Digital Storytelling and Creative Communication: Does One Help Develop the Other?

Alan Alda, from M*A*S*H*, knows how to tell a story.  In one of his presentations, he asks a young woman to the stage.  Alda then asks the young woman to carry an empty glass across the stage.  She stares at the him awkwardly and does it without much fanfare. Alda then walks to her with a pitcher of water.  He pours water into the empty glass and fills to the brim. He asks her to carry the glass to the other side of the stage. “Don’t spill a drop of water or your entire village will die.”- he says.  The young woman, slowly, deliberately walks across the stage. She carefully gauges the level of water in the glass as she takes each step. The audience is silent, enraptured in the backstory of the overfilled glass.  They are interested and invested in the story. (Watch Alan Alda explain the importance of storytelling in his video: “Knowing How to Tell a Good Story is Like Having Mind Control.”)

Stories are powerful. Storytelling is one of the oldest forms of communication that we have.  We are attracted to stories because they are human, (Alda, 2017). Stories relay information about human nature, accomplishments, challenges, and discoveries. They make us feel part of a community and help evoke empathy, (Dillion, 2014).  According to Alan Alda, we like stories because we think in stories, particularly if the story has an obstacle. Like in the example above, we are interested in listening to the attempts overcoming the obstacle, (Alda, 2017).

Stories can also be powerful in the classroom.  A good story helps shape mental models, motivates and persuades others, and teaches lessons, (Dillion, 2014).  There are many ways to deliver a story but I have been gaining significant interest in digital storytelling. Technology is not stoic but rather highly personalizable as people are discovering unique ways to learn, entertain, network, and build relationships using technology, (Robin, 2008).  It is not surprising then that people are using technology to also share their story. Digital storytelling is technique that I discovered as I was exploring problem based learning (PBL) to develop innovation skills.  In that blog post, I explained that digital storytelling was one mode students could employ to “solve” a problem in PBL by creating an artifact. I realize that this wasn’t directly related to my inquiry at the time, because problem-based learning is more focused on the process of problem-solving rather than the artifact itself.  Despite this, I found the idea of digital storytelling interesting and wanted to revisit it. “Storytelling” in particular, is a buzzword that circles back in unexpected mediums. For example, my husband attended a conference that explored storytelling through data, in other words, how to design graphs, charts, and other visual representations of data that share a story without any significant description or explanation. Yet these graphs communicate important information. That then got me pondering about how digital storytelling can be used to teach students to creativity communicate information either about themselves or about a topic using technology.

So then how can students use digital storytelling for the purposes of creative communication? This question relates to ISTE Student Standard 6: Creative Communicator in which, “students communicate clearly and express themselves creatively for a variety of purposes using the platforms, tools, styles, formats and digital media appropriate to their goals.”  Digital storytelling is one vehicle in which students can use to express and communicate clearly.  Interestingly, the idea of digital storytelling isn’t new, it was originally developed in the 1980’s but is experiencing a renaissance in the 2000’s, (Robin, 2008). Not only can digital storytelling be a medium for learning, but also different types of information can be relayed using this technique including personal narrative (what most non-ed professionals use), stories on informing/instructing, and lastly, stories that examine historical events, (Robin, 2008).

Stories must be well-crafted in order for them to be effective and memorable. Students can deliver a story by investigating a topic, write a script, develop their story, and tie it all together using multimedia, (Robin, 2008).  Blogs, podcasts, wikis, and other mediums like pinterest can be used to convey a story simply,(University of Houston, 2018). To help students get started, the University of Houston’s Educational Uses of Digital Storytelling webpage offers great information such as timing, platforms, and examples of artifacts.

Figure depicting the digital storytelling process.
Figure 1.1 The Digital Storytelling Process

Before diving into a story, the most important elements are explored in its theoretical framework.  This framework includes the seven-elements needed in order for each story to be impactful. Figure 1.2 below summarizes the seven key elements.  

Infographic describing the 7 elements of digital storytelling
Figure 1.2 The 7 Elements of Digital Storytelling

Just as Alan Alda explores in his video, the seven-elements emphasize that good stories must capture the audience’s attention, explore obstacles or serious issues that the audience can connect with, and must be personal in order to enhance and accelerate comprehension, (Robin, 2008). By allowing students to engage in digital storytelling, they are also developing crucial 21st century skills: digital, global, technology, visual, and information literacy.

Tying it all together: How does digital storytelling fulfill the requirements for the ISTE student standard on creative communicator?

As Robin alludes to, it can be challenging to distinguish the various types of stories because oftentime they overlap, particularly considering the personal narrative, (Robin, 2008). A good story is relatable, we can put ourselves into the shoes of the protagonist.  The use of technology is just another medium we can use to communicate our stories. By implementing digital storytelling in the classroom, it would allow for transformation (SAMR) of existing assignments and lectures.  Here are some additional thoughts on how this technique can help students become creative communicators:

  • ISTE 6A: “Students choose the appropriate platforms and tools for meeting the desired objectives of their creation or communication”.  Platforms such as blogs, podcasts, in addition to tools such as cameras, and editing software are all components of digital storytelling. Allowing students to evaluate the various platforms and tools in relation to their desired outcome, they would be developing digital, technology, and visual literacy.
  • ISTE 6B: “Students create original works or responsibly repurpose or remix digital resources into new creations”. Though the most common application of digital storytelling would be to create an original artifact, Robin provides an example of remixing in recreating historical events by using photos, or old headlines to provide depth and meaning to the facts students are learning in class, (Robin, 2008). By curating and remixing existing artifacts, students would develop global, digital, visual, and information literacy.
  • ISTE 6C: “Students communicate complex ideas clearly and effectively by creating or using a variety of digital objects such as visualizations, models or simulations”. This idea goes back to the example I shared of storytelling using data (graphs/charts/figures) but it can also include infographics. Depicting complex data through an interesting visual medium engages digital, global, technology, visual, and information literacy.
  • ISTE 6D: “Students publish or present content that customizes the message and medium for their intended audiences”. The basis of storytelling is that it is meant to be shared with others.  If the story doesn’t match the audience, it will not be impactful or important. This is a point the 7-elements of digital storytelling stresses. Understanding and crafting stories for a specific audience demonstrates digital and global literacy.

Good digital storytelling can allow students become creative communicators.  Using technology can reach audiences in many ways never thought of before while still sharing the human experience.  As Robin puts it, in a world where we are receiving thousands of messages a day across many different platforms, stories become engaging, driving, and a powerful way to share a message in a short period of time, (Robin, 2008).

Resources

[big think channel]. (2017, July 18). Knowing how to tell a good story is like having mind control: Alan Alda. [Video File]. Retrieved from https://www.youtube.com/watch?v=r4k6Gm4tlXw

Dillon, B. (2014). The power of digital story. Edutopia. Retrieved from http://www.edutopia.org/blog/the-power-of-digital-story-bob-dillon

International Society for Technology in Education, (2017).  The ISTE standards for students. Retrieved from: https://www.iste.org/standards/for-students.

Robin, BR., (2008). Digital storytelling: A powerful technology tool for the 21st century classroom. Theory into Practice, 47: 220-228. DOI:1080/00405840802153916

University of Houston, (2018). Educational use of digital storytelling. Retrieved from: http://digitalstorytelling.coe.uh.edu/page.cfm?id=27&cid=27&sublinkid=75

Building Computational Thinking through a Gamified Classroom

Who says playing video games doesn’t teach you anything?  Playing and creating games could actually help students develop another 21st century skill, computational thinking (CT).  Computational thinking is  a form of problem solving that takes large, complex problems, breaks them down into smaller problems, and uses technology to help derive solution. In deriving solutions, students engage in a systematic form of problem solving that involves four steps: 1) “decomposition” where a complex problem is broken down into smaller, more manageable problems, 2) “pattern recognition” or making predictions by finding similarities and differences between the broken down components, 3) “abstraction” developing general principles for the patterns that emerge, and  4) “algorithm design”, creating step-by-step instructions to solve not only this problem but other similar problems in the future, (Google School, 2016). By engaging in computational thinking, “students develop and employ strategies for understanding and solving problems in ways that leverage the power of technological methods to develop and test solutions, (ISTE, 2017).  In other words, the key to successfully following this process is that students develop their own models rather than simply applied existing models, (Google School, 2016).

Figure 1.1 Components of Computational Thinking
Figure 1.1 Components of Computational Thinking

In researching ways to apply computational thinking in the classroom, I ran across scholarly articles discussing the gamified classroom. I have always been intrigued with this concept, from my own experience students are so much more engaged during class time when the required content is converted into a game.  During these game sessions, my role changes from the the person delivering the content, to the person delivering the game (i.e. asking the questions).  The students are responsible for providing the content by providing solutions to the posed questions, thereby evoking problem-solving skills and in some cases, critical thinking skills. This idea-thread then led me to think “what are some ways that a “gamified” classroom can help develop computational thinking?”

To help answer my question, I came across two articles that pinpointed models in game-design to build computational thinking:

Article 1: Yang & Chang, 2013. Empowering students through digital game authorship: Enhancing concentration, critical thinking, and academic achievement.

Yang and Chang explore how students can increase their motivation for learning when they are allowed to design their own game given a specific topic.  During the game design process there is significant problem-solving that occurs because of the interaction and the immediate feedback the process entails.  In addition, students gain high order thinking such as building creativity, and critical thinking. The authors mention three game building software that does not require extensive coding skills: RPG Maker, Game Maker, and Scratch. During their study, the researchers investigated the effects of game design process on seventh grade biology students that were using either Flash animation (digital flash cards)  or RPG Maker.  The investigated effects included concentration, critical thinking, and academic performance. Their result demonstrated that the group using the RPG maker had significant improvements on critical thinking and academic performance, while no significant difference was noted on concentration for both groups.

Article 2: Kazimoglu, et. al., 2012.  A serious game for developing computational thinking and learning introductory computer programming.

Kazimoglu et. al. begin their inquiry by providing a few definitions.  It is important to understand the terminology they use, mainly defining any game used for educational purposes as a “serious” game.  They acknowledge that several definitions of computational thinking exist so they create their own definition that require the following elements: 1) conditional logic (true vs. false conditions); 2) building algorithms (step-by-step instructions); 3) debugging (resolving issues with the instructions); 4) simulation (modeling); and 5) distributed computation (social sharing). The authors are challenged to create a non-threatening introduction to programming unit to combat common student perception that programming is “difficult.” Kazimoglu et. al. believe that when students are allowed to engage in game design, they are motivated to learn which provokes problem solving. They take this approach to their introduction programming class where they challenge students through a series of exercises using the Robocode platform. At the end of the study, all students successfully completed the exercise, engaging in problem-solving skills.

Conclusions. Interestingly, both of these articles struggle to exactly define “computational thinking” and both mention that specific research investigating the extent to which games can develop CT is lacking.  However, what both can agree on is that CT is best developed when students are the game designers.  In order to do this, both studies involved elements of programming instruction to help students successfully build their games.

While these articles offer models into successfully implementing computational thinking through game design and creation, it was a little disheartening to discover that programming instruction was a necessary component. My inclination was to think how can these processes be implemented and/or adapted in other classroom scenarios particularly when programming instruction may or may not be feasible.  Interestingly, not all researchers agree that programming need be involved in successful CT implementation. Voogt et. al. argue that although most research on CT involves programming, because CT is a thinking skill,  it does not require programming in order to be successfully implemented, (Voogt et. al., 2015). In fact, in a literature review conducted by Voogt demonstrated that students do not automatically transfer CT skills to a non-programming context when instruction focused on programming alone. The strongest indicator of CT mastery was actually heavily dependant on instructional practices that focuses on application, (Voogt et. al., 2015).

The lack of a standard definition of computational thinking also needs to be addressed. The two articles above and the Voogt researchers agree that discrepancies exist among current definitions of computational thinking.  To avoid confusion regarding the role of programming and other such technologies, computational thinking can be simply defined as a way of processing information and tasks to solve complex problems, (Voogt et. al., 2015).  It is a way to look at similarities and relationships between a problem and follow a systematic process to reaching a solution.  Figure 1.2 summarizes this simplified process.

Figure 1.2 Simplified Computational Thinking Components
Figure 1.2 Simplified Computational Thinking Components

According to this new context, it is not necessary to program games in order for students to build computational thinking.  Allowing students to participate in systematic artifact creation will do the trick.  Some examples of artifact creation without the use of programing include: remixing music, generating animations, developing websites, and writing programs.  The main idea of this artifact creation process is that students follow procedures that can be applied to similar problems. Figure 1.3 highlights this artifact creation process.

Figure 1.3 Artifact Creation Process for Computational Thinking
Figure 1.3 Artifact Creation Process for Computational Thinking

How can this artifact creation process be used in creating gamified classroom?  To help me explore this issue, one of my colleagues suggested allowing students to develop and design their own board game. While the solution seems low-tech, others agree with this strategy.  Michele Haiken, an educational leadership for ISTE, writes about adapting “old school” games for the classroom to help develop critical thinking and problem solving skills, (Haiken, 2017).  Students can even create an online “quest,” scavenger hunt, or create a “boss event” to problem-solve computationally, (Haiken, 2017).  For more tech-y solutions, existing platforms and/or games such as GradeCraft and 3DGameLab can be used to  apply computational thinking in a gamified classroom, (Kolb, 2015). Regardless of the method used, low-tech board games or high-tech game creation through programming, allowing students to participate in the artifact creation process helps to build computational skills that they can then apply to other complex problems to create their own models.

References

Google School, (2016). What is computational thinking? [Youtube Video]. Retrieved from: https://www.youtube.com/watch?v=GJKzkVZcozc&feature=youtu.be.

Haiken, M., (2017).  5 ways to gamify your classroom. Retrieved from: https://www.iste.org/explore/articledetail?articleid=884.

International Society for Technology in Education, (2017).  The ISTE standards for students. Retrieved from: https://www.iste.org/standards/for-students.

Kazimoglu, C., et. al., (2012). A serious game for developing computational thinking and learning introductory computer programming. Procedia-Social and Behavioral Sciences, 47, 1991-1999.

Kolb, L., (2015). Epic fail or win? Gamifying learning in my classroom. Retrived from: https://www.edutopia.org/blog/epic-fail-win-gamifying-learning-liz-kolb.

Voogt J, et. al., (2015). Computational thinking in compulsory education: Toward an agenda for research and practice. Education and Technologies, 20(4), 715-728.

Yang, Y. C., & Chang, C. (2013). Empowering students through digital game authorship: Enhancing concentration, critical thinking, and academic achievement. Computers & Education, 68(c), 334–344.

Innovation Through Using Problem-Based Learning

Whenever I think of the word “innovation,” I am reminded of the bear, honey, and powerline story. If you are not familiar with this story, I’ll offer a brief synopsis here, though there are other detailed versions available.

Employees of a powerline company met to brainstorm the issue of snow and ice accumulation on power lines which would down the lines in winter months. Despite formal, morning-long brainstorming, the session yielded little results. Frustrated, the team decided to take a short break. While on break, a few of the team members began to talk over coffee where one team member reminisced about how he got chased by a bear while out servicing the lines. After a good laugh, other team members jokingly suggested that they get bears to remove the snow/ice by placing honey pots on top of the powerlines. Continuing the joke, one team member suggested that they use helicopters to place the pots.  This idea was put to rest as another team member mentioned that the vibrations from the helicopters would scare the bears. Suddenly they realized they had a great solution on their hands, the company could use helicopters to remove the snow/ice through the force and vibrations caused by the helicopter blades. Because of this impromptu brainstorming session, using helicopters to remove snow and ice from powerlines is a common practice today.

diagram of a bear, honey, and a helicopter facilitating innovation.
Figure 1.1 A bear, honey, and a helicopter for innovation.

I like this story because it dispels the misconception that to be innovative you must create something new, like a product or a service.  Instead, innovation can be a way to problem solve. Much like the process that unfolded in the bear story, students should be encouraged to problem solve in creative ways.  By offering students opportunity to seek, identify, and apply information, they are building cognitive flexibility, a 21st century skill, (Kuo et. al., 2014). Cognitive flexibility encourages the development of creativity needed for innovation, a concept that involves the ISTE innovative designer standard where “students use a variety of technologies within a design process to identify and solve problems by creating new, useful or imaginative solutions,” (ISTE, 2017).

So then, how do you get students to begin thinking less about the “correct answer” and more “bears, honey, and helicopters” for innovation? This can be particularly difficult when students historically have been offered a “right” and “wrong” depiction of problems. Students can be “eased” into creativity through scaffolding using the systematic thinking concept of the creative problem solving model, (Kuo et. al., 2014). A summary of the model can be found in figure 1.2 below.  

Diagram of the Creative Problem Solving Model
Figure 1.2 The Creative Problem Solving Model

The creative problem solving model transitions students between understanding a problem, generating ideas about the problem, and finding solutions to that problem, (Kuo et. al., 2014).  The students evolve their thinking from identification to more complex thinking, ultimately evoking creativity and innovation.

While the creative problem solving model can be used to build cognition through various problem-solving steps, problem-based learning (PBL) can help format the classroom to help achieve self-directed learning. An instructor can start with any question-type from the creative problem solving model and allow students to work through that question with PBL.  The general process for designing a problem-based classroom is demonstrated in figure 1.3 below.  

Diagram depicting the Problem-Based Learning Process
Figure 1.3 The Problem-Based Learning Process

According to the National Academies Press, a PBL activity focuses on student-centered learning where the instructor is a facilitator or guide and the students work together to gather information, then generate ideas to solve the problem. The problem itself becomes the tool to obtain knowledge and develop problem solving skills, (National Academies Press, 2011).  PBL is not without its faults, in using PBL, students have slightly lower content knowledge than in the traditional classroom and students in a group may not share the same level of cognition, (National Academies Press, 2011).  Despite this, students engaging in PBL have a higher retention of content than in traditional classrooms, are better able to apply their knowledge, and have a deeper understanding of the content, (National Academies Press, 2011).

Putting the Theory into Practice: The Investigation

Several of the classes that I teach are content-based/coverage-based classes. These classes are designed to be foundational, meant to prepare students for higher level or more in-depth, application-based classes later on. As I was thinking about problem-based learning, I started wondering: “how can we fully expect students to become problem-solvers and apply content in more advanced classes when all they are expected to do is identify a concept in these foundational classes”?  Students really don’t understand the importance of a particular topic because the idea of application and innovation isn’t introduced until they are in another class.  To help give these coverage-based classes more meaning to the students now, I am considering applying more PBL-based activities to directly replace coverage-based activities. My investigation leads me develop the two guiding questions below that will help me gather ideas on how to solve this problem. I realize that I am essentially engaging in my own PBL.

Question 1: What are some examples of problem-based, or “idea-finding” class activities that better support student learning in coverage-based classes?  One resource that addresses this question is from the National Academies Press who published a summary of two workshops conducted in 2011 on “Promising Practices in Undergraduate Science.” The selected chapter (Chapter 4) summarizes the benefits of problem-based learning and describes 3-methods that show promise in content-heavy classrooms. Additionally the chapter provides templates or guiding principles for problem based activities, case-scenarios, and complex problems that are clear, concise, and general enough that they can be applied to various assignments or learning activities.  However, this chapter does not address specific examples to use as a model.  Despite this, the chapter is supportive in building theory and gathering initial ideas for PBL in the classroom. Another resource that may help address this question comes from the The Creative Classroom Project.  The project is a website created by the Eramus project led by university lecturers in Estonia specializing in digitally-enhanced learning scenarios.  The website/blog provides not only offers theory-based ideas but actual examples of the various methods that use PBL.  The professors call the various PBL methods “learning scenarios” and base their work off of a “trialogical learning design.” Though most of the examples are for primary and secondary education, the formatting  is helpful in brainstorming similar scenarios for higher education.

Question 2: How/can ICT be used to enhance learning in those above examples? To be honest, I was not sure I would find very many examples on how to apply technology in PBL.  I was quite mistaken.  Depending on the goal or scope of the learning activity, a multitude of tech apps and websites can be applied to the various PBL methods. Here are just a few examples of tech resources that can be used with PBL:

  • LePlanner lesson plan templates from the Creative Classroom Project. This resource provides several examples of specific tech such as padlet, pearltree, and mindmiester, that can be used to enhance classroom activities. The templates also provide lesson plans (via LePlanner software) which includes description of objectives, class activities that meets the objectives, and even includes timelines for each activity.
  • Digital storytelling corresponds with the case-studies (case scenario) PBL method. According to the National Academies Press chapter, one of the justifications for using case studies is that it is a form of storytelling.  Storytelling helps students learn by integrating knowledge, reflecting on ideas, and later articulating them while considering various perspectives, (National Academie Press, 2011).  Digital storytelling is a way to introduce technology as a problem-solving tool and helps students express their various perspectives. This digital storytelling resource offers background information about digital storytelling, the seven elements of storytelling, and resources (tech solutions) can be explored. I had never considered using blogs, pinterest, and other such social media resources for the purposes of digital storytelling.

The Next Steps.

This investigation has been a great first step in generating ideas for implementing more PBL activities into my content-intensive courses. There seems to be an endless world of possibilities for  integrating technology to develop creative solutions and innovation in the classroom. What I find interesting is that my findings mirrors that of the bear, honey, and helicopter story.  I discovered that coming up with a solution to my questions doesn’t involve reinventing the wheel, but rather considers ideas/products that already exist and using them in creative ways.  For example, I would have never considered using the Pinterest app or even Google Docs as a creative solution to digital storytelling.  Nor would I have considered that developing good problem-solving skills for students simply involves asking the right questions.

My process doesn’t end here. If I choose to implement PBL, the next steps will involve the six-step process highlighted in this article to successfully design, implement, and evaluate problem-based learning.  I need to carefully consider the major objectives of my course(s) and the amount of time needed for this process.  As suggested by the National Academies Press, successfully implementing any of the PBL methods takes time which may not always be a luxury in coverage-based classes. Before moving forward, I need to understand that I would not be able implement PBL with every topic but must carefully select activities that would help solidify the major objectives of the course.

My colleagues and professors have also suggested using alternative models such as the  human-centered design or Kathleen McClaskey’s Continuum of Choice (see figure 1.4 below).

Diagram of the Continuum of Choice.
Figure 1.4 McClaskey’s Continuum of Choice. (Continuum of Choice TM by Barbara Bray and Kathleen McClaskey is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License available at: https://creativecommons.org/licenses/by-nc-nd/4.0/.)

I would need to investigate which design model best fits with specific course needs as well as brainstorm what questions need to be asked in order for problem-solving to be effective. Perhaps the answer to these questions will be course-specific and may require the use different models for different activities to further promote cognitive flexibility.

References

International Society for Technology in Education, (2017).  The ISTE standards for students. Retrieved from: https://www.iste.org/standards/for-students.

Kuo, F.-R., Chen, N.-S., & Hwang, G.-J. (2014). A creative thinking approach to enhancing the web-based problem solving performance of university students. Computers & Education, 72(c), 220–230.

National Academies Press. (2011). Chapter 4: Scenario-, problem-, and case-based teaching and learning. In National Academies Press, Promising practices in undergraduate science, technology, engineering, and mathematics: Summary of two workshops.(pp. 26-34.) Washington, DC. DOI: https://doi.org/10.17226/13099.

Pata, K. (2016). Problem-based learning in task-based and inquiry-based scenarios. [Blog] Retrieved from: https://creativeclassroomproject.wordpress.com/creative-classroom-collection/problem-based-learning/