9.1 Introduction
Scholars have pointed out the problems of a knowledge-transmission paradigm of education rooted in industrialism, such as uniform teaching and learning, teacher-centric methods, standardized assessment, and learning by acquisition (Halverson & Collins, 2009). Higher education intuitions have explored new methods of teaching and learning with the integration of technologies to move away from knowledge-transmission to knowledge creation, and to provide students with more flexible learning opportunities through online technologies. The growth of online learning in the higher education sector has occurred through blending various learning approaches. Massive Open Online Course (MOOC) is one of the emerging approaches in higher education that leverages the openness of learning content for massive learners for the delivery of content and instruction. For the past decade, MOOCs have been transformed into several variations since the first appearance in the higher education sector. Brown (2018) suggests that MOOCs have gone through three waves. During the first wave, MOOCs were mainly used for marketing purposes to increase the institution’s visibility and to recruit more students. The second wave is to use MOOCs for lifelong learning, propelled by large-scale MOOC projects at a national level and a cross-institutional level. The third wave is to use MOOCs for credit recognition and continuing professional development pathways.
Despite such increasing variations of MOOCs in the higher education landscape, a little framework is available to unpack mechanisms that blend various learning experiences. In MOOCs, as portions of learning experiences are delivered partly through online modalities, various integrations can happen, affecting what students learn online and face-to-face. Further, MOOCs have been increasingly positioned as a platform to integrate formal traditional courses with informal learning experiences. Given this nature of variations in MOOCs, this chapter aims to present and discuss various ways of integrating formal and informal learning experiences through MOOCs. This chapter is structured to firstly provide theoretical understandings of various MOOCs in the higher education sector, and then to present the integration framework with discussions of respective research studies. In the integration framework, we mainly discuss three approaches: blended learning, flipped learning, and non-formal/informal learning. The chapter concludes with some suggestions for research directions that can inform future research on integrating formal and informal learning experiences through MOOCs in higher education.
9.2 Theoretical Foundation
9.2.1 MOOCs: Concepts and Features
MOOCs have provided innovative open learning environments since the term was first introduced in 2008 (Akgül, 2018; Littlejohn & Milligan, 2015). MOOCs have been derived from distance education but have more distinctive features as courses are completely online, free and open to anyone, and available to massive audiences (Atiaja & Gueerero, 2016; Iniesto, McAndrew, Minocha, & Coughlan, 2017). MOOCs were originated from the Open Educational Resources (OER) movement, which is a philosophy to offer educational opportunities to all through free content and courses (Atiaja & Guerrero, 2016). The original notion of this innovative approach is for open access to learning. Moreover, the socio-cultural trends accelerated through the development of web 2.0 technology and social networks promoted the emergence of connectivism as a new pedagogical phenomenon that emphasizes participating and interacting, sharing ideas, and developing new knowledge through the continual improvement of knowledge among learners on the open learning platforms.
MOOCs as the innovative educational stream have attracted much public attention since diverse groups of learners can benefit from open access with a formal educational structure, free or low cost, flexible learning process with preferred pace and place, social learning opportunities, and even earning certificates and credits from prestigious universities (Iniesto et al., 2017). From learners’ perspectives, there are a variety of motivations to take MOOC courses: to gain better understanding about a certain subject or topic, to explore a specific field of interest, to participate in social interactions, and to have fun and enjoyable experiences without any expectation of achievement and completion (Belanger & Thornton, 2013).
MOOCs have many advantages over traditional brick-and-mortar university models. First, MOOCs provide massive and diverse learners from all over the world with an opportunity to access open, free, and high-quality learning content (Abdelrahman, 2016). Second, MOOCs provide individual learners with an opportunity to personalize their learning in terms of topics, time, place, and methods (Morris, 2014). MOOC learners have different learning objectives and plan to utilize online courses according to their personal needs. In MOOCs, while some students aim to achieve a certificate by studying the entire weeks of content with assignments, other students plan to study a specific element and content that they are interested in. To support such different student needs, MOOCs have taken an open approach to increase the availability of on-demand course videos and flexible schedules (Lapworth, 2018). Third, at an institutional level, MOOCs can be a strategic driver to increase student recruitments through the increased visibility of institutions and can promote the accessibility of lifelong learning opportunities with flexible pathways to international alliances (Brown, 2018). Universities can expand curriculums and opportunities with cross-cultural knowledge and friendship around the globe for their students. Finally, MOOCs have recently evolved to use learning analytics to better identify student profiles and learning paths. As big data and intelligent technologies are advancing, learners’ self-regulation can be promoted through the automatic tracking of the frequency and patterns of learner engagement in MOOCs (Cha & Park, 2019).
9.2.2 Comparison of Traditional, Blended, and Flipped Learning
For a clear conceptualization of integrating MOOCs in higher education, we firstly contrast the characteristics (a) traditional instruction, (b) blended learning, and (c) flipped learning. First, traditional instruction can be described as a direct instruction approach, where an instructor mainly delivers a face-to-face lecture in a classroom. Students learn mainly through textbooks, lectures, and assignments in the classroom setting. It is important to acknowledge that direct instruction or an instructor-led lecture is not in itself good or bad. There is sufficient evidence that direct instruction is effective for delivering declarative knowledge to learners and for reducing cognitive load (Kirschner, Sweller, & Clark, 2006). Rather, the critics of direct instruction are associated with the lack of time devoted to high-order cognitive skills, such as applying, analyzing, and evaluating, since most of the class time is devoted to transmitting content knowledge in an instructor-centric mode (Kuhn, 2007).
Comparison of the main characteristics of various learning approaches (Thai et al., 2017)
Traditional learning | e-learning | Blended learning conditions | ||
---|---|---|---|---|
Blended learning | Flipped classroom | |||
Lecture | F2F | Online | F2F | Online |
Guiding questions | F2F | Online | Online | F2F |
Feedback | F2F immediate | Online delayed | Online delayed | F2F immediate |
Lastly, it is possible that in-class teaching of flipped learning remains an instructor-centered approach when instructors focus mainly on reviewing the content that learners have already learned through lecture videos before class. With that, the Flipped Learning Network (FLN) differentiates the concepts of flipped classroom and flipped learning. Flipping a class is a method of presenting lectures and supplementary materials in advance before class, as some instructors have already done in the past. The FLN suggests that although flipping a class can lead to flipped learning, it does not necessarily do so. For the proper implementation of flipped learning, the FLN suggests that instructors must incorporate the four pillars of F-L-I-P™, namely flexible environment, learning culture, intentional content, and a professional educator (Bergmann & Sams, 2014). In this study, we use the term flipped learning, following the definition by FLN, to refer to “a pedagogical approach in which direct instruction moves from the group learning space to the individual learning space, and the resulting group space is transformed into a dynamic, interactive learning environment where the educator guides students as they apply concepts and engage creatively in the subject matter” (Flipped Learning Network, 2014, p. 1). Flipped learning advocates learning experiences that engage learners in cognitive processes demanded in the real-world context. By moving much of the abstract learning outside of class and bringing in more practical activities into the class, this sequence of learning can better facilitate student engagement in high-level cognitive activities and knowledge integration.
9.3 Integration Framework
Credit recognition is an important consideration of MOOCs in higher education. Sandeen (2013) suggests that higher education institutions are entering the era of the hybrid MOOC called “MOOC 3.0 or hMOOC”, which indicates the increasing trend of integrating MOOCs into traditional academic programs or courses for academic credits. However, Chamberlin and Parish (2011) contend that students who receive credits from MOOCs tend to receive more benefits such as additional meetings and activities with the facilitator than non-credit students. If students choose to enroll in MOOCs due to the advantage of the flexible learning environment to earn academic credits, their behavior may not be fully encouraged by intrinsic motivation, but by external incentives to some extent. Hence, it is necessary to distinguish two types of MOOCs: (a) formal, certification-oriented participation in MOOCs where learning is primarily centered on receiving credits from MOOCs and (b) non-formal, professional development-oriented participation in MOOCs where learning is centered on the utilization of knowledge in real-world contexts.
Formal learning: learning that occurs in an organized structured environment and is explicitly designated as learning in terms of learning objectives, time, or learning support.
Informal learning: learning that results from daily activities related to work, family, or leisure. It is not organized or structured in terms of learning objectives, time, or learning support.
Non-formal learning: learning which is embedded in planned activities not explicitly designated as learning in terms of learning objectives, time, or learning support.
MOOC integration framework
Blended learning versus flipped learning
Lecture | Activities | |
---|---|---|
Flipped learning | Online | Face-to-face |
Blended learning | Face-to-face | Online |
In the following section, we review and discuss how MOOCs have been used in various integration approaches. Type 1 (fully online MOOC) is not discussed here since this chapter is interested in incorporating different learning components such as the combination of online and offline learning or formal and informal learning experiences. Our review of the existing literature reveals that three integration approaches are often used in the higher education contexts: (1) integrating MOOCs in blended learning, (2) integrating MOOCs in flipped learning, and (3) integrating MOOCs in non-formal and informal learning.
9.3.1 Integration Approach I: Integrating MOOCs in Blended Learning
The first integration approach is to utilize MOOCs in blended learning to supplement and/or replace some segments of courses and learning contents in traditional formal learning (Bralić & Divjak, 2016; National Research Council, 2012). Blended learning varies in concepts and models, depending on what form and mode are blended (Bryan & Volchenkova, 2016). In this chapter, blended learning is defined as a hybrid form of learning that integrates MOOCs into traditional brick-and-mortar classrooms by taking the benefits of MOOCs in flexible ways. While some researchers (e.g., Bergmann & Sams, 2012; Hung, Sun, & Liu, 2018) used flipped learning in the same sense as blended learning, flipped learning has been studied with its own specific purposes and characteristics. Therefore, we classify flipped learning as a separate integration approach rather than blended learning. In this section, we discuss how MOOCs have been used in blended learning, which combines different learning modes (e.g., integration of online and offline, integration of MOOCs, and traditional classrooms).
Summary of previous studies in the integration approach I
Reference | Methods | Subjects | Students | MOOCs platform and purpose | Major findings |
---|---|---|---|---|---|
Griffiths et al. (2015) | – Case study – Quantitative and qualitative data | – Art – Poetry – Genetics – Psychology learning – community – Information technology – Political science – English learning community A – Philosophy – Literature – English learning community B | – Undergraduates – Sizes ranged from 6 to 60 | Platform: Coursera – Content portion – Live public offering – Replace some lectures – Replace some content – Replace some of the course – Supplemental – As a common experience – Entirely online – Provide greater insight into subject – Provide context to the literature | – Faculty members identified six benefits of using MOOCs in blended learning – Student satisfaction in the blended learning group was significantly lower. They preferred face-to-face interaction with instructors |
– Case study – Quantitative and qualitative data | Discrete Mathematics with Graph Theory (DMGT) | – First-year masters students – Sizes differ in each term: 107 in 14/15 88 in 15/16 83 in 16/17 | Platform: Coursera – To give students more online learning experiences – To help part-time students who are not able to fully participate in campus-based courses | Positive – Provide regular knowledge assessment – Positive experience in online learning – Helpful for part-time students Negative – Student workload – Language barriers | |
Cornelius (2019) | – Case study – Quantitative and qualitative data | Africa: sustainable development for all | Undergraduates 88 students | Platform: FutureLearn – To provide an interdisciplinary opportunity for curriculum enhancement for first- and second-year on-campus undergraduates | Compared with the general undergraduate cohort, the blended learning cohort was more engaged in some items in learning with others, reflecting and connecting, staff-student partnership, etc., but less engaged in critical thinking and course challenge |
As another blended learning example, Bralić and Divajak (2016) conducted a case study about integrating MOOCs into a traditional course in a higher education context to demonstrate the qualitative effects on learning experiences of MOOCs as well as on learning achievements among part-time students through student’s learning diary. The learning diary consisted of eight open questions to identify the benefits of learning experiences, effects on learning achievement for the part-time students, students’ workload, and main challenges. The study revealed that the qualitative feedback and reflections from students were positive, especially in terms of self-paced learning and knowledge assessment on a regular basis. In particular, students recognized blended learning as a good approach taking the best of two modes since online learning was not highly motivating compared to face-to-face learning. However, they claimed that the main challenges were related to language problems and more time required to complete online MOOC contents.
Bralić and Divajak (2017) extended the study to trace student changes through three consecutive academic years and to see the effects of blended learning with MOOCs. They found that students who experienced blended learning wanted to take more MOOCs when they were given an option to choose either MOOCs or offline projects as assignments. Furthermore, they also reported that the former group who selected MOOCs as assignments achieved higher than those who selected an offline project as assignments. From the qualitative analysis, it was reported that most of the students had highly positive learning experiences with MOOCs such as opportunities with frequent evaluation and complementary learning experiences of what was taught in the offline class. The blended learning approach made students complete the online MOOC course and improved their self-efficacy. In addition, part-time students indicated that MOOCs helped them to adopt self-paced learning and met their individual needs.
Recently, Cornelius (2019) used a blended learning approach that replaced 6-week MOOC lectures, combining tutor-led tutorials and an independent study with additional materials. Quantitative and qualitative data were collected to analyze factors that might impact learner’s engagement through MOOCs. The survey results showed that students from the blended learning approach were more engaged in the aspects of learning with others, reflecting and connecting, research and inquiry, staff–student partnership, and skills development compared to those in the offline campus approach.
In addition, the qualitative results demonstrated that students considered MOOCs as a flexible way of learning with a variety of resources. In particular, active and social learning was achieved through authentic contents and examples shared by peers in the discussions forum. Overall, incorporating MOOCs into traditional classrooms as a blended learning approach has many advantages: enhancing learning by making learners engaged in varied expertise and other styles of teaching and learning activities as well as enriching teaching and learning resources. The blended learning approach can also reinforce learning experience by providing the flexibility of teaching and learning, supporting diversity, and improving efficiency (Sharpe, Benfield, Roberts & Francis, 2006). Indeed, students in the previous studies described self-control, flexibility, and diversity as positive features of the blended approach. However, as seen in low student satisfaction in some studies (e.g., Griffiths et al., 2015), it is crucial to consider how to employ MOOC contents in a blended context. That is, instructors should first consider how to integrate MOOCs into their formal education contexts since there are varied blended learning concepts and approaches.
9.3.2 Integration Approach II: Integrating MOOCs in Flipped Learning
The second and most prevalent integration is a flipped learning approach that integrates MOOCs into pre-class activities to promote student-centered learning during face-to-face in-class sessions (Hung et al., 2018). In general, flipped learning consists of pre-class, in-class, and after-class activities. Flipped learning originated from the idea of how instructors better utilize in-class time (Tucker, 2012). During the in-class time in flipped learning, it is crucial to have more interactions between peers and instructors through student-centered activities. To make the in-class time more interactive and student-centered, instructional video lectures are considered a powerful tool to replace teacher-led passive lectures. The concept behind flipped learning is to make students more actively engaged in learning, rather than passive participants in teacher-led lectures during the face-to-face in-class time (Bishop & Verleger, 2013). In this respect, MOOCs courses and videos can also play an important role in helping instructors transform such instructor-centric lectures to student-centric learning experiences.
Summary of previous studies in the integration approach II
Reference | Methods | Subjects | Students | MOOCs platform and purpose | Major findings |
---|---|---|---|---|---|
Bruff et al. (2013) | – Quantitative: survey – Qualitative: focused group interview | – Machine learning | – Graduate-level – 10 students in the focus group | Platform: Coursera – Purpose: to use it as part of the course – Design of flipped learning (1) Pre-class: MOOC lecture (10 weeks) (2) In-class: reading, seminar, discussion (3) Final 4 weeks: project | – Positive: as effective, informative, useful for self-paced learning, productive in-class discussions – Negative: misalignment between online and offline class |
Ghadiri et al. (2013) | Case study – Quantitative: exam – Qualitative: student’s reaction | – Introduction to circuit analysis | Undergraduates | Platform: edX – Purpose (1) To improve students’ passage rate (2) To shorten time-to-degree – Design of flipped learning (1) Pre-class: outside-of-class e-learning (2) In-class: F2F, team-based learning (3) After-class: follow-up activities | – Positive: supplementary materials, self-paced learning, and productive in-class activities – Negative: materials not corresponding to in-class materials, time-consuming, difficult online homework |
Holotescu et al. (2014) | Case study – Quantitative: analysis of student’s behaviors – Qualitative: open comments on pedagogical benefits of MOOCs | – Web programming | 70 undergraduates students | Platform: Cirip.eu and various MOOCs – Purpose (1) To allow students to be familiar with and analyze the MOOC trends (2) To enlarge knowledge of the course – Design of flipped learning (1) Pre-class: 10% of MOOC activities (2) In-class: discussions (3) After-class: portfolio development | – Positive: learner-centric teaching, self-paced learning with enhanced attention, openness, collaboration with peers, active learning, – Challenging: new tasks and skills required for instructors |
Dunn (2015) | – Qualitative: survey of students’ responses | – Statistics for engineering | 99 undergraduates students | Platform: Coursera – Purpose (1) Final-year students: maintain relevant skills with life-long learning (2) Cost-effective approach – Design of flipped learning (1) Pre-class: reading, video, quizzes (2) In-class: recap of concepts, worksheet, online submission and feedbacks | – Positive: supplementing traditional lectures and promoting self-directed learning – Negative: misaligned and irrelevant videos and assignments |
Three distinct phases for the flipped learning approach (Ghadiri et al., 2013)
Step 1. online outside-of-the class | Step 2. in-class team-based learning | Step 3. after-class activities |
---|---|---|
edX topical mini-lecture videos | Mental ramp-up period | Professor emails absent students with class materials |
edX online textbook | In-class mini-review lecture | Optional, friday, one-hour, F2F walk-in session |
edX problem sets | Group quiz | |
edX online lab experiments | Solution of group quiz | |
SJSU virtual discussion board | Individual quiz | |
Assessment handout for the next class session | Solution to the individual quiz | |
Preview for next class session |
Flipped learning approach with Coursera (Dunn, 2015)
Based on the literature discussed above in this section, we identified the common benefits of integrating MOOCs in flipped learning. First of all, productive in-class time is achieved by making students more actively engaged in discussions, projects, and exercise practices. Students have more opportunities to interact with their peers and/or instructors. Secondly, the role of instructors changed from a knowledge-giver to a knowledge facilitator. Thirdly, MOOCs play an effective role in replacing and supplementing traditional lectures and promoting self-directed learning. However, it was also revealed that MOOCs lectures and contents cannot completely replace in-class lectures because students reported misaligned and irrelevant videos and assignments in MOOCs (e.g., Bruff et al., 2013; Ghadiri et al., 2013). In addition, students were not highly satisfied with MOOCs due to more efforts and time they should devote. In particular, Holotescu et al. (2014) emphasized that instructors are required with new course-redesign skills and pedagogical tasks as a facilitator. Therefore, it is crucial to consider how MOOC components can be integrated into traditional learning contexts more effectively and efficiently and how instructors can play a facilitator role during the in-class time to make flipped learning more successful.
9.3.3 Integration Approach III: Integrating MOOCs in Non-formal and Informal Learning
The final integration approach is to adopt MOOCs for non-formal or informal learning in higher education contexts. This approach reflects the original goal of OER and MOOCs, which is to benefit learners who would like to study with free, open, and flexible participation at their preferred pace and location. In addition, since many popular MOOCs are associated with world-class higher education (Alraimi, Zo, & Ciganek, 2014), such disruptive potentials, which mean not only to create innovative opportunities but also to have potential threats (Kaltencher, Huesig, Hess, & Dowling, 2013), can expand opportunities for non-formal and informal learning
OECD (2010) defines that informal learning is not structured or organized, whereas non-formal learning is associated with planned learning activities, but is not explicitly designed in terms of learning purposes, learning schedule, or learning supports. European Communities (2001) suggest that the differences between non-formal and informal learning lie in the structuredness in learning experiences and intention from learners’ perspectives. Informal learning is more experienced-based learning, whereas non-formal learning is more intentional and structured. A common aspect of non-formal and informal learning is that learning does not necessarily lead to formal recognition such as degrees or certification. While some MOOC contents provide students with a structured syllabus, schedule, and certification, generally MOOCs do not force learners to such structured and certified learning experiences. Rather, MOOCs support learners to choose how, when, and in what ways they want to engage with flexible learning paths and goals. With the flexible nature of learning, MOOCs have attracted learners who have a variety of learning purposes and learning paths.
Summary of previous studies in the integration approach III
Reference | Methods | Subjects | Students | MOOCs platform and purpose | Major findings |
---|---|---|---|---|---|
Gillani and Eynon (2014) | – Case study – Pre and post surveys –Analysis of forum usage | – Business strategy | – 7,337 | Platform: Coursera Research purpose: (1) To explore the MOOCs use and learner’s activities (2) Demographic characteristics of students (3) Discussion patterns | – Majority of learners were well-educated, young adults from developed countries, and had prior knowledge on the selected course |
Alraimi et al. (2014) | – Quantitative: Partial Least Squares (PLS) | – No information | – 316 • Coursera: 178 • edX: 104 • Udacity: 34 | –Platform: Coursera, edX, Udacity – Research purpose (1) To identify factors that enhance an individual intention to continue using MOOCs | – Perceived reputation and openness of MOOCs were stronger predictors for learner retention than perceived usefulness and enjoyment |
Hone & Said (2016) | – Quantitative: Partial Least Squares (PLS) | (1) Management Information System (MIS) (2) Software skills | (1) 256 undergraduate (2) 245 postgraduate | –Platform: various MOOCs (Coursera, FutureLearn, Khan Academy, edX) – Research purpose: To explore the factors that influence MOOC completion and retention | – It was identified that the perceived effectiveness of the MOOC course contents affected learner retention |
Hood et al. (2015) | – Statistical analysis: Pearson correlation, t-test, factor analysis | – Introduction to data science | – 788 from 79 countries | –Platform: Coursera – Research purpose: To measure SRL in adult learners in informal learning contexts | – Learner’s current contexts and learning purposes influence their SRL |
Littlejohn et al. (2015) | – Statistical analysis: factor correlations – Interview with 32 students from 16 countries via Skype | – Introduction to data science | – 788 from 79 countries | – Platform: Coursera – Research purpose: To compares the narrative descriptions of behavior between learners with self-reported high and low SRL scores | – Intrinsic motivation and goals for high SRL-scored learners to develop knowledge and expertise in their workplace could lead to non-formal learning opportunities to select activities and contents according to their specific needs |
The absence of instructors and pre-determined structure in non-formal and informal learning settings requires learners to self-regulate own learning experiences (Hood, Littlejohn, & Milligan, 2015). Low completion rate is one of the main challenges that MOOCs faced (Jordan, 2014; Perna et al., 2014; Weller, 2014). Recently, researchers attempted to find factors that impact the completion of MOOCs and learner retention and to improve Self-Regulated Learning (SRL). For instance, Alraimi et al. (2014) found that perceived reputation and openness of MOOCs were stronger predictors for learner retention than perceived usefulness and enjoyment. On the other hand, Hone and Said (2016) focused on the factors related to MOOC features and user experiences that influenced learner retention in MOOCs and identified that perceived effectiveness of the MOOC contents affected learner retention. Another line of research into MOOC-integrated learning has focused on increasing the completion and retention rates by improving SRL strategies. Hood et al. (2015) found that learner’s current contexts and learning purposes influenced their SRL in a MOOC about data science by Coursera. It was revealed that students who aimed to receive a Higher Education (HE) qualification had significantly higher SRL than those who were not studying for a HE qualification. Further, students with expertise in the data science area showed higher self-efficacy and meaningful learning approaches and strategies than those without expertise in the area.
Littlejohn, Hood, Milligan, and Mustain (2015) compared behaviors between learners with high and low self-reported SRL scores. They found that the intrinsic motivation and goals for high SRL-scored learners to develop knowledge and expertise in their workplace could lead to non-formal learning opportunities to select activities and contents according to their specific needs. They discussed that open, flexible, and non-linear approaches, which are different from traditional learning with a linear progression, promote SRL for highly intrinsically motivated learners. They also suggested that the completion rate of MOOCs might not be the indicator of MOOC quality and value, and new forms of evaluation criteria specific to MOOCs should be developed.
Overall, from the literature review on the third integration approach, it was found that a diverse range of students has utilized MOOCs with the purpose of informal or non-formal learning. The demographic profiles and learner behaviors in MOOCs shown in some case studies may imply that well-educated and young students consider MOOCs as a complement to traditional formal learning. However, there is still uncertainty about how MOOCs can be replacing or integrated into traditional classrooms due to the characteristics of massiveness and flexibility (Marcus-Quinn & Clancy, 2015). Such flexible open learning contexts and massive learners have led to diverse teaching and learning paths and models. Furthermore, as MOOC platforms are rapidly growing around the world, the diversity of learners, learning objective, and learning behaviors are also getting expanded.
Due to such features, most research related to informal or non-formal learning through MOOCs was conducted with a case study method. Recent literature tends to deal with the completion and SRL problems in MOOCs (Marcus-Quinn & Clancy, 2015). Littlejohn et al. (2015) found that one of the important purposes, why learners utilize MOOCs, is to enjoy open and flexible learning experiences. The perceived reputation and effectiveness of MOOC contents similar to the traditional learning contexts appear to make learners complete the course and increase retention (Alraimi et al. 2014; Hone & Said, 2016). Therefore, to promote informal and non-formal learning through MOOCs, open and flexible learning experiences should be strengthened with high-quality contents.
9.3.4 Comparison Between Integration Approaches
Satisfaction and dissatisfaction factors in MOOCs (Gutiérrez-Santiuste et al., 2015)
Planning | Instructional design, choice of topics, course organization, number of participants, course duration |
Community | Social character, community and group work, sharing outside the platform |
Contents | Content, resources |
Technical | Technical/technological situations |
Participation | Level of involvement and contributions to the course |
Kursun (2016) evaluated the effect of credit on learners’ achievement, perceived intrinsic and extrinsic goal orientations, and perceived course value by comparing credit-bearing vs. non-credit-bearing students. While the study did not specifically focus on the integration of MOOCs, the results and implications from the study are meaningful in that the credit recognition is an important factor that universities should consider when integrating MOOCs into their traditional higher education contexts. The study found a statistically significant difference between two groups, indicating that credits influenced learner achievement, goal orientations, and perceived course values. The credit-bearing group showed significantly higher achievement scores, perceived goal orientation, and course values than the non-credit-bearing group.
Overall, comparative studies show that there are significant differences in student participation, engagement, motivation, goal orientation, course values, satisfaction, and barriers. Such findings from the comparison studies provide universities with insights on how to integrate MOOCs into own contexts. In particular, it is noteworthy that students encounter technical obstacles such as inadequate infrastructure, connection, and transmission due to the bandwidth problem, and poor functioning in online learning environments regardless of integration approaches. Universities need to deal with technical barriers when considering the integration of MOOCs into traditional offline learning. For instance, MOOC platforms should be user-friendly designed with interfaces and functions to facilitate smooth online learning experiences. A small unit of video lectures can be also considered to deal with bandwidth problems.
9.4 Conclusion
In this chapter, we discussed how MOOCs can be integrated in higher education, for both formal and non-formal/informal learning experiences. The development of large-scale MOOCs offered by elite institutions has propelled MOOCs into the mainstream. MOOCs represent the democratization of education, by making education more accessible to a wide range of learners. However, this chapter problematizes that little frameworks are available to unpack the complex potential of integrating MOOCs in higher education. With that, the integration framework proposed in this chapter considers learners’ purpose (e.g., for earning academic credits) and course structure (e.g., online vs. F2F). In this chapter, we mainly discussed three possible integration approaches: (a) integrating MOOCs in blended learning, (b) integrating MOOCs in flipped learning, and (c) integrating MOOCs in non-formal/informal learning. We then discussed some related research for the respective integration approaches to provide better understandings about how MOOCs can be integrated into various contexts of higher education.
The review of related literature revealed some limitations in the existing research studies. First, authors tend to use terms loosely, such as using blended learning and flipped learning in an interchangeable way while there are clear differences between the two approaches. Second, we found that there are few empirical studies conducted on this topic, and many of them adopted a case study approach. Methodologically, there is a need to conduct more empirical studies that investigate the potential and challenges of integrating MOOCs in higher education settings. Third, we suggest that higher education institutions may need to take cautious steps in offering MOOCs to fee-paying students for academic credits. Given that the initial goal of MOOCs was to reach out to a wider range of learners, including learners in disadvantaged areas and conditions, the increasing trend of offering MOOCs to fee-paying students who are already in formal higher education may indicate that MOOCs are failing in the initial philosophy on “openness”. Indeed, it is true that such features of “openness” and “free” have led MOOCs to vivid arguments of the sustainability issues including dropout rates and cost. To make MOOC platforms more sustainable, both higher education institutions and MOOCs providers need to consider some possibilities of pricing strategies (e.g., cross-subsidy, third-party, freemium and nonmonetary) in MOOC business models (Baker & Passmore, 2016). However, MOOCs providers should also consider the balance between the original goals of MOOCs and sustainable strategies. In this respect, we believe that this chapter provides some insights concerning how MOOCs can be integrated into higher education to provide meaningful learning experiences for a wide range of learners.
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