Abstract
Improving the K-12 education system in the USA is one of the wicked problems of the twenty-first century. For all the discussion around STEM (Science, Technology, Engineering, and Mathematics), “Every Student Succeeds,” and other countless initiatives and interventions, it seems reasonable to ask—why are K-12 school systems still starved for lasting, meaningful change? While education researchers and evaluators have certainly brought rigor to understanding intervention impacts and outcomes on a student and teacher level, these studies often do not directly account for the social science-based context that surrounds interventions. In this paper, we present an approach for modeling school settings using causal loop diagrams and accompanying stochastic simulations to better understand schools’ capacity for intervention. We present initial evidence to support the claim that the modeling process and the resultant models can aid in the design of quality, school-compatible interventions by improving understanding of the ecosystems in which educational interventions operate. This work attempts to shine light on the relationship between a K-12 school environment and an intervention, paying respect to the fact that the two cannot be cleanly decoupled. We also present a framework that can be adopted by other intervention teams in the future to better understand the settings in which they are operating.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Lyon, A. R., Frazier, S. L., Mehta, T., Atkins, M. S., & Weisbach, J. (2011). Easier said than done: Intervention sustainability in an urban after-school program. Administration and Policy in Mental Health and Mental Health Services Research, 38(6), 504–517.
Penuel, W. R., & Fishman, B. J. (2012). Large-scale science education intervention research we can use. Journal of Research in Science Teaching, 49(3), 281–304.
National Science Foundation. (2018). Discovery research PreK-12. Available from: https://www.nsf.gov/funding/pgm_summ.jsp?pims_id=500047
Fishman, B. J., Penuel, W. R., Allen, A.-R., Cheng, B. H., & Sabelli, N. (2013). Design-based implementation research: An emerging model for transforming the relationship of research and practice. National Society for the Study of Education, 112(2), 136–156.
Penuel, W. R., & Fishman, B. J. (2017). Design based implementation research. Cited February 10, 2017. Retrieved from: http://learndbir.org/
Groff, J. S. (2013). Dynamic systems modeling in educational system design & policy. New Approaches in Educational Research, 2(2), 72–81.
Mital, P., Moore, R. A., & Llewellyn, D. C. (2017). Education system intervention modeling framework. Policy and Complex Systems, 3(2), 72–87.
Magerko, B., Freeman, J., Mcklin, T., Mccoid, S., Jenkins, T., & Livingston, E. (2013). Tackling engagement in computing with computational music remixing. Proceeding of the 44th ACM Technical Symposium on Computer Science Education, ACM
Mahadevan, A., Freeman, J., Magerko, B., & Martinez, J. C. (2015). EarSketch: Teaching computational music remixing in an online Web Audio based learning environment. Web Audio Conference. Citeseer.
Mccoid, S., Freeman, J., Magerko, B., Michaud, C., Jenkins, T., Mcklin, T., et al. (2013). EarSketch: An integrated approach to teaching introductory computer music. Organised Sound, 18(02), 146–160.
Freeman, J., Magerko, B., Mcklin, T., Reilly, M., Permar, J., Summers, C., et al. (2014). Engaging underrepresented groups in high school introductory computing through computational remixing with EarSketch. Proceedings of the 45th ACM Technical Symposium on Computer Science Education, ACM.
Astrachan, O., Barnes, T., Garcia, D. D., Paul, J., Simon, B., & Snyder, L. (2011). CS principles: Piloting a new course at national scale. Proceedings of the 42nd ACM Technical Symposium on Computer Science Education, ACM.
Astrachan, O., & Briggs, A. (2012). The CS principles project. ACM Inroads, 3(2), 38–42.
Collegeboard. (2016). AP computer science principles: Course and exam description. https://apcentral.collegeboard.org/pdf/ap-computer-science-principles-course-and-exam-description.pdf.
Llewellyn, D. C., Usselman, M., Edwards, D., Moore, R. A., & Mital, P. (2013). Analyzing K-12 education as a complex system. 120th ASEE Annual Conference & Exposition, Atlanta, GA.
Mital, P. (2015). A modeling framework for analyzing the education system as a complex system. H. Milton School of Industrial and Systems Engineering, Georgia Institute of Technology.
Mital, P., Moore, R., & Llewellyn, D. (2014). Analyzing K-12 education as a complex system. Procedia Computer Science, 28, 370–379.
Blumenfeld, P., Fishman, B. J., Krajcik, J., Marx, R. W., & Soloway, E. (2000). Creating usable innovations in systemic reform: Scaling up technology-embedded project-based science in urban schools. Educational Psychologist, 35(3), 149–164.
Helms, M., Moore, R., Edwards, D., & Freeman, J. (2016). STEAM-based interventions: Why student engagement is only part of the story. In Research on equity and sustained participation in engineering, computing, and technology (RESPECT). New York: IEEE.
Moore, R. A., Helms, M., & Freeman, J. (2017). STEAM-based interventions in computer science: Understanding feedback loops in the classroom. Columbus, OH: American Society for Engineering Education.
Moore, R. A., Helms, M., & Usselman, M. (2018). effective design-based implementation research using complex systems modeling. American Society for Engineering Education Annual Conference. Salt Lake City, UT.
Morris, M. D. (1991). Factorial sampling plans for preliminary computational experiments. Technometrics, 33(2), 161–174.
Acknowledgements
EarSketch receives funding from the National Science Foundation (CNS #1138469, DRL #1417835, DUE #1504293, and DRL #1612644), the Scott Hudgens Family Foundation, the Arthur M. Blank Family Foundation, and the Google Inc. Fund of Tides Foundation. We would like to acknowledge the other members of the EarSketch team who have provided input on these models, including Jason Freeman, Doug Edwards, Tom McKlin, Brian Magerko, Sabrina Grossman, Anna Xambó, Léa Ikkache, and Morgan Miller, as well as Drs. Marion Usselman and Donna Llewellyn for their influence in this work. EarSketch is available online at http://earsketch.gatech.edu.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2020 Springer Nature Switzerland AG
About this paper
Cite this paper
Moore, R.A., Helms, M. (2020). Modeling Schools’ Capacity for Lasting Change: A Causal Loop and Simulation-Based Approach. In: Carmichael, T., Yang, Z. (eds) Proceedings of the 2018 Conference of the Computational Social Science Society of the Americas. CSSSA 2018. Springer Proceedings in Complexity. Springer, Cham. https://doi.org/10.1007/978-3-030-35902-7_14
Download citation
DOI: https://doi.org/10.1007/978-3-030-35902-7_14
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-35901-0
Online ISBN: 978-3-030-35902-7
eBook Packages: Mathematics and StatisticsMathematics and Statistics (R0)