Content uploaded by Szymon Machajewski
Author content
All content in this area was uploaded by Szymon Machajewski on Aug 24, 2017
Content may be subject to copyright.
The Short and Long Game Theory for Academic Courses
Posted: Aug 23, 2017.
This is a guest post by Dr. Szymon Machajewski, Blackboard MVP, faculty with the School of
Computing & Information Systems at Grand Valley State University.
http://blog.blackboard.com/the-short-and-long-game-theory-for-academic-courses/
Gamification is a buzzword that sometimes receives a skeptical welcome in higher
education. Some may wonder whether playing games has any place in a college level class, and
the research results are mixed. Some researchers found that applying leaderboards to a college
course can actually demotivate students and lower academic results (Hanus & Fox, 2015).
Gartner warned that as much as 80% of gamification projects are likely to fail (Gartner, 2012).
So why bother with a pedagogy that may be risky to adopt and at the same time represents
controversial characteristics of childish play and perceived lack of seriousness?
In my view, the risk is worthwhile. Lack of engagement in traditional courses, especially
introductory college courses, discourages students and faculty. This lack of engagement can
perhaps be due to what has been called ‘dysfunctional illusions of rigor.’ Craig E. Nelson from
Indiana University coined the term to reflect on research-debunked traditional views of college
instruction. Some examples include: “1. Hard courses weed out weak students. When students
fail it is primarily due to inability, weak preparation, or lack of effort. 2. Traditional methods of
instruction offer effective ways of teaching content to undergraduates. Modes that pamper
students teach less.”
Rather than ‘pampering’ students, active learning has proven to make a significant
difference in academic results and student engagement. In addition, research published by the
American Psychological Association (APA) found that play is good for learning and it holds a
large potential for teaching new forms of thought and behavior. In that same study, playing
digital games was found to boost learning, health, and social skills.
At Grand Valley State University, I have conducted research on gamification which has
led to the development of a “short and long game theory” (Machajewski, 2017). The application
of gamification in academic courses requires the gameful design of individual lecture periods, as
well as the gameful design of the semester-long student journey.
Some examples of short game elements include:
•Clickers
•Daily Journal
•Duolingo
•Kahoot
•One Minute Paper
•Problem Based Learning
•Puzzles/Paradoxes
•Quizlet Live
•Think-pare-share
Examples of long game elements include:
•Exam Peace of Mind Points PofM
•Formative Assessments
•My Progress instead of My Grades
•XP Ledger – MyGame
While active learning fits well in the “short game” design, something else is needed to
make the course “long game” worth playing for students. We have implemented the “long
game” design in our Introduction to Computing course at Grand Valley State University, which
earned exemplary course status in the 2017 Blackboard ECP program. The key to the “long
game” is the adoption of an experience points (XP) ledger. This instrument allows students to
earn XP during lectures, homework assignments, hands-on practice sessions and track the total
across the length of the course.
School grades used to serve as the “long game” strategy. However, today they are more
likely to demotivate students than encourage them to conduct deeper exploration or to appreciate
the subject matter. Grades have become a high stakes extrinsic reward. Just as money – in the
research of Daniel Pink – is a poor motivator of knowledge workers, grades are a poor motivator
of intellectual performance for students.
Students are knowledge workers and require creative thinking. To motivate knowledge
workers, we need to appeal to autonomy, mastery, and purpose. These three characteristics are
based on the self-determination theory (Ryan & Deci, 2000). Not only do we care about the
intellectual performance of students during class, but we also want students to grow their affinity
for the subject matter. In other words, we want to avoid the sentiment: “I got an A in the class,
but I hate math, and I hope I will never have to use it again in my life.”
For gamification to be successful in academic courses, you need to have exemplary
instructional design, which is why the value of the Blackboard ECP program is directly related to
gamification. Clarifying instructions for students, setting attainable course and learning
objectives, and chunking content to encourage progress are all efforts to turn a course into well-
designed work, which is one of the definitions for a game.
A focus on student experience creates the common ground between instructional design
and gamification. Best practices of instructional design recommend active learning as the most
effective way to engage students in the classroom. While tutoring may increase grades by two
standard deviations (Bloom, 1984), active learning could increase academic performance by 0.47
standard deviations (Ruiz-Primo, Briggs, Iverson, Talbot, & Shepard, 2011). Some students are
150% more likely to fail in courses dominated by traditional lectures over courses with active
learning strategies (Freeman et al., 2014).
My gamification research (Machajewski, 2017) recommends Quizlet Live and Kahoot! as
active learning platforms with a competitive edge. The “short game” in courses depends on
classroom, hybrid, or online deliveries. However, the “long game” approach is just as important
to consider. Opportunities for improvement can be found in mitigating student exam anxiety,
sufficient encouragement of failure in practicing of hands-on material, and adopting intermediate
due dates to ensure an ongoing growth of mastery.
The specific technologies used in my Introduction to Computing course were presented in
New Orleans at the BbWorld 2017 conference and can be reviewed in the conference
publication. My theory of the “short and long game” in academic courses is being developed on
the background of case studies and emerging gamification tools. Some examples of the case
studies include a Germanic Studies course and STEM introductory college course.
Gamification in an academic course can be considered a complex system of many tools
within two main categories: short-term engagement and long-term participation. Adoption of
just a few of them separately, such as a leaderboard, badges, a points system, or classroom
response system may not lead to an intrinsically satisfying experience and expected high levels
of motivation. This follows the Anna Karenina principle (Bornmann & Marx, 2012) present in
complex systems.
Conversely, gamification studies showing negative results should not reflect a general
lack of applicability of gameful design in academic courses. A consideration of both the short
game and the long game will help faculty experience more benefits of gameful design. In turn,
the reciprocal quality of engagement is likely to affect the faculty and the students.
References
Bloom, B. S. (1984). The 2 Sigma Problem: The Search for Methods of Group Instruction as
Effective as One-to-One Tutoring. Educational Researcher, 13(6), 4.
doi:10.3102/0013189X013006004
Bornmann, L., & Marx, W. (2012). The Anna Karenina principle: A way of thinking about
success in science. Journal Of The American Society For Information Science &
Technology, 63(10), 2037-2051. doi:10.1002/asi.22661
Burke, B. (2014). Gartner Redefines Gamification. Retrieved from
http://blogs.gartner.com/brian_burke/2014/04/04/gartner-redefines-gamification/
Freeman, S., Eddy, S. L., McDonough, M., Smith, M. K., Okorafor, N., Jordt, H., and
Wenderoth, M. P., (2014). Active learning increases student performance in science,
engineering, and mathematics. Proceedings of the National Academy of Sciences
(PNAS), 111(23),8410-8415.
Hanus, M., & Fox, J. (2015). Assessing the effects of gamification in the classroom: A
longitudinal study on intrinsic motivation, social comparison, satisfaction, effort, and
academic performance. Computers & Education, 80152–161.
Machajewski, S. (2017). Application of Gamification in a College STEM Introductory Course: A
Case Study. Retrieved from https://eric.ed.gov/?id=ED574876
Ryan, R., & Deci, E. (2000). Self-determination theory and the facilitation of intrinsic
motivation, social development, and well-being. American Psychologist, 55, 68–78.
Ruiz-Primo, M.A., Briggs, D., Iverson, H., Talbot, R., Shepard, L.A. (2011). Impact of
undergraduate science course innovations on learning. Science 331, 1269–1270.