Pedagogic Approaches

Katrina Falkner; Judy Sheard

doi:10.1017/9781108654555.016

15 - Pedagogic Approaches

from Systemic Issues

Published online by Cambridge University Press: 15 February 2019

Katrina Falkner and

Judy Sheard

Edited by

Sally A. Fincher and

Anthony V. Robins

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Sally A. Fincher: Affiliation:
University of Kent, Canterbury
Anthony V. Robins: Affiliation:
University of Otago, New Zealand

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Summary

The pedagogic approaches adopted within Computer Science education vary widely, both in terms of the adoption and adaptation of general pedagogic approaches and practices, and the development of pedagogic approaches that are specific to the Computer Science domain. In recent years, there has been an increasing focus on student-centred education approaches within Computer Science, as well as the adoption of technology-rich and technology-driven learning practice and environments. In this Chapter, we provide an brief survey of the development of common pedagogical approaches, and present an overview of the Computer Science scholarship and education research literature addressing the application of pedagogic approaches. We discuss exemplars and case studies of the use of these approaches within the Computer Science context, and the development of new approaches specific to our domain.

Type: Chapter
Information: The Cambridge Handbook of Computing Education Research , pp. 445 - 480

DOI: https://doi.org/10.1017/9781108654555.016 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2019

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References

Abad, C. L. (2008). Learning through creating learning objects: Experiences with a class project in a distributed systems course. In 13th Annual Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘08) (pp. 255–259). New York: ACM.Google Scholar

Armellini, A., & Padilla Rodriguez, B. C. (2016). Are Massive Open Online Courses (MOOCs) pedagogically innovative? In Journal of Interactive Online Learning, 14(1), 17–28.Google Scholar

Aronson, E., Blaney, N., Stephen, C., Sikes, J., & Snapp, M. (1978). The Jigsaw Classroom. Beverly Hills, CA: Sage.Google Scholar

Atkins, M. J. (1993). Theories of learning and multimedia: An overview. Research Papers in Education, 8(2), 251–271.CrossRef Google Scholar

Atapattu, T., & Falkner, K. (2016). A framework for topic generation and labeling from MOOC discussions. In 3rd ACM Conference on Learning@Scale (L@S’2016) (pp. 201–204). New York, NY: ACM.CrossRef Google Scholar

Atapattu, T., Falkner, K., & Falkner, N. (2017). A comprehensive text analysis of lecture slides to generate concept maps. Computers & Education, 115, 96–113.Google Scholar

Barrows, H. S. (1986). A taxonomy of problem-based learning methods. Medical Education, 20, 481–486.Google Scholar

Batista, A. L. F., Connolly, T., & Angotti, J. A. P. (2016). A framework for games-based construction learning: A text-based programming languages approach. In European Conference on Games Based Learning (pp. 815–823). Reading, UK: Academic Conferences International Ltd.Google Scholar

Battistella, P., & Gresse von Wangenheim, C. (2016). Games for teaching computing in higher education – A systematic review. IEEE Technology and Engineering Education, 1(3), 8–30.Google Scholar

Bayne, S., & Ross, J. (2014). The Pedagogy of the Massive Open Online Course: The UK view. York, UK: The Higher Education Academy.Google Scholar

Beck, K. (2002). Test-Driven Development: By Example. Boston, MA: Addison-Wesley.Google Scholar

Beck, L., & Chizhik, A. (2013). Cooperative learning instructional methods for CS1: Design, implementation, and evaluation. Transactions on Computing Education (TOCE), 13(3), 10.Google Scholar

Ben-Ari, M. (1998). Constructivism in computer science education. In Joyce, D., , D. & Impagliazzo, J. (Eds.), 29th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘98) (pp. 257–261). New York: ACM.Google Scholar

Bishop, J. L., & Verleger, M. A. (2013). The flipped classroom: A survey of the research. ASEE National Conference, 30(9), 1–18.Google Scholar

Blanc, R., DeBuhr, L., & Martin, D. (1983). Breaking the attrition cycle: The effects of supplemental instruction on undergraduate performance and attrition. The Journal of Higher Education, 54(1), 80–90.Google Scholar

Blank, D. (2006). Robots make computer science personal. Communications of the ACM, 9(12), 5–27.Google Scholar

Brady, C., Orton, K., Weintrop, D., Anton, G., Rodriguez, S., & Wilensky, U. (2017). All roads lead to computing: making, participatory simulations, and social computing as pathways to computer science. IEEE Transactions on Education, 60(1), 59–66.Google Scholar

Buckley, M., Nordlinger, J., & Subramanian, D. (2008). Socially relevant computing. In 39th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘08) (pp. 347–351). New York: ACM.Google Scholar

Buffardi, K., & Edwards, S. H. (2012). Impacts of teaching test-driven development to novice programmers. International Journal of Information and Computer Science, 1(6), 135–143.Google Scholar

Carbone, A., & Sheard, J. (2002). A studio-based teaching and learning model in IT: What do first year students think? In 7th Annual Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘02) (pp. 213–217) New York: ACM.Google Scholar

Ching, E., Chen, C. T., Chou, C. Y., Deng, Y. C., & Chan, T. W. (2005). A pilot study of computer supported learning by constructing instruction notes and peer expository instruction. In Conference on Computer Support for Collaborative Learning: Learning 2005: The Next 10 Years! (CSCL) (pp. 63–67). Taipei, Taiwan: International Society of the Learning Sciences.Google Scholar

Clarke, D., Clear, T., Fisler, K., Hauswirth, M., Krishnamurthi, S., Politz, J. G., Tirronen, V., & Wrigstad, T. (2014). In-flow peer review. In Clear, A. & Lister, R. (Eds.), Working Group Reports of the 2014 Innovation & Technology in Computer Science Education Conference (ITiCSE-WGR ‘14) (pp. 59–79). New York: ACM.Google Scholar

Collis, B., & Moonen, J. (2005). An On-Going Journey: Technology as a Learning Workbench. Enschede, The Netherlands: University of Twente.Google Scholar

Computing Research Association (2017). Generation CS: Computer Science Undergraduate Enrollments Surge Since 2006. Retrieved from https://cra.org/data/Generation-CS/Google Scholar

Cooper, S., Dann, W., & Pausch, R. (2003). Teaching objects-first in introductory computer science. In 34th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘03) (pp. 191–195). New York: ACM.CrossRef Google Scholar

Corral, J. M. R., Balcells, A. C., Estévez, A. M., Moreno, G. J., & Ramos, M. J. F. (2014). A game-based approach to the teaching of object-oriented programming languages. Computers & Education, 73, 83–92.Google Scholar

Creese, A., & Blackledge, A. (2010). Translanguaging in the bilingual classroom: A pedagogy for learning and teaching? The Modern Language Journal, 94(1), 103–115.Google Scholar

Crescenzi, P., & Nocentini, C. (2007). Fully integrating algorithm visualization into a CS2 course: A two-year experience. In 12th Annual SIGCSE Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘07) (pp. 296–300). New York: ACM.Google Scholar

CSER (2017). A look at IT and Engineering Enrolments in Australia – Updated. Retrieved from: https://blogs.adelaide.edu.au/cser/2017/02/15/a-look-at-it-and-engineering-enrolments-in-australia-updated/Google Scholar

Cunningham, K., Blanchard, S., Ericson, B., & Guzdial, G. (2017). Using tracing and sketching to solve programming problems: Replicating and extending an analysis of what students draw. In 2017 ACM Conference on International Computing Education Research (ICER ‘17) (pp. 164–172). New York: ACM.Google Scholar

Day, J. A., & Foley, J. D. (2006). Evaluating a web lecture intervention in a human–computer interaction course. IEEE Transactions on Education, 49(4), 420–431.Google Scholar

Denny, P., Luxton-Reilly, A., & Hamer, J. (2008). The PeerWise system of student contributed assessment questions. In Simon, & Hamilton, M. (Eds.), 10th conference on Australasian computing education – Volume 78 (ACE ‘08), Vol. 78 (pp. 69–74). Darlinghurst, Australia: Australian Computer Society, Inc.Google Scholar

DesPortes, K., Anupam, A., Pathak, N., & DiSalvo, B. (2016). BitBlox: A redesign of the breadboard. In 15th International Conference on Interaction Design and Children (IDC ‘16) (pp. 255–261). New York: ACM.Google Scholar

Dragon, T., & Dickson, P. E. (2016). Memory diagrams: A consistent approach across concepts and languages. In 47th ACM Technical Symposium on Computing Science Education (SIGCSE ‘16) (pp. 546–551). New York: ACM.Google Scholar

du Boulay, B. (1986). Some difficulties of learning to program. Journal of Educational Computing Research, 2(1), 57–73.Google Scholar

du Boulay, B., O’Shea, T., & Monk, J. (1981). The black box inside the glass box: Presenting computing concepts to novices. International Journal of Man-Machine Studies, 14(3), 237–249.Google Scholar

Duffy, T. M., & Cunningham, D. J. (1996). Constructivism: Implications for the design and delivery of instruction. In Jonassen, D. H. (Ed.), Handbook of Research for Educational Communications and Technology (pp. 170–198). New York: Macmillan.Google Scholar

Earl, S. E. (1986). Staff and peer assessment – Measuring an individual’s contribution to group performance. Assessment & Evaluation in Higher Education, 11(1), 60–69.Google Scholar

Ebert, M., & Ring, M. (2016). A presentation framework for programming in programing lectures. In Global Engineering Education Conference (EDUCON ‘16) (pp. 369–374). New York, NY: IEEE.Google Scholar

Edwards, S. H. (2004). Using software testing to move students from trial-and-error to reflection-in-action. In 35th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘04) (pp. 26–30). New York: ACM.Google Scholar

Elgort, I., Smith, A., & Toland, J. (2008). Is Wiki an effective platform for group course work? Australasian Journal of Educational Technology, 24(2), 195–210.Google Scholar

Ernest, E. (1995). The one and the many. In Steffe, L. & Gale, J. (Eds.), Constructivism in Education (pp. 459–486). New York: Lawrence Erlbaum.Google Scholar

Ewing, J. M., Dowling, J. D., & Coutts, N. (1998). Learning using the World Wide Web: A collaborative learning event. Journal of Educational Multimedia and Hypermedia, 8(1), 3–22.Google Scholar

Falkner, N. J. G., & Falkner, K. (2014). “Whither, badges?” or “wither, badges!”: A metastudy of badges in computer science education to clarify effects, significance and influence. In 14th Koli Calling International Conference on Computing Education Research (Koli Calling ‘14) (pp. 127–135). New York: ACM.Google Scholar

Falkner, K., Falkner, N., Szabo, C., & Vivian, R. (2016). Applying validated pedagogy to MOOCs: An introductory programming course with media computation. In 2016 ACM Conference on Innovation and Technology in Computer Science Education (pp. 326–331). New York, NY: ACM.Google Scholar

Falkner, K., & Palmer, E. (2009). Developing authentic problem solving skills in introductory computing classes. In 40th ACM Technical Symposium on Computer Science Education (SIGCSE ‘09) (pp. 4–8). New York: ACM.CrossRef Google Scholar

Falkner, K., Vivian, R., Falkner, N., & Williams, S. (2017). Reflecting on three offerings of a community-centric MOOC for k-6 computer science teachers. In 2017 ACM SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘17) (pp. 195–200). New York: ACM.Google Scholar

Findler, R. B., Clements, J., Flanagan, C., Flatt, M., Krishnamurthi, S., Steckler, P., & Felleisen, M. (2002). DrScheme: A programming environment for Scheme. Journal of. Functional Programming, 12(2), 159–182.Google Scholar

Firmin, S., Sheard, J., Carbone, A., & Hurst, J. (2012). An exploration of factors influencing tertiary IT educators’ pedagogies. In de Raadt, M. & Carbone, A. (Eds.), 14th Australasian Computing Education Conference – Volume 123 (ACE ‘12), Vol. 123 (pp. 157–166). Darlinghurst, Australia: Australian Computer Society, Inc.Google Scholar

Fisher, A., & Margolis, J. (2002). Unlocking the clubhouse: The Carnegie Mellon experience. SIGCSE Bulletin, 34(2), 79–83.Google Scholar

Geer, U., & Rudge, D. (2002). A review of research on constructivist-based strategies for large lecture science classes. Electronic Journal of Science Education, 7(2). Retrieved from www.scholarlyexchange.org/ojs/index.php/EJSE/article/view/7701 Google Scholar

Gehringer, E. F., & Miller, C. S. (2009). Student-generated active-learning exercises. In 40th ACM Technical Symposium on Computer Science Education (SIGCSE ‘09) (pp. 81–85). New York: ACM.Google Scholar

Giannakos, M. N., Krogstie, J., & Chrisochoides, N. (2014). Reviewing the flipped classroom research: Reflections for computer science education. In Barendsen, E. & Dagiené, V. (Eds.), Computer Science Education Research Conference (CSERC ‘14) (pp. 23–29). New York: ACM.CrossRef Google Scholar

Glance, D., Forsey, M., & Riley, M. (2013). The pedagogical foundations of massive open online courses. First Monday, 18(5). Retrieved from http://firstmonday.org/ojs/index.php/fm/article/view/4350/3673 Google Scholar

Grover, S., Pea, R., & Cooper, S. (2014). Promoting active learning & leveraging dashboards for curriculum assessment in an OpenEdX introductory CS course for middle school. In 1st ACM Conference on Learning @ Scale Conference (L@S ‘14) (pp. 205–206). New York: ACM.Google Scholar

Guo, P. J. (2013). Online python tutor: Embeddable web-based program visualization for cs education. In 44th ACM Technical Symposium on Computer Science Education (SIGCSE ‘13) (pp. 579–584). New York: ACM.Google Scholar

Guzdial, M. (2013). Exploring hypotheses about media computation. In 9th Annual International ACM Conference on International Computing Education Research (ICER ‘13) (pp. 19–26). New York: ACM.Google Scholar

Hamer, J., Cutts, Q., Jackova, J., Luxton-Reilly, A., McCartney, R., Purchase, H., Riedesel, C., Saeli, M., Sanders, K., & Sheard, J. (2008). Contributing student pedagogy. SIGCSE Bulletin, 40(4), 194–212.Google Scholar

Hamer, J., Luxton-Reilly, A., Purchase, H. C., & Sheard, J. (2011). Tools for “contributing student learning”. ACM Inroads, 2(2), 78–91.Google Scholar

Hativa, N. (2000). Active learning during lectures. In Teaching for Effective Learning in Higher Education (pp. 87–110). Dordrecht, The Netherlands: Springer.Google Scholar

Hertz, M., & Jump, M. (2013). Trace-based teaching in early programming courses. In 44th ACM Technical Symposium on Computer Science Education (SIGCSE ‘13) (pp. 561–566). New York: ACM.Google Scholar

Higher Education Commission (2016). From Bricks to Clicks: The Potential of Data and Analytics in Higher Education. London, UK: Higher Education Commission.Google Scholar

Horton, D., & Craig, M. (2015). Drop, fail, pass, continue: Persistence in CS1 and beyond in traditional and inverted delivery. In 46th ACM Technical Symposium on Computer Science Education (SIGCSE ‘15) (pp. 235–240). New York: ACM.Google Scholar

Hundhausen, C. D., Agrawal, A., & Agarwal, P. (2013). Talking about code: Integrating pedagogical code reviews into early computing courses. ACM Transactions on Computing Education (TOCE). 13(3), 14.Google Scholar

Hundhausen, C. D., Douglas, S. A., & Stasko, J. T. (2002). A meta-study of algorithm visualization effectiveness. Journal of Visual Languages & Computing, 13(3), 259–290.Google Scholar

Hundhausen, C. D., Narayanan, N. H., & Crosby, M. E. (2008). Exploring studio-based instructional models for computing education. In 39th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘08) (pp. 392–396). New York: ACM.Google Scholar

Jonas, M. (2013). Group note taking in Mediawiki, a collaborative approach. In 14th Annual ACM SIGITE Conference on Information Technology Education (SIGITE ‘13) (pp. 131–132). New York: ACM.Google Scholar

Jonassen, D. H. (1991). Objectivism versus constructivism: Do we need a new philosophical paradigm? Educational Technology Research & Development, 39(3), 5–14.Google Scholar

Kaczmarczyk, L., Boutell, M., & Last, M. (2007). Challenging the advanced first-year student’s learning process through student presentations. In 3rd International Workshop on Computing Education Research (ICER ‘07) (pp. 17–26). New York: ACM.Google Scholar

Kandiko, C. B., & Mawer, M. (2013). Student Expectations and Perceptions of Higher Education. London, UK: King’s Learning Institute.Google Scholar

Kapur, M. (2008). Productive failure. Cognition and Instruction, 26(3), 379–424.Google Scholar

Khan, N. Z., & Luxton-Reilly, A. (2016). Is computing for social good the solution to closing the gender gap in computer science? In Australasian Computer Science Week Multiconference (ACSW ‘16) (p. 17). New York: ACM.Google Scholar

Koh, J. H. L., Chai, C. S., Wong, B., & Hong, H.-Y. (2015). Design Thinking for Education. Singapore: Springer.Google Scholar

Kölling, M., & Barnes, D. J. (2004). Enhancing apprentice-based learning of Java. In 35th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘04) (pp. 286–290). New York: ACM.Google Scholar

Kurtz, B. L., Fenwick, J. B., Tashakkori, R., Esmail, A., & Tate, S. R. (2014). Active learning during lecture using tablets. In 45th ACM Technical Symposium on Computer Science Education (SIGCSE ‘14) (pp. 121–126). New York: ACM.Google Scholar

Lacher, L. L., & Lewis, M. C. (2015). The effectiveness of video quizzes in a flipped class. In 46th ACM Technical Symposium on Computer Science Education (SIGCSE ‘15) (pp. 224–228). New York: ACM.Google Scholar

Lawson, B. (2005). How Designers Think: The Design Process Demystified, 4th edn. London, UK: The Architectural Press.Google Scholar

Lee, E., Shan, V., Beth, B., & Lin, C. (2014). A structured approach to teaching recursion using cargo-bot. In 10th Annual Conference on International Computing Education Research (ICER ‘14) (pp. 59–66). New York: ACM.Google Scholar

Leutenegger, S., & Edgington, J. (2007). A games first approach to teaching introductory programming. In 38th SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘07) (pp. 115–118). New York: ACM.Google Scholar

Lui, D., Anderson, E., Kafai, Y. B., & Jayathirtha, G. (2017). Learning by fixing and designing problems: A reconstruction kit for debugging e-textiles. In 7th Annual Conference on Creativity and Fabrication in Education (FabLearn ‘17) (p. 6). New York: ACM.Google Scholar

Lui, A. K., Ng, S. C., Cheung, Y. H. Y., & Gurung, P. (2010). Facilitating independent learning with Lego Mindstorms robots. ACM Inroads, 1(4), 49–53.Google Scholar

Lockwood, K., & Esselstein, R. (2013). The inverted classroom and the CS curriculum. In 44th ACM Technical Symposium on Computer Science Education (SIGCSE ‘13) (pp. 113–118). New York: ACM.Google Scholar

Lowyck, J., & Elen, J. (1993). Transitions in the theoretical foundation of instructional design. In Duffy, T. M., Lowyck, J., & Jonassen, D. H. (Eds.), Designing Environments for Constructive Learning (pp. 213–229). Berlin, Germany: Springer-Verlag.Google Scholar

Lutteroth, C., & Luxton-Reilly, A. (2008). Flexible learning in CS2: A case study. In 21st Annual Conference of the National Advisory Committee on Computing Qualifications (pp. 77–83). New Zealand: Computing and Information Technology Research and Education New Zealand (CITRENZ).Google Scholar

Luxton-Reilly, A., Bertinshaw, D., Denny, P., Plimmer, B., & Sheehan, R. (2012). The impact of question generation activities on performance. In 43rd ACM Technical Symposium on Computer Science Education (SIGCSE ‘12) (pp. 391–396). New York: ACM.Google Scholar

Luxton-Reilly, A., Plimmer, B., & Sheehan, R. (2010). StudySieve: A tool that supports constructive evaluation for free-response questions. In 11th International Conference of the NZ Chapter of the ACM Special Interest Group on Human-Computer Interaction (CHINZ ‘10) (pp. 65–68). New York: ACM.Google Scholar

Maher, M. L., Latulipe, C., Lipford, H., & Rorrer, A. (2015). Flipped classroom strategies for CS education. In 46th ACM Technical Symposium on Computer Science Education (SIGCSE ‘15) (pp. 218–223). New York: ACM.Google Scholar

Mayer, R. E. (1975). Different problem-solving competencies established in learning computer programming with and without meaningful models. Journal of Educational Psychology, 67(6), 725–734.Google Scholar

Mayer, R. E. (1976). Some conditions of meaningful learning for computer programming: Advance organizers and subject control of frame order. Journal of Educational Psychology, 68(2), 143–150.Google Scholar

Medel, P., & Pournaghshband, V. (2017). Eliminating gender bias in computer science education materials. In 2017 ACM SIGCSE Technical Symposium on Computer Science Education (SIGCSE ‘17) (pp. 411–416). New York: ACM.Google Scholar

Milligan, S. (2015). Crowd-sourced learning in MOOCs: learning analytics meets measurement theory. In 5th International Conference on Learning Analytics & Knowledge (LAK ‘15) (pp. 151–155). New York: ACM.Google Scholar

Milligan, S., He, J., Bailey, J., Zhang, R., & Rubinstein, B. I. P. (2016). Validity: A framework for cross-disciplinary collaboration in mining indicators of learning from MOOC forums. In 6th International Conference on Learning Analytics & Knowledge (LAK ‘16) (pp. 546–547). New York: ACM.Google Scholar

Moog, R. S. & Spencer, J. N. (Eds.) (2008). Process-Oriented Guided-Inquiry Learning (POGIL). Washington, DC: American Chemical Society.Google Scholar

Morgan, M., Butler, M., Sinclair, J., Cross, G., Fraser, J., Jackova, J., & Thota, N. (2017). Understanding international benchmarks on student engagement: Awareness, research alignment and response from a computer science perspective. In 2017 ACM Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘17) (pp. 383–384). New York: ACM.Google Scholar

Moritz, S. H., & Blank, G. D. (2005). A design-first curriculum for teaching Java in a CS1 course. SIGCSE Bulletin, 37(2), 89–93.Google Scholar

Nelson, G. L., Xie, B., & Ko, A. J. (2017). Comprehension first: Evaluating a novel pedagogy and tutoring system for program tracing in CS1. In 2017 ACM Conference on International Computing Education Research (ICER ‘17) (pp. 2–11). New York: ACM.Google Scholar

Nortcliffe, A. (2005). Student-driven module: promoting independent learning. International Journal of Electrical Engineering Education, 42(3), 247–512.Google Scholar

Papert, S. (1993). Mindstorms: Children, Computers, and Powerful Ideas. New York: Basic Books.Google Scholar

Parsons, D., & Haden, P. (2006). Parson’s programming puzzles: a fun and effective learning tool for first programming courses. In Tolhurst, D. & Mann, S. (Eds.), 8th Australasian Conference on Computing Education – Volume 52 (ACE ‘06) (pp. 157–163). Darlinghurst, Australia: Australian Computer Society, Inc.Google Scholar

Pask, G. (1976). Conversation Theory, Applications in Education and Epistemology. Amsterdam, The Netherlands: Elsevier.Google Scholar

Patitsas, E., Craig, M., & Easterbrook, S. (2016). How CS departments are managing the enrolment boom: Troubling implications for diversity. In Research on Equity and Sustained Participation in Engineering, Computing and Technology (RESPECT) (pp. 1–2). New York, NY: IEEE.Google Scholar

Paul, J. (2016). Test-driven approach in programming pedagogy. Journal of Computing Sciences in Colleges, 32(2), 53–60.Google Scholar

Perkins, D. N., Schwartz, S., & Simmons, R. (1990). Instructional strategies for the problems of novice programmers. In Meyer, R. E. (Ed.), Teaching and Learning Computer Programming: Multiple Research Perspectives (pp. 153–178). Mahwah, NJ: Lawrence Erlbaum.Google Scholar

Phillips, D., & Soltis, J. F. (2015). Perspectives on Learning, 5th edn. New York: Teachers College Press.Google Scholar

Piaget, J. (1972). Psychology and Epistemology: Towards a Theory of Knowledge (Vol. 105). London, UK: Penguin Books Ltd.Google Scholar

Piccioni, M., Estler, C., & Meyer, B. (2014). SPOC-supported introduction to programming. In 19th Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘14) (pp. 3–8). New York: ACM.Google Scholar

Pirker, J., Riffnaller-Schiefer, M., & Gütl, C. (2014). Motivational active learning: engaging university students in computer science education. In 2014 Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘14) (pp. 297–302). New York: ACM.Google Scholar

Politz, J. G., Krishnamurthi, S., & Fisler, K. (2014). In-flow peer-review of tests in test-first programming. In 10th Annual Conference on International Computing Education Research (ICER ‘14) (pp. 11–18). New York: ACM.Google Scholar

Pollock, L., & Harvey, T. (2011). Combining multiple pedagogies to boost learning and enthusiasm. In 16th Annual Joint Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘11) (pp. 258–262). New York: ACM.Google Scholar

Porter, L., & Simon, B. (2013). Retaining nearly one-third more majors with a trio of instructional best practices in CS1. In 44th ACM Technical Symposium on Computer Science Education (SIGCSE ‘13) (pp. 165–170). New York: ACM.Google Scholar

Portillo, J. A. P., & Campos, P. G. (2009). The jigsaw technique: Experiences teaching analysis class diagrams. In Mexican International Conference on Computer Science (pp. 289–293). New York: IEEE Press.Google Scholar

Pulimood, S. M., & Wolz, U. (2008). Problem solving in community: A necessary shift in cs pedagogy. ACM SIGCSE Bulletin, 40(1), 210–214.Google Scholar

Purchase, H. (2000). Learning about interface design through peer assessment. Assessment & Evaluation in Higher Education, 24(4), 341–352.Google Scholar

Preston, G., Phillips, R., Gosper, M., McNeill, M., Woo, K., & Green, D. (2010). Web-based lecture technologies: Highlighting the changing nature of teaching and learning. Australasian Journal of Educational Technology, 26(6), 717–728.Google Scholar

Prince, M. (2004). Does active learning work? A review of the research. Journal of Engineering Education, 93(3), 223–231.Google Scholar

Ragonis, N., & Ben-Ari, M. (2005). A long-term investigation of the comprehension of OOP concepts by novices. Computational Science Education, 15(3), 203–221.Google Scholar

Reeves, T. C., & Reeves, P. M. (1997). Effective dimensions of interactive learning on the World Wide Web. In Khan, B. H. (Ed.), Web-Based Instruction (pp. 59–66). Englewood Cliffs, NJ: Educational Technology Publications.Google Scholar

Reilly, M., Shen, H., Calder, P., & Duh, H. (2014). Towards a collaborative classroom through shared workspaces on mobile devices. In 28th International BCS Human Computer Interaction Conference on HCI 2014 – Sand, Sea and Sky – Holiday HCI (BCS-HCI ‘14) (pp. 335–340). London, UK: BCS.Google Scholar

Reza, S., & Baig, M. (2015). A study of inverted classroom pedagogy in computer science teaching. International Journal of Research Studies in Educational Technology, 4(2). Retrieved from www.learntechlib.org/p/151048/Google Scholar

Rich, L., Perry, H., & Guzdial, M. (2004). A CS1 course designed to address interests of women. SIGCSE Bulletin, 36(1), 190–194.Google Scholar

Rizzardini, R. H., & Amado-Salvatierra, H. R. (2017). Full engagement educational framework: A practical experience for a MicroMaster. In 4th ACM Conference on Learning @ Scale (L@S ‘17) (pp. 145–146). New York: ACM.Google Scholar

Rubin, M. J. (2013). The effectiveness of live-coding to teach introductory programming. In 44th ACM Technical Symposium on Computer Science Education (SIGCSE ‘13) (pp. 651–656). New York: ACM.Google Scholar

Rubio, M. A., Romero-Zaliz, R., Mañoso, C., & De Madrid, A. P. (2015). Closing the gender gap in an introductory programming course. Computers & Education, 82, 409–420.Google Scholar

Rudestam, K., & Schoenholtz-Read, J. (2010). The flourishing of adult online education: an overview. In Rudestam, K. & Schoenholtz-Read, J. (Eds.), Handbook of Online Learning, 2nd edn (pp. 1–28). Thousand Oaks, CA: SAGE.Google Scholar

Rudman, P. (2002). Investigating Domain Information as Dynamic Support for the Learner During Spoken Conversations (PhD thesis). University of Birmingham.Google Scholar

Salmon, G. (2004). E-Tivities: The Key to Active Online Learning, 2nd edn. Abingdon, UK: Taylor & Francis e-Library.Google Scholar

Sanders, K., Boustedt, J., Eckerdal, A., McCartney, R., & Zander, C. (2017). Folk pedagogy: Nobody doesn’t like active learning. In 2017 ACM Conference on International Computing Education Research (ICER ‘17) (pp. 145–154). New York: ACM.Google Scholar

Schneider, B., & Blikstein, P. (2016). Flipping the flipped classroom: A study of the effectiveness of video lectures versus constructivist exploration using tangible user interfaces. IEEE Transactions on Learning Technologies, 9(1), 5–17.CrossRef Google Scholar

Sharples, M., de Roock, R., Ferguson, R., Gaved, M., Herodotou, C., Koh, E., Kukulska-Hulme, A., Looi, C-K., McAndrew, P., Rienties, B., Weller, M. & Wong, L. H. (2016). Innovating Pedagogy 2016: Open University Innovation Report 5. The Open University.Google Scholar

Shulman, L. (2005). Pedagogies. Liberal Education, 91(2), 18–25.Google Scholar

Siemens, G. (2005). Connectivism: A learning theory for the digital age. In International Journal of Instructional Technology and Distance Learning, 2(1), 3–10.Google Scholar

Siemens, G. (2012). MOOCs are really a platform. ELearnspace. Retrieved from www.elearnspace.org/blog/2012/07/25/moocs-are-really-a-platform/Google Scholar

Simon, B., & Cutts, Q. (2012). Peer instruction: A teaching method to foster deep understanding. Communications of the ACM, 55(2), 27–29.Google Scholar

Sirkiä, T. (2016). Combining parson’s problems with program visualization in CS1 context. In 16th Koli Calling International Conference on Computing Education Research (Koli Calling ‘16) (pp. 155–159). New York: ACM.Google Scholar

Sirkiä, T., & Sorva, J. (2015). Tailoring animations of example programs. In 15th Koli Calling Conference on Computing Education Research (Koli Calling ‘15) (pp. 147–151). New York: ACM.Google Scholar

Slavin, R. E. (1991). Synthesis of research on cooperative learning. Educational Leadership, 48(5), 71–82.Google Scholar

Slavin, R. E., & Cooper, R. (1999). Improving intergroup relations: Lessons learned from cooperative learning programs. Journal of Social Issues, 55, 647–663.Google Scholar

Smith, P. A., & Webb, G. I. (1995). Reinforcing a generic computer model for novice programmers. In 7th Australian Society for Computer in Learning in Tertiary Education Conference (ASCILITE ’95). Retrieved from www.ascilite.org/conferences/melbourne95/smtu_bak/papers/smith.pdf Google Scholar

Smith, J., Tessler, J., Kramer, E., & Lin, C. (2012). Using peer review to teach software testing. In 9th Annual International Conference on International Computing Education Research (ICER ‘12) (pp. 93–98). New York: ACM.Google Scholar

Sonnentag, S. (1998). Expertise in professional software design: A process study. Journal of Applied Psychology, 83, 703–715.Google Scholar

Sorva, J. (2013). Notional machines and introductory programming education. Transactions on Computing Education (TOCE), 13(2), 8.Google Scholar

Sorva, J., Karavirta, V., & Malmi, L. (2013). A review of generic program visualization systems for introductory programming education. Transactions on Computing Education (TOCE), 13(4), 15.Google Scholar

Sorva, J., & Sirkiä, T. (2010). UUhistle: A software tool for visual program simulation. In 10th Koli Calling International Conference on Computing Education Research (Koli Calling ‘10) (pp. 49–54). New York: ACM.Google Scholar

Srinivasan, V., Butler-Purry, K. & Pedersen, S. (2008). Using video games to enhance learning in digital systems. In 2008 Conference on Future Play: Research, Play, Share (Future Play ‘08) (pp. 196–199). New York: ACM.Google Scholar

Summet, J., Kumar, D., O’Hara, K., Walker, D., Ni, L., Blank, D., & Balch, T. (2009). Personalizing CS1 with robots. ACM SIGCSE Bulletin, 41(1), 433–437.Google Scholar

Swan, K., Day, S., & Bogle, L. (2016). Metaphors for learning and MOOC pedagogies. In 3rd ACM Conference on Learning @ Scale (pp. 125–128). New York: ACM.Google Scholar

Tarimo, W. T., Deeb, F. A., & Hickey, T. J. (2015). A flipped classroom with and without computers. In International Conference on Computer Supported Education (pp. 333–347). New York: Springer International Publishing.Google Scholar

Titterton, N., Lewis, C. M., & Clancy, M. J. (2010). Experiences with lab-centric instruction. Computer Science Education, 20(2), 79–102.Google Scholar

Toven-Lindsey, B., Rhoads, R. A., & Lozano, J. B. (2015). Virtually unlimited classrooms: Pedagogical practices in massive open online courses. The Internet and Higher Education, 24, 1–12.Google Scholar

Umapathy, K., & Ritzhaupt, A. D. (2017). A meta-analysis of pair-programming in computer programming courses: Implications for educational practice. ACM Transactions on Computing Education (TOCE), 17(4), 16.Google Scholar

Utting, I., Cooper, S., Kölling, M., Maloney, , , J., & Resnick, M. (2010). Alice, Greenfoot, and Scratch – A discussion. ACM Transactions on Computing Education (TOCE), 10(4), 17.Google Scholar

Vassiliadis, B., Kameas, A., & Sgouropoulou, C. (2016). A closer look at MOOC’s adoption from a qualitative perspective. In 20th Pan-Hellenic Conference on Informatics (PCI ‘16) (p. 17). New York: ACM.Google Scholar

Vickers, R., Cooper, G., Field, J., Thayne, M., Adams, R., & Lochrie, M. (2014). Social media and collaborative learning: Hello Scholr. In 18th International Academic MindTrek Conference: Media Business, Management, Content & Services (AcademicMindTrek ‘14) (pp. 103–109). New York: ACM.Google Scholar

Vozniuk, A., Holzer, A., & Gillet, D. (2014). Peer assessment based on ratings in a social media course. In 4th International Conference on Learning Analytics And Knowledge (LAK ‘14) (pp. 133–137). New York: ACM.Google Scholar

Vygotsky, L. S. (1978). Mind in Society: The Development of Higher Psychological Processes. Cambridge, MA: Harvard University Press.Google Scholar

Wakeling, D. (2008). A robot in every classroom: Robots and functional programming across the curriculum. In 2008 International Workshop on Functional and Declarative Programming in Education (FDPE ‘08) (pp. 51–60). New York: ACM.Google Scholar

Walker, J. D., Brooks, D. C., & Baepler, P. (2011). Pedagogy and space: Empirical research on new learning environments. EDUCAUSE Quarterly, 34(4). Retrieved from https://eric.ed.gov/?id=EJ958727 Google Scholar

Watson, C., & Li, F. W. B. (2014). Failure rates in introductory programming revisited. In 2014 Conference on Innovation and Technology in Computer Science Education (ITiCSE ‘14) (pp. 39–44). New York: ACM.Google Scholar

Wenger, E. (1998). Communities of practice. Learning as a social system. Systems Thinker. 9(5). Retrieved from https://thesystemsthinker.com/communities-of-practice-learning-as-a-social-system/Google Scholar

Williams, L. (2000). The Collaborative Software Process (PhD dissertation). University of Utah.Google Scholar

Williams, L., & Kessler, R. (2002). Pair Programming Illuminated. Boston, MA: Addison-Wesley Longman Publishing Co., Inc.Google Scholar

Williams, L., McCrickard, D. S., Layman, L., & Hussein, K. (2008). Eleven guidelines for implementing pair programming in the classroom. In Melnik, G. & Poppendieck, M. (Eds.), Agile Conference (pp. 445–452). New York: IEEE Press.Google Scholar

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15 - Pedagogic Approaches

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