Skip to main content
Fachgebiete
Automobil + Motoren Bauwesen + Immobilien Business IT + Informatik Elektrotechnik + Elektronik Energie + Nachhaltigkeit Finance + Banking Management + Führung Marketing + Vertrieb Maschinenbau + Werkstoffe Versicherung + Risiko
DE
EN
Bücher
Zeitschriften
Themenseiten
Organisationspsychologie Projektmanagement Marketing Smart Manufacturing
Weitere Formate
Podcasts Webinare Technik Webinare Wirtschaft Kongresse Veranstaltungskalender Awards
Jetzt Einzelzugang starten
Zugang für Unternehmen
Referenzkunden
SLX-Digitalkonferenz: Zukunftswerkstatt 2024

Mehr Umsatz mit Top-Kontakten

Am 7. Mai erfahren Sie, wie Vertriebsteams Leadgenerierung, Leadnurturing und Leadstrategien effizient steuern können.
Erweiterte Suche
Anmelden
nach oben
Journal of Science Education and Technology
Erschienen in: Journal of Science Education and Technology 2/2021

15.09.2020

Combining Machine Learning and Qualitative Methods to Elaborate Students’ Ideas About the Generality of their Model-Based Explanations

verfasst von: Joshua M. Rosenberg, Christina Krist

Erschienen in: Journal of Science Education and Technology | Ausgabe 2/2021

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config
loading …

Abstract

Assessing students’ participation in science practices presents several challenges, especially when aiming to differentiate meaningful (vs. rote) forms of participation. In this study, we sought to use machine learning (ML) for a novel purpose in science assessment: developing a construct map for students’ consideration of generality, a key epistemic understanding that undergirds meaningful participation in knowledge-building practices. We report on our efforts to assess the nature of 845 students’ ideas about the generality of their model-based explanations through the combination of an embedded written assessment and a novel data analytic approach that combines unsupervised and supervised machine learning methods and human-driven, interpretive coding. We demonstrate how unsupervised machine learning methods, when coupled with qualitative, interpretive coding, were used to revise our construct map for generality in a way that allowed for a more nuanced evaluation that was closely tied to empirical patterns in the data. We also explored the application of the construct map as a framework for coding used as a part of supervised machine learning methods, finding that it demonstrates some viability for use in future analyses. We discuss implications for the assessment of students’ meaningful participation in science practices in terms of their considerations of generality, the role of unsupervised methods in science assessment, and combining machine learning and human-driven approach for understanding students’ complex involvement in science practices.
Vorheriger Artikel Using Machine Learning to Score Multi-Dimensional Assessments of Chemistry and Physics
Nächster Artikel Correction to: Combining Machine Learning and Qualitative Methods to Elaborate Students’ Ideas About the Generality of their Model-Based Explanations

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

  • über 102.000 Bücher
  • über 537 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Maschinenbau + Werkstoffe
  • Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 390 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Maschinenbau + Werkstoffe




 

Jetzt Wissensvorsprung sichern!

Jetzt informieren
Anhänge
Nur mit Berechtigung zugänglich
Fußnoten
1
The approach we used has been shown to lend greater stability to the k means clustering solution, which can be influenced by the starting points for the algorithm. This approach uses the results from hierarchical clustering as the starting points for k means (Bergman and El-Khouri 1999). In our technique, what is being clustered is the vector space representation of each document: in other words, the raw data for the clustering procedure is a row in a table, with values ranging from zero to the maximum number of times any term appears across all documents. The default distance metric for the hierarchical clustering is cosine similarity.
 
2
The R package we created and used (Rosenberg and Lishinski 2018) is available to anyone via GitHub for anyone seeking to carry out a similar two-step cluster analysis in R (R Core Team 2019); Sherin (2020) provides a very similar package in python.
 
3
LOOCV is equivalent to k folds cross-validation when k is equal to the number of observations in the dataset.
 
Literatur
Anderson, D. J., Rowley, B., Stegenga, S., Irvin, P. S., & Rosenberg, J. M. (2020). (advance online publication). Evaluating content-related validity evidence using a text-based, machine learning procedure. Educational Measurement: Issues and Practice. https://​doi.​org/​10.​1111/​emip.​12314.
Beggrow, E. P., Ha, M., Nehm, R. H., Pearl, D., & Boone, W. J. (2014). Assessing scientific practices using machine-learning methods: how closely do they match clinical interview performance? Journal of Science Education and Technology, 23(1), 160–182.
Bergman, L. R., & El-Khouri, B. M. (1999). Studying individual patterns of development using I-states as objects analysis (ISOA). Biometrical Journal: Journal of Mathematical Methods in Biosciences, 41(6), 753–770.
Berland, L., & Crucet, K. (2016). Epistemological trade-offs: accounting for context when evaluating epistemological sophistication of student engagement in scientific practices. Science Education, 100(1), 5–29.
Berland, L. K., Schwarz, C. V., Krist, C., Kenyon, L., Lo, A. S., & Reiser, B. J. (2016). Epistemologies in practice: making scientific practices meaningful for students. Journal of Research in Science Teaching, 53(7), 1082–1112.
Bouchet-Valat, M. (2014). SnowballC: snowball stemmers based on the C libstemmer UTF-8 library. R package version 0.5, 1.
Burrows, S., Gurevych, I., & Stein, B. (2015). The eras and trends of automatic short answer grading. International Journal of Artificial Intelligence in Education, 25(1), 60–117.
Chinn, C. A., & Malhotra, B. A. (2002). Epistemologically authentic inquiry in schools: a theoretical framework for evaluating inquiry tasks. Science Education, 86(2), 175–218.
Cohen, J. (1968). Weighted kappa: nominal scale agreement provision for scaled disagreement or partial credit. Psychological Bulletin, 70(4), 213–220.
DeBarger, A. H., Penuel, W. R., & Harris, C. J. (2013). Designing NGSS assessments to evaluate the efficacy of curriculum interventions. Invitational Research Symposium on Science Assessment. Washington, DC: K-12 Center at ETS. Retrieved from http://​www.​k12center.​ org/rsc/pdf/debarger-penuel-harris.pdf.
Dickes, A. C., Sengupta, P., Farris, A. V., & Basu, S. (2016). Development of mechanistic reasoning and multilevel explanations of ecology in third grade using agent-based models. Science Education, 100(4), 734–776.
Duncan, R. G., & Tseng, K. A. (2011). Designing project-based instruction to foster generative and mechanistic understandings in genetics. Science Education, 95(1), 21–56.
Ford, M. J. (2015). Educational implications of choosing “practice” to describe science in the next generation science standards. Science Education, 99(6), 1041–1048.
Ford, M. J., & Forman, E. A. (2006). Chapter 1: redefining disciplinary learning in classroom contexts. Review of Research in Education, 30(1), 1–32.
Fram, S. M. (2013). The constant comparative analysis method outside of grounded theory. The Qualitative Report, 18, 1.
Gerard, L. F., & Linn, M. C. (2016). Using automated scores of student essays to support teacher guidance in classroom inquiry. Journal of Science Teacher Education, 27(1), 111–129.
Giere, R. N. (1988). Explaining science: a cognitive approach. Chicago: University of Chicago Press.
Gobert, J. D., Sao Pedro, M., Raziuddin, J., & Baker, R. S. (2013). From log files to assessment metrics: measuring students’ science inquiry skills using educational data mining. The Journal of the Learning Sciences, 22(4), 521–563.
Gobert, J. D., Baker, R. S., & Wixon, M. B. (2015). Operationalizing and detecting disengagement within online science microworlds. Educational Psychologist, 50(1), 43–57.
Gotwals, A. W., & Songer, N. B. (2013). Validity evidence for learning progression-based assessment items that fuse core disciplinary ideas and science practices. Journal of Research in Science Teaching, 50(5), 597–626.
Greene, D., Hoffmann, A. L., & Stark, L. (2019). Better, nicer, clearer, fairer: a critical assessment of the movement for ethical artificial intelligence and machine learning, Hawaii international conference on system sciences (HICSS). HI: Maui.
Harris, C. J., Krajcik, J. S., Pellegrino, J. W., & DeBarger, A. H. (2019). Designing knowledge-in-use assessments to promote deeper learning. Educational Measurement: Issues and Practice, 38(2), 53–67.
Hastie, T., Tibshirani, R., & Friedman, J. (2009). The elements of statistical learning (2nd ed.). Springer.
Haudek, K. C., Osborne, J., & Wilson, C. D. (2019). Using automated analysis to assess middle school students’ competence with scientific argumentation. In National Conference on Measurement in Education. Toronto: NCME.
Helleputte, T. (2017). LiblineaR: linear predictive models based on the Liblinear C/C++ library. R package version, 2, 10–18.
Hirschberg, J., & Manning, C. D. (2015). Advances in natural language processing. Science, 349(6245), 261–266.
Inkinen, J., Klager, C., Juuti, K., Schneider, B., Salmela-Aro, K., Krajcik, J., & Lavonen, J. (2020). High school students’ situational engagement associated with scientific practices in designed science learning situations. Science Education, 104(4), 667-692.
Jiménez-Aleixandre, M. P., Bugallo Rodríguez, A., & Duschl, R. A. (2000). “Doing the lesson” or “doing science”: argument in high school genetics. Science Education, 84(6), 757–792.
Kolodner, J. L. (Ed.). (1993). Case-based learning. Dordrecht: Kluwer Academic Publishers.
Krajcik, J., McNeill, K. L., & Reiser, B. J. (2008). Learning-goals-driven design model: developing curriculum materials that align with national standards and incorporate project-based pedagogy. Science Education, 92(1), 1–32.
Krajcik, J., Reiser, B., Sutherland, L., & Fortus, D. (2011). IQWST: investigating and questioning our world through science and technology (middle school science curriculum materials). Greenwich: Sangari Active Science.
Kuhn, D. (2000). Metacognitive development. Current Directions in Psychological Science, 9(5), 178–181.
Landis, J. R., & Koch, G. G. (1977). An application of hierarchical kappa-type statistics in the assessment of majority agreement among multiple observers. Biometrics, 33(2), 363–374.
Laverty, J. T., Underwood, S. M., Matz, R. L., Posey, L. A., Carmel, J. H., Caballero, M. D., Fata-Hartley, C. L., Ebert-May, D., Jardeleza, S. E., & Cooper, M. M. (2016). Characterizing college science assessments: the three-dimensional learning assessment protocol. PLoS One, 11(9), e0162333.
Lead States, N. G. S. S. (2013). Next generation science standards: for states, by states. Washington, DC: National Academies Press.
Lehrer, R., & Schauble, L. (2006). Cultivating model-based reasoning in science education. In R. K. Sawyer (Ed.), The Cambridge handbook of the learning sciences (p. 371–387). Cambridge University Press.
Lehrer, R. & Schauble, L. (2015). Developing scientific thinking. In L. S. Liben & U. Müller (Eds.), Cognitive processes. Handbook of child psychology and developmental science (Vol. 2, 7th ed., pp. 671-174). Hoboken, NJ: Wiley.
Lehrer, R., Schauble, Leona, & Petrosino, A. J. (2001). Reconsidering the role of experiment in science education. Designing for science: implications from everyday, classroom, and professional settings, 251–278.
Manz, E. (2012). Understanding the codevelopment of modeling practice and ecological knowledge. Science Education, 96(6), 1071–1105.
Manz, E. (2015). Representing student argumentation as functionally emergent from scientific activity. Review of Educational Research, 85(4), 553–590.
McNeill, K., Lizotte, D. J., Krajcik, J., & Marx, R. W. (2006). Supporting students’ construction of scientific explanations by fading scaffolds in instructional materials. The Journal of the Learning Sciences, 15(2), 153–191.
Morell, L., Collier, T., Black, P., & Wilson, M. (2017). A construct-modeling approach to develop a learning progression of how students understand the structure of matter. Journal of Research in Science Teaching, 54(8), 1024–1048.
National Research Council. (2012). A framework for K-12 science education: practices, crosscutting concepts, and core ideas. Washington, DC: National Academies Press.
Nehm, R. H., Ha, M., & Mayfield, E. (2012). Transforming biology assessment with machine learning: automated scoring of written evolutionary explanations. Journal of Science Education and Technology, 21(1), 183–196.
Passmore, C., Schwarz, C. V., & Mankowski, J. (2017). Developing and using models. In C. V. Schwarz, C. Passmore, & B. J. Reiser (Eds.), Helping students make sense of the world using next generation science and engineering practices (pp. 109–135). Arlington, VA: NSTA Press.
Pei, B., Xing, W., & Lee, H. S. (2019). Using automatic image processing to analyze visual artifacts created by students in scientific argumentation. British Journal of Educational Technology, 50(6), 3391–3404.
Pellegrino, J. W. (2013). Proficiency in science: assessment challenges and opportunities. Science, 340(6130), 320–323.
Penuel, W. R., Turner, M. L., Jacobs, J. K., Van Horne, K., & Sumner, T. (2019). Developing tasks to assess phenomenon-based science learning: challenges and lessons learned from building proximal transfer tasks. Science Education, 103(6), 1367–1395.
Popper, K. R. (1959). The propensity interpretation of probability. The British Journal for the Philosophy of Science, 10(37), 25–42.
Reiser, B. J., Kim, J., Toyama, Y., & Draney, K. (2016). Multi-year growth in mechanistic reasoning across units in biology, chemistry, and physics. Paper presented at NARST, April, 14, 2016.
Ryu, S., & Sandoval, W. A. (2012). Improvements to elementary children’s epistemic understanding from sustained argumentation. Science Education, 96(3), 488–526.
Saldaña, J. (2016). The coding manual for qualitative researchers. Sage.
Sandoval, W. A. (2005). Understanding students’ practical epistemologies and their influence on learning through inquiry. Science Education, 89(4), 634–656.
Sandoval, W. A., & Millwood, K. A. (2005). The quality of students’ use of evidence in written scientific explanations. Cognition and Instruction, 23(1), 23–55.
Schwarz, C. V., Reiser, B. J., Davis, E. A., Kenyon, L. O., Archer, A., Fortus, D., & Krajcik, J. (2009). Developing a learning progression for scientific modeling: making scientific modeling accessible and meaningful for learners. Journal of Research in Science Teaching, 46(6), 632–654.
Schwarz, C. V., Passmore, C., & Reiser, B. J. (2017). Helping students make sense of the world using next generation science and engineering practices. Arlington, VA: NSTA Press.
Shaffer, D. W. (2017). Quantitative ethnography. Madison: Cathcart Press.
Sherin, B. (2013). A computational study of commonsense science: an exploration in the automated analysis of clinical interview data. The Journal of the Learning Sciences, 22(4), 600–638.
Shin, N., Stevens, S. Y., & Krajcik, J. (2010). Tracking student learning over time using construct-centred design. In Using Analytical Frameworks for Classroom Research (pp. 56–76). Routledge.
Tabak, I., & Reiser, B.J. (1999). Steering the course of dialogue in inquiry-based science. Paper presented at the Annual Meeting of the American Educational Research Association Montreal, Canada.
Thagard, P. R. (1978). The best explanation: criteria for theory choice. Journal of Philosophy, 75(2), 76–92.
Wiley, J., Hastings, P., Blaum, D., Jaeger, A. J., Hughes, S., Wallace, P., Griffin, T. D., & Britt, M. A. (2017). Different approaches to assessing the quality of explanations following a multiple-document inquiry activity in science. International Journal of Artificial Intelligence in Education, 27(4), 758–790.
Wilson, M. (2004). Constructing measures: An item response modeling approach. London: Routledge.
Zangori, L., Forbes, C. T., & Schwarz, C. V. (2015). Exploring the effect of embedded scaffolding within curricular tasks on third-grade students’ model-based explanations about hydrologic cycling. Science & Education, 24(7–8), 957–981.
Zehner, F., Sälzer, C., & Goldhammer, F. (2016). Automatic coding of short text responses via clustering in educational assessment. Educational and Psychological Measurement, 76(2), 280–303.
Zhai, X., Yin, Y., Pellegrino, J. W., Haudek, K. C., & Shi, L. (2020). Applying machine learning in science assessment: a systematic review. Studies in Science Education, 56(1), 111–151.
Metadaten
Titel
Combining Machine Learning and Qualitative Methods to Elaborate Students’ Ideas About the Generality of their Model-Based Explanations
verfasst von
Joshua M. Rosenberg
Christina Krist
Publikationsdatum
15.09.2020
Verlag
Springer Netherlands
Erschienen in
Journal of Science Education and Technology / Ausgabe 2/2021
Print ISSN: 1059-0145
Elektronische ISSN: 1573-1839
DOI
https://doi.org/10.1007/s10956-020-09862-4

Weitere Artikel der Ausgabe 2/2021

Journal of Science Education and Technology 2/2021 Zur Ausgabe

OriginalPaper

Practices and Theories: How Can Machine Learning Assist in Innovative Assessment Practices in Science Education

OriginalPaper

Relationships between Facial Expressions, Prior Knowledge, and Multiple Representations: a Case of Conceptual Change for Kinematics Instruction

OriginalPaper

Using Machine Learning to Score Multi-Dimensional Assessments of Chemistry and Physics

OriginalPaper

Automated Scoring of Chinese Grades 7–9 Students’ Competence in Interpreting and Arguing from Evidence

Letter

Commentary—Applying Machine Learning in Science Assessment: Opportunity and Challenges

OriginalPaper

On the Validity of Machine Learning-based Next Generation Science Assessments: A Validity Inferential Network

Premium Partner

    Marktübersichten

    Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen. 

    Zur Marktübersicht
    Bildnachweise