model. When creating their own computer vision learning models, students recognized that “clear images” and “many images” were needed for accurate models. Many students recognized that AI models were only as good as the data used to build the model, with one student saying AI may have “trouble generating answers for people. If you give limited answers or bad pictures of descriptions.” Students&#39; achievement and science related attitudes are currently being assessed and analyzed, and more details will be shared during the full paper.
	While curricular interventions using chatbots and LLMs have a growing literature base, curricula for young people on building and using computer vision models is sparse. A more robust description on our innovative computer vision curriculum, the curriculum modifications made by the teacher, data analysis, results and implications will be given in the full paper and the presentation.
AU  - Christine Wusylko
AU  - Rachel Still
AU  - Pavlo Antonenko
AU  - Brian Abramowitz
AU  - Jeremy A. Magruder Waisome
AU  - Victor Perez
AU  - STEPHANIE KILLINGSWORTH
CY  - Montreal, Quebec, Canada 
DA  - 2025/06/22
PB  - ASEE Conferences
TI  - BOARD # 75: One Teacher’s Experience Adapting an Innovative, Flexible Computer Vision Curriculum in a Middle School Science Classroom
UR  - https://peer.asee.org/55891
ER  -