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An Investigation of Design Features for Inverted Classroom Support Technology

An Investigation of Design Features for Inverted Classroom Support Technology. Joslenne Pena, Mary Beth Rosson College of Information Sciences & Technology The Pennsylvania State University. Introduction. Technology is changing education

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An Investigation of Design Features for Inverted Classroom Support Technology

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  1. An Investigation of Design Features for Inverted Classroom Support Technology Joslenne Pena, Mary Beth Rosson College of Information Sciences & Technology The Pennsylvania State University

  2. Introduction • Technology is changing education • Instructors are constantly looking for new ways to engage students in an interactive environment • Presenting dry material through hands-on activities, active discussion, and problem solving • The inverted classroom has emerged as an exciting approach to teaching along with online, hybrid, and blended approaches • Different types of technologies are used to support it (hardware, software)

  3. Literature Review • Inverted classroom (flipped, reverse, backwards) • Lecture happens away from the classroom while homework occurs within [Lage et al, 2001] • Active learning and student-centered learning [Bishop and Verleger, 2013] • Handful of studies investigating student perception, student engagement and student assessment of the inverted classroom [Strayer, 2012] • Other studies compare traditional vs. non-traditional • Another set solely devoted to the pedagogical method i.e. content delivery, content creation, and curriculum development • Very positive reactions from both instructors and students – only increasing

  4. Literature Review • Many tasks involved with inverted classroom implementation, therefore, various pieces of technology are used • Tasks include video and audio creation, file management, document creation • The use of certain tools depends on a variety of factors • Resources available, cost limitations, willingness to learn, time constraints, type of material presented (topic, curriculum) • Examples of technology used include • Camtasia • PowerPoint • Adobe Captivate • Final Cut Pro • Doceri

  5. Motivation & the gap • Rise of unconventional teaching methods like the inverted classroom (online, hybrid, blended) in the world of education, again, only increasing • Very few studies discuss their rationale behind tools or the design of custom support tools dedicated to inversion • One semester implementation – instructors can use anywhere between 3-8 tools and technologies to aid in various tasks • MOOCs exist for large online courses, Angel/Blackboard for course management, why not custom supported tool for inverted? • How can we make inverted classroom implementation easier and less time consuming?

  6. Research Question • What are the design features of a tool that best supports the inverted classroom environment structure?

  7. Methodology • Theoretical Framework – Activity Theory [Engestrom, 1990] • Human actions decomposed into components • Understanding the context and actions surrounding the outcome of an activity • Complex system with intricate hierarchical structures • Special attention paid to the instruments component • Fits HCI and education [Hashim and Jones, 2007]

  8. Methodology • Interpretive epistemology • Expand knowledge of the inverted classroom • Drawing from personal instructors experiences implementing the inverted classroom pedagogy • Exploring the tools and technologies instructors are using to support this teaching method • Research design • Interview-based study of exploratory nature

  9. Methodology • Examined the inverted classroom environment through literature and own interpretation of data • Components in this activity are aligned with the many parts of an inverted classroom structure

  10. Data Collection • 7 semi-structured interviews (35min – 80min) • Audio recorded and manually transcribed • Snowball sampling method • Encourage diversity in discipline and technology use • Instructor on PSU main campus and have implemented the pedagogy - Main criteria • Participants were PSU instructors across campus representing 4 colleges

  11. Data Analysis • Initial coding process guided by Activity Theory • Second round of coding examined emergent themes not suggested by Activity Theory but relevant to design • Using an open coding technique • Special focus given to the instruments component – representing tools and technology

  12. Findings – instructors as subjects • All instructors were in STEM related disciplines, which [Gannod et al, 2008] argues best fit the inverted pedagogy • Heavy experience teaching and experience with online, hybrid, and blended courses (8-25 years) • 4/7 instructors conduct education research and have an advanced degree in education • 5/7 are women instructors, Lage argues women are more receptive to collaborative environments such as inverted classroom[Lage et al, 2001]

  13. Findings – the surrounding community • [Linda] I saw another instructor showcasing their work at an event and I saw all the cool things they were doing which influenced me to try it out. • Looking towards their on campus educational community for ideas and innovative teaching strategies • [Harold] {Another colleague} has been really good to me. • Here, Harold talks about his very positive experience with one senior-level colleague. This colleague, over the years, has been extremely supportive of his various teaching strategies including the inverted classroom

  14. Findings – inverted classroom as object • [Michelle] It allows me to cater material to different people at different times. There is more room to cover technical content and meet the needs of students. • [Tara] …the thing that I think is the sweet spot is to make the connection for the student. They are learning and they don’t even know they are learning, they are more engaged in the learning process. • [Nicole] I definitely prefer flipped, I mean, the online, as you can imagine-very separated from the students, I don’t know what they look like, yeah… I don’t like it. Somehow with the flipped course they feel like I’m on their side. • Here Michelle, Tara, and Nicole discuss the positive experiences they had using the inverted model

  15. Findings – inverted classroom as object • [Linda] Yeah I almost got fired. I had students really angry, saying they didn’t learn anything. It was extremely frustrating. • [Joe] The concept works great if the student is participating and buying into it… it’s a perfectly valid concept, the problem is that students are not that self-directed. • [Joe] Automating a bad process just makes a bad process more efficient… the bad thing is if you didn’t sign up for that, “I didn’t ask to be indoctrinated into a certain way of thinking”. • Joe and Linda discuss their negative experiences. Linda tried the model once but decided to give it another shot after almost being fired and ended up with a positive experience. In contrast, Joe tried the model but decided to disregard it, as he found it does not work

  16. Findings – technology and tools as instruments • [Harold] I have already expressed my displeasure about the replacement of Angel, yeah but Angel sucks, yeah but I’ve already learned it, we are all gonna be lost. I know what it takes to break technology. I keep separate excel workbooks, I don’t trust Angel. • [Tara] Angel sucks! There’s not that many other tools to use, I put a syllabus and readings and assignments and I use it because it’s within the system. • [Nicole] Yeah, Angel is totally, it’s dinosaur-ish, I have thought about using yammer. I spend a lot of time in the summer with my kids, so if I’m sitting there and I got my phone and someone pings me a question in yammer I can answer it, I can’t do that through Angel, it’s not intuitive. • [Joe] I use Angel as mostly a communication tool, emails, and announcements. TAs and LAs assist with answering questions online. • Here, Harold, Tara, Nicole, and Joe talk about their use of Angel (CMS). Most of them see Angel in a negative light because of its usability, learnability, and functionality. There are also talks at PSU about replacing Angel which is affecting how they see it.

  17. Findings – technology and tools as instruments • [Tara] Ithink that when you leverage these tools there is an approach-ability that they have to it… they find it more accessible and more current… they create a tiny more sense of community. • [Tara] I think a baseline system that has functionality in it, basic tools that everyone can use but do not restrict people • [Joe] I use a peer review submission that I wrote because Angel doesn't have anything useful. • [Nicole] the user should have some preferences, I don’t want this or that, there’s so much on Angel… why are we not including mobile instead we tell students to put it away? • [Nicole] the technology piece that I have really been looking for, videos in 10-15min chunks, you should have questions dispersed throughout the video or after a 10minute video, and you test for understanding… i don’t think the videos are interactive enough… I’ve thought about using clickers in class. • Here Tara, Joe, Nicole discuss their use of other tools besides Angel to support inversion. Furthermore, they suggest features or requirements for a technology that can be designed to support inversion, or in many cases, is better than Angel.

  18. Discussion • Design implications • Did not find extremely specific and detailed features • Angel (CMS) constantly used as a benchmark, mostly seen negatively • Value convenience, functionality, customization, cross-compatibility, and flexibility • Instructors carry the “As long as it works” attitude • Limit Angel usage to pursue other options for tools, spending more time on various tasks

  19. Discussion • Theoretical implications • Broad and basic application of Activity Theory , interested in one component • Actions surrounding the inverted classroom are numerous and complex • Instruments play a role in shifting effectiveness and outcome of activity which for the purposes of this study is learning • Community does have an influence over subjects and tools • Rules implemented by an instructor affect student interaction with content and instruments • Contradictions between these components create tensional relationships

  20. Conclusion • The inverted classroom is a very complex activity with many aspects • Instructors are using a variety of technologies to assist them in their inverted implementations • Perhaps the model best suits computing disciplines • Although we did not get as detailed design features as expected, basic thoughts did arise • Build a tool that is responsive • Cross-compatibility • Customized choices (instructors may enable or disable components) • Personalization • Better Angel? (using a CMS structure as a template)

  21. Limitations • Time constraints • Participants contacted us after data collection phase (will be considered for next phase in study) • Bigger sample size desired • Absence of triangulation • Generalizations to other populations cannot be made • Inverted implementations are unique to every instructor

  22. Future Work • Same study on a larger scale with multiple data sources (observation, focus groups) • Quantitative study involving surveys or questionnaires • Mixed methods approach • Design-based research with low-fidelity prototype development, usability testing and use cases • Iterative design process of prototype through agile methods • Thorough content analysis of literature • Study on liberal arts/humanities instructors?

  23. References • Bates, S., & Galloway, R. (2012). The inverted classroom in a large enrolment introductory physics course: a case study. • Bishop, J. L., Verleger, M. A. (2013). The flipped classroom: A survey of the research. In Proceedings of the 120th ASEE Annual Conference & Exposition. • Boutell, M., & Clifton, C. (2011). SPLICE: Self-Paced Learning in an Inverted Classroom Environment. In Proceedings, of the 42nd ACM Technical Symposium on Computer Science Education. • Butt, A. (2012). Student views on the use of lecture time and their experience with a flipped classroom approach. Business Education & Accreditation, 6(1). • Campbell, J., Horton, D., Craig, M., & Gries, P. (2014, March). Evaluating an inverted CS1. In Proceedings of the 45th ACM technical symposium on Computer science education (pp. 307-312). ACM. • Choi, E. M. (2013). Applying inverted classroom to software engineering education. International Journal of e-Education, e-Business, e-Management and e-Learning, 3(2), 121-125. • Engeström, Y. (1990). Learning, Working, and Imagining: Twelve Studies in Activity Theory. Helsinki: Orienta-KonsultitOy. • Findlay-Thompson, S., & Mombourquette, P. (2014). EVALUATION OF A FLIPPED CLASSROOM IN AN UNDERGRADUATE BUSINESS COURSE. Business Education & Accreditation, 6(1). • Gannod, G. C., Burge, J. E., & Helmick, M. T. (2008, May). Using the inverted classroom to teach software engineering. In Proceedings of the 30th international conference on Software engineering (pp. 777-786). ACM.

  24. References (cont.) • Gehringer, E. F., & Peddycord III, B. W. (2013, March). The inverted-lecture model: a case study in computer architecture. In Proceeding of the 44th ACM technical symposium on Computer science education (pp. 489-494). ACM. • Haden, C., Flikkema, P., Weller, T., Frolik, J., Verrei-Berenback, W., & Shiroma, W. (2009). Assessment of a hybrid, online/in-class course developed at multiple universities. In 2009 ASEE Annual Conference. Austin, TX, June (pp. 14-17). • Hashim, N. H., & Jones, M. L. (2007). Activity Theory: A framework for qualitative analysis. Faculty of Commerce-Papers, 408. • Houston, M., & Lin, L. (2012, March). Humanizing the Classroom by Flipping the Homework versus Lecture Equation. In Society for Information Technology & Teacher Education International Conference (Vol. 2012, No. 1, pp. 1177-1182). • Jonassen, D. H., & Rohrer-Murphy, L. (1999). Activity theory as a framework for designing constructivist learning environments. Educational Technology Research and Development, 47(1), 61-79. • Kellogg, S. (2009, October). Developing online materials to facilitate an inverted classroom approach. In Frontiers in Education Conference, 2009. FIE'09. 39th IEEE (pp. 1-6). IEEE. • Lage, M. J., & Platt, G. (2000). The Internet and the Inverted Classroom. The Journal of Economic Education, 31(1), 11. • Lage, M. J., Platt, G. J., & Treglia, M. (2000). Inverting the Classroom: A Gateway to Creating an Inclusive Learning Environment. The Journal of Economic Education, 31(1), 30-43. • Lockwood, K., & Esselstein, R. (2013, March). The inverted classroom and the CS curriculum. In Proceeding of the 44th ACM technical symposium on Computer science education (pp. 113-118). ACM.

  25. References (cont.) • Mason, G. S., Shuman, T. R., & Cook, K. E. (2013). Comparing the effectiveness of an inverted classroom to a traditional classroom in an upper-division engineering course. • McLaughlin, J. E., Roth, M. T., Glatt, D. M., Gharkholonarehe, N., Davidson, C. A., Griffin, L. M., & Mumper, R. J. (2014). The flipped classroom: a course redesign to foster learning and engagement in a health professions school. Academic Medicine, 89(2), 236-243. • Papadopoulos, C., Santiago-Román, A., & Portela, G. (2010, October). Work in Progress–Developing and Implementing an Inverted Classroom for Engineering Statics. In Frontiers in Education Conference (FIE), 2010 IEEE (pp. F3F-1). IEEE. • Schullery, N. M., Reck, R. F., & Schullery, S. E. (2011). Toward Solving the High Enrollment, Low Engagement Dilemma: A Case Study in Introductory Business. International Journal of Business, Humanities and Technology, 1(2), 1-9. • Strayer, J. F. (2012). How learning in an inverted classroom influences cooperation, innovation and task orientation. Learning Environments Research, 1-23. • Swartz, B., Velegol, S. B., Laman, J. A. (2013). Three approaches to flipping ce courses: Faculty perspectives and suggestions. In Proceedings of the 120th ASEE Annual Conference & Exposition. • Toto, R., & Nguyen, H. (2009, October). Flipping the Work Design in an industrial engineering course. In Frontiers in Education Conference, 2009. FIE'09. 39th IEEE (pp. 1-4). IEEE. • Warter-Perez, N., & Dong, J. (2012). Flipping the classroom: How to embed inquiry and design projects into a digital engineering lecture. In Proceedings of the 2012 ASEE PSW Section Conference. • Zappe, S., Leicht, R., Messner, J., Litzinger, T., & Lee, H. W. (2009). "Flipping" the classroom to explore active learning in a large undergraduate course. In American Society for Engineering Education. American Society for Engineering Education.

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