LIBRARY SUBSCRIPTION: Guest
1 Strada Institute for the Future of Work, Atlanta, GA
2 Georgia Tech Professional Education, Atlanta, GA
3 Center for 21st Century Universities, Georgia Tech, Atlanta, GA
4 College of Computing, Georgia Tech, Atlanta, GA
*Address all correspondence to: Robert S. Kadel, Strada Institute for the Future of Work, 10 W. Market Street, Suite 1100, Indianapolis, IN 46204; Tel.: (+1) 317-806-1243, E-mail: rob.kadel@stradaeducation.org
Fifty-five educators from around the country convened on the Georgia Tech campus in November 2018 to discuss the concept of scalable advanced learning ecosystems (SALEs) (Kadel, R.S., Finding the Right Wavelength: Scalable Advanced Learning Ecosystems, Int. J. Innovations Online Educ., vol. 2, no. 2, https://onlineinnovationsjournal.com/streams/editor-s-choice-articles/0791c5ee61f00a91.html, 2018). The purpose was to identify the overarching issues that would need to be addressed in creating a system of learning that was both highly personalized and scalable online. Five themes emerged from the summit: (i) enhanced learner agency; (ii) transformation of instruction, assessment, and the faculty role; (iii) rethinking accreditation, financial aid, and the credit hour; (iv) moving toward a complex and interconnected technical infrastructure; and (v) affordability and determining return on educational investment. This paper illuminates these five themes. Funding for the summit was provided by the National Science Foundation under grant DRL-1824854 (Synthesis and Design Workshops).
KEY WORDS: scale, scalability, ecosystem, learner agency, instruction, assessment, accreditation, financial aid, credit hour, technical infrastructure, affordability, return on educational investment
In November 2018, an article by Kadel (2018) was published in the Editor’s Choice stream of this journal on scalable advanced learning ecosystems (SALEs). That article served two purposes. First, it was a thought piece on the necessity of thinking about scalable online learning as an ecosystem of platforms and tools that need to work seamlessly in order to provide a consistent learner experience. Furthermore, it would provide instructors and administrators flexibility in the tools they need to deliver learning effectively, whether fully online or in a blended format. Second, the article was a preview of a summit, sponsored by the National Science Foundation (grant no. DRL-1824854 [Synthesis and Design Workshops]), that sought to bring together educators from around the country to collaborate on ideas for SALEs. Fifty-five attendees came together on the Georgia Tech campus on November 29 and 30, 2018 to create a road map for creating SALEs.
This paper, a follow-up to the original article, will illuminate some of the major themes that emerged from the SALE summit. (A full accounting of the conference is expected to be published as a white paper through NSF in 2019.) The summit was organized around five working groups: business models; technical infrastructure; immersive learning, such as augmented and virtual reality; artificial intelligence and personalization; and research, assessment, and insights. Each of the groups was tasked with a series of questions to consider and asked to use those questions to create visions for the future of a SALE in 1–2, 3–5, and 6–10 years.
In comparing these visions, both during the summit and in subsequent discussions, five major themes emerged that showed the overlap of the groups’ work. The following sections provide descriptions and examples of these major themes.
Although each workgroup identified various perspectives and characteristics of SALEs within their own domains, five major themes repeated across all these domains.
The most sweeping theme centered on the individual learner, who will have agency over what, how, when, and where he or she learns. That is, the learner will have some options for what courses constitute a degree or certificate program, whether those courses will be delivered online or in a blended format, what schedule for learning best fits the learner’s life, and what environment the learner chooses for completing coursework (from classrooms to coffee shops). To aid the learner in this journey, much attention was paid at the SALE summit to the role of artificial intelligence (AI). AI-based learning applications will continue to develop from being a “cognitive primer” to a “cognitive partner.” Whereas most AI applications currently in use are able to deliver information based on algorithms that predict what information a learner needs, AI apps of the future will be able to provide deliberate practice with feedback, either within an online learning management system or as standalone apps. For example, the online videos of the Georgia Tech OMSCS 7637 class on Knowledge-Based AI have about 150 problem-solving exercises built into them. Most of these exercises come with tutors who assess the student’s answer and provide explanations when it is incorrect (Goel and Joyner, 2017). The students have found these exercises and tutors both interesting and useful. Ou et al. (2019) presented a seven-principle model for designing instructional videos abstracted from this course.
In the future, AI apps will also act as a coach that assesses the level of learning, delivers content in ways that are tuned to each learner’s needs, and prompts the learner in order to measure competence. As those competencies are demonstrated, the learner’s transcript—we use that term loosely here—will reflect not only mastery of content knowledge across multiple learning outcomes, but also mastery of “human + skills” (Weise et al., 2018) in critical thinking, presentation, writing, collaboration, etc. These AI apps will be useful not only for online education but also for blended learning (Madden et al., 2019).
The shift to learner agency however is not limited to changes in instructional technology. Business models will also need to adapt. For example, how much will learners need to pay, and how will such monies be aggregated or disaggregated? The standard tuition model will need to be replaced with one that encourages payment according to each learner’s individual needs. Likewise, this would necessitate changes in financial aid, such as what counts as “full-time” enrollment, or enrollment in professional development courses rather than, or in addition to, credit-bearing activities, when the standard Carnegie unit may face its own set of changes.
Consequently, this could result in changes to revenue models. The logic based on a traditional view of higher education may conclude that, if learning is less defined by a specific degree program and more by competencies across a range of subjects, then revenue will likely decrease. If Student A would normally pay $40,000 for a four-year degree program, but she can give evidence of prior learning and finish in three years, then the institution only receives $30,000. Bradley et al. (2012) dispelled this myth in their discussion of the Prior Learning Model of competency-based education. The authors stated that revenues would not be negatively affected by changes in such education because the faster a student moves through the program, the sooner another student could be added. In other words, if Student A is given credit for prior learning, she will simply finish her program in three years instead of four. This would open up a spot for Student B to start, ensuring a steady stream of students enrolling at the institution. Furthermore, according to Bradley et al. (2012), such a model may be more attractive to students with on-the-job experience that can be applied to the program, thus increasing the number of students who would wish to be served by that program. Obviously, online programs with more generous or more nebulous concepts of “available seats” create additional flexibilities for competency-based, competency-oriented, or learner-led educational activities.
This emphasis on learner agency invigorates the domain of heutagogy, the study of self-determined learning. In a heutagogical approach to learning, learners are expected to be highly autonomous, owning the path to learning as well as the processes and the criteria for what will be learned and how (Hase and Kenyon, 2001). Learner agency and autonomy is also a source of caution, though (Gazi, 2014), for two major reasons: first, decisions about what to learn and how to learn can lead to gaps in competence, which may cause material loss or loss of lives. Hence, there should be multiple levels of accountability built into the learning experience to ensure that, independent of the choices learners make, the result of the learning experience is mastery of the essential learning outcomes. Second, personal autonomy and freedom of choice, foundational characteristics of adult learning as defined by Boyd (1966) and Anderson (2013), are primarily Western and democratic values. Hence, such freedoms need to be carefully examined with an open mind about their utility in a variety of global educational platforms and contexts.
As the learner’s experiences and choices dictate more and more of the learning process, it will also be necessary to change instruction to provide the best and most applicable knowledge and skills. One working group at the SALE summit spent considerable time looking at the value of immersive learning—augmented, virtual, and mixed reality. The goal of using such technology should be “to make the unfamiliar familiar,” said this group. Multiple studies have demonstrated the value of experiential learning [see, e.g., Kolb (2015)]. However, in-person experiential learning can be costly and is not scalable. Immersive learning provides an avenue to deliver to the learner experiences beyond the classroom, but wholly online in a simulated environment. A prime example would be walking the streets of Berlin during the 1961 construction of the wall versus the destruction of that wall in 1989. Students could learn about the politics, economics, culture, history, and unrest that ultimately brought down one of the greatest symbols of the Cold War.
Currently, virtual and augmented reality headsets are cumbersome and expensive. However, companies from Microsoft to Magic Leap are making great strides in reducing both the size and cost of these headsets, while also harnessing increased processor speed that will allow for better virtual experiences. With 5G networks (Techradar, 2019) and the new WiFi6 standard (WiFi Alliance, 2019) in the near term, it will be easier than ever to stream the tremendous amounts of data needed to render these virtual worlds at home, at school, or on the go. This will make AR/VR experiences less dependent on large desktop computers and massive local storage. The end result will be experiential learning that draws on a vast library of experiences and interactions but with reduced cost and increased availability for learners.
New ways of assessing student learning will work hand in hand with the adoption of immersive learning environments. Summative assessments, for example, can be redesigned to take place within a virtual world. These will reflect realistic scenarios and challenges and will provide case studies that are directly related to the careers students will have. As such, assessments will be chunked into smaller parts, evaluating knowledge in an episodic way. (We are already seeing this in many online courses, where content and assessments are interwoven to provide more quick, real-time feedback to the learner.) On the plus side, this allows for better real-time intervention for struggling learners. However, on the minus side, this process will make for a less holistic measure of learning, which must be addressed at some point in the learning process.
As the landscape of instruction, assessment, and administration changes, so too will employment. Instructors will need to be as flexible as the courses and programs that are being delivered to students. This could result in two significant changes: first, there may be less of a need for traditional instructional tasks. As instruction becomes more scalable through a variety of online systems, fewer faculty will be needed to deliver that instruction. However, this is not to say that the faculty role will become extinct. Faculty will continue to create the curriculum and be the owner of the digital learning environment; however, as many of the tasks of instruction will become more automated and scaled to larger audiences of students, the faculty role will shift to mentoring and facilitation of learning. Faculty will continue to be the authority on expected outcomes and how those outcomes are demonstrated and assessed. Although, even the most hardworking faculty member would not be able to meet all the needs of a class of 1,000 students. Therefore, and the second significant change, schools will need to hire more teaching assistants who can provide the day-to-day contact hours that students will need. As above, such services would be in addition to any automated instruction that the students receive regularly. One question the SALE summit participants asked along these lines is whether this will affect the number of graduate students who go on to earn their PhD rather than taking a full-time job as a teaching assistant. This remains an open question.
In the vast and often confusing landscape of postsecondary education, it is often difficult for students to know how to assign value to specific educational opportunities. If you think of higher education as an investment from which you later expect a positive return (see Section 2.5) then potential students need a way to evaluate the possible risks associated with that investment. In the world of finance, this is done partly through corporate credit ratings, and there are a handful of independent firms (e.g., Moody’s and Standard and Poor’s) that regularly publish such ratings. In higher education, a similar function is accomplished through accreditation. Accreditation is an attempt to guarantee quality and is a shortcut to making an informed decision as to the reputability of an institution. There are twenty-one institutional accreditors recognized by the U.S. Department of Education at the time of this writing in the United States, and a few dozen programmatic accreditors (U.S. Department of Education, 2019c). The Council for Higher Education Accreditation (CHEA) recognizes seven regional accrediting agencies (CHEA, 2019) and over 150 additional international organizations. There are at least 191 unrecognized accrediting agencies operating in the U.S. (Wikipedia, 2019). The U.S Department of Education database of accredited campuses contains over 31,000 entries, including multiple campuses belonging to the same institution (U.S. Department of Education, 2019c).
When the accreditation space is overwhelming even to those of us in higher education, how can learners be expected to make sense out of it? Despite the best efforts of policy makers, accrediting agencies, and institutions, accreditation has been, and very much still is, a resource-intensive administrative activity that repels most higher education faculty. Accreditation’s focus on controlling change to maintain the evaluated and certified quality makes it notorious for its rigidity to allow for educational innovation. Having said that, we also see incredible examples of innovation in the higher education space within the restrictions of regional accreditors. For example, Georgia Tech’s affordable master’s degrees at scale (in computer science, analytics, and cybersecurity) (McKenzie, 2018), Arizona State University’s Global Freshmen Academy (Arizona State University, n.d.), and edX’s MicroMasters credentials (edX, n.d.) were launched in partnership with elite institutions that provide pathways from open and free courses to degrees.
One of the biggest challenges to creating SALEs with any sort of flexibility in courses and degrees is the credit hour (Carnegie Unit). The overreliance on the credit hour as a measure of learning has resulted in definitions of courses (three credit hours), degrees (e.g., 120 credit hours for a bachelor’s degree), and so on. Federal financial aid—and many employer-based programs—are tied to the credit hour, where in order to qualify, the learner must be taking at least 12 credit hours per semester. However, if learning and instruction are changed such that students enroll in micro-courses, service-based learning, or competency-based learning (to name just a few examples), the credit hour becomes a limiting definition of learning. For example, a credit hour is supposed to represent one hour of faculty–student contact time per week during a 15-week semester. If courses at the same institution run on 4-, 5-, 10-, and 15-week schedules, the credit hour is not flexible enough to be a measure of learning in all of them. Furthermore, in competency-based programs, where faculty–student contact time may be different for each student depending on their incoming competencies, how does the credit hour apply equally to all?
In late 2018, the Department of Education initiated a rulemaking process that intended to address several issues, including the credit hour (U.S. Department of Education, 2019a). The proposed language for the credit hour would replace the existing definition as “defined by an institution and approved by the institution’s accreditor and is based upon an amount of work, a unit of time spent engaged in learning activities, and/or a set of clearly defined learning objectives or competencies” (U.S. Department of Education, 2019b, p. 2). This new definition removes credit hour/clock hour equivalency and is poised to open a new approach to institutional eligibility for financial aid. Although these are initial proposals, they give us an idea of how the Department of Education intends to change accreditation, providing clarity around the credit hour and regular and substantive interaction, and providing pathways for innovation. The rulemaking process will be open for public comments and ideas.
One possible idea is suggested in the report of the Georgia Tech Commission on Creating the Next in Education (Office of the Provost, 2018). This report proposes a new unit for recording student learning based on achievement instead of a fixed time in which the achievement must happen. Called the “Dewey Unit” after John Dewey, this unit measures experiential learning that may happen in or out of the classroom. Students will be able to get credit not only for formal classroom accomplishments but also for more informal learning activities that may happen in small increments and in a wide variety of settings. Switching to credit being experience-based rather than time-based allows students to have much more agency in creating a personalized learning journey that is also more readily amenable to credit transfer and financial aid.
In 2013, Rob Abel (IMS Global), Malcom Brown (EDUCAUSE), and Jack Suess (University of Maryland Baltimore County) had an article published in EDUCAUSE Review titled, “A New Architecture for Learning” (Abel et al., 2013). The article served as a “call to action” for information technology managers to collaborate on and adopt a set of standards that would allow for agility, flexibility, and personalization across the range of educational platforms and applications that support learning. That article also served as one of the precursors to terms common in educational ecosystems today, such as Learning Tools Interoperability (LTI) (IMS Global, 2019a) and Next Generation Digital Learning Environments (NGDLEs) (Pomerantz et al., 2018). NGDLEs are, in their core, ecosystems; dynamic, interconnected, ever-evolving communities of learners, instructors, tools, and content (Feldstein, 2017).
We view NGDLEs as one major part of the SALE landscape. To a large extent, the NGDLE would address technical infrastructure needs and standards that range from application integration, such as: (i) making it easy to ingest data from all platforms by adhering to standards like Caliper or xAPI, (ii) allowing content to be easily transportable between platforms using Common Cartridge or SCORM, (iii) enabling instructional teams to expand functionality and tighten integrations using LTI or open APIs, and (iv) enabling personalized learning through a highly flexible framework that encourages instructors to mix and match or plug and play components (Lisle and Gazi, 2019).
A major challenge to the idea of demonstrating mastery of both content and skills will be in how that information is shared with employers, other schools, or anyone who has an interest in what a student is able to do. IMS Global has proposed the “Comprehensive Learner Record” (CLR) (IMS Global, 2019b) now making headlines (Shendy et al., 2019). The CLR is envisioned as a collection of skills, experience, abilities, competencies, etc., that provide much more granular detail about what (and how) a student has learned. Technology infrastructure is expected to support a comprehensive learner record, similar to how healthcare systems are investing in electronic health records for patients. Thus, as a learner swirls in an and out of educational activities throughout their lifetime, no matter how many different institutions touch the learner and the type of credentials and competencies are achieved, there is a coherent and comprehensive record of activity that is owned by the learner. Data would be collected with the student’s permission and gathered into a repository that can be shared with anyone the student deems should have access to the information. It would further be customizable so that the student can share relevant information, depending on the recipient’s needs. Georgia Tech is making a push into the CLR where such information would be shared on the Blockchain (Office of the Provost, 2018). Other institutions, such as MIT (Newton, 2018), the Universities of Auckland and Melbourne (Browne and Manahan, 2018), UNESCO (Chakroun, 2018), and the entire nation of Malta (Tonin, 2019) are experimenting with sharing such academic credentials on the Blockchain.
Parents, students, companies, the federal government, etc., invest significant resources into postsecondary institutions with the expectation to receive some future benefit. Yet, increasingly, the ability of postsecondary institutions to deliver the expected return on investment has been called into question. For instance, a 2018 Gallup poll indicated that only 48% of U.S. adults expressed “a great deal” or “quite a lot” of confidence in higher education, which represents a 9% drop from the 2015 poll (Jones, 2018). Furthermore, Jones (2018) noted that “No other institution has shown a larger drop in confidence over the past three years than higher education” (p. 2). Whereas studies like this poll can and should alarm postsecondary educators, the results are undergirded by a complex system of expectations and metrics that are not aligned and present an inadequate view of postsecondary return on investment (ROI). Blagg and Blom (2018) emphasized this issue in their conceptual framework for ROI. For example, the first component of their model emphasizes that “the exact returns for an individual are highly uncertain and evolve over the years” (p. 2). The authors go on to emphasize that this uncertainty, in part, can be traced back to things such as variation in financial aid packages; the amount of time to graduation; earning variations by institutions, major, degree level, and earning variation; and variation in earnings by demographics and local economic conditions.
As the postsecondary community considers a future with SALEs, the community must recognize the considerable ROI challenges SALEs present. Considerable debate exists about the ROI of online learning (Protopsaltis and Baum, 2019). Furthermore, creating an ecosystem of platforms and tools represents a sizeable technology investment, with the benefits often not seen by the students whose tuition and fees are being invested. That being said, the investments made in SALEs are investments into the core mission of institutions, namely, learning and the learner experience. SALEs strive to allow institutions to more deeply acknowledge the individuality in ROI. SALEs that integrate systematic ROI investigation and reporting provide an opportunity to reshape the ROI debate, with parents, students, legislatures, donors, etc., becoming informed partners.
SALEs can achieve affordability through scale, as evidenced by Georgia Tech’s master’s degrees in computer science, analytics, and cybersecurity, all offered for under $10,000 for program tuition and fees. These programs collectively have almost 12,000 students as of Spring 2019. Master’s tuition at a fraction of the cost of the residential program at a top-ranked university, with essentially unlimited capacity makes a very compelling and exciting case for ROI.
The experts and practitioners from a variety of domains, whom we brought together under the auspices of the National Science Foundation and Georgia Tech, identified the broad themes that will achieve SALEs. It should not be surprising that learners, learning environment, policies, technological infrastructure, and business sense stood out from the rest of the issues and characteristics identified. These are broad themes to address in any digital learning environment. Having said this, the devil is in the details. SALEs pose significant challenges in terms of the rapid pace of technological advances that are promising yet still elusive and resource-intensive. They expose the vulnerabilities in terms of governance (of policy making, data, and faculty role, to name a few). More importantly, not all institutions can achieve scale in all subject areas. Therefore, it will be interesting to see unfold those who will emerge as leaders and establish themselves in certain fields.
Abel, R., Brown, M., and Suess, J., A New Architecture for Learning, EDUCAUSE Rev., September/October, pp. 88–102, 2013.
Anderson, W., Independent Learning, Handbook of Distance Education, Moore, M.G. and Anderson, W.G. (eds.), Mahwah, NJ: Lawrence Erlbaum, pp. 86–103, 2013.
Arizona State University, Global Freshman Academy, accessed May 2, 2019, from https://gfa.asu.edu/, 2018.
Boyd, R., A Psychological Definition of Adult Education, Adult Leadership, vol. 13, pp. 16–162, 1966.
Blagg, K. and Blom, E. Evaluating the Return on Investment in Higher Education: An Assessment of Individual- and State-Level Returns, accessed April 30, 2019, from https://www.urban.org/sites/default/files/publication/99078/evaluating_the_return_on_investment_in_higher_education.pdf, 2018.
Bradley, M.J., Seidman, R.H., and Painchaud, S.R., Saving Higher Education: The Integrated, Competency-Based Three Year Bachelor’s Degree Program, San Francisco: Jossey-Bass, 2012.
Browne, J. and Manahan, A., Everyday Digital – Business as Usual ‘The Good the Bad and the Ugly,’ Proc. of Groningen Declaration Network, Groningen, Netherlands, accessed April 19, 2019, from https://www.groningendeclaration.org/wp-content/uploads/2018/Presentations/04-19%20Joanna%20Browne%20Anthony%20Manahan%20Everyday%20Digital.pdf, 2018.
Chakroun, B., Global Dialogue on Recognition of Skills and Qualification Across-Borders, Proc. of Groningen Declaration Network, Groningen, Netherlands, accessed April 19, 2019, from https://www.groningendeclaration.org/wp-content/uploads/2018/Presentations/04-18%20Borhene%20Chakroun%20Global%20Dialogue.pdf, 2018.
Council on Higher Education Accreditation (CHEA), Regional Accrediting Organizations, accessed April 29, 2019, from https://www.chea.org/regional-accrediting-organizations, 2019.
edX, Micromasters Programs, accessed May 2, 2019, from https://www.edx.org/micromasters, 2019.
Feldstein, M., What is the Next Generation?, EDUCAUSE Rev., July-August, pp. 38–44, 2017.
Gazi, Y., Issues Surrounding a Heutagogical Approach in Global Engineering Education, Proc. of 121st Annual Conf. and Exposition: 360 Degrees of Engineering Education, Indianapolis, accessed May 2, 2019, from http://www.asee.org/public/conferences/32/papers/9938/view, 2014.
Goel, A. and Joyner, D., Using AI to Teach AI: Lessons from an Online AI Class, AI Mag., vol. 38, pp. 48–58, 2017.
Hase, S. and Kenyon, C., From Andragogy to Heutagogy, accessed January 2, 2014, from http://www.psy.gla.ac.uk/~steve/pr/Heutagogy.html, 2001.
IMS Global, LTI v1.3 and LTI Advantage, accessed February 27, 2019, from https://www.imsglobal.org/activity/learning-tools-interoperability, 2019a.
IMS Global, Comprehensive Learner Record, accessed February 27, 2019, from https://www.imsglobal.org/activity/comprehensive-learner-record, 2019b.
Jones, J. Confidence in Higher Education Down Since 2015, accessed April 27, 2019, from https://news.gallup.com/opinion/gallup/242441/confidence-higher-education-down-2015.aspx, 2018.
Kadel, R.S., Finding the Right Wavelength: Scalable Advanced Learning Ecosystems, Int. J. Innovations Online Educ., vol. 2, no. 2, accessed June 12, 2019, from https://onlineinnovationsjournal.com/streams/editor-s-choice-articles/0791c5ee61f00a91.html, 2018.
Kolb, D.A., Experiential Learning: Experience as the Source of Learning and Development, 2nd Ed., Upper Saddle River, NJ: Pearson, 2015.
Lisle, M. and Gazi, Y., Towards an Ecosystem of Platforms, Evolllution, accessed April 29, 2019, from https://evolllution.com/technology/infrastructure/towards-an-ecosystem-of-platforms-the-critical-importance-of-interoperability/, 2019.
Madden, A.G., Marguilieux, L., Kadel, R.S., and Goel, A., Blended Learning in Practice: A Guide for Practitioners and Researchers, Cambridge, MA: MIT Press, 2019.
McKenzie, L., Online, Cheap – and Elite, Inside Higher Educ., accessed February 27, 2019, from https://www.insidehighered.com/digital-learning/article/2018/03/20/analysis-shows-georgia-techs-online-masters-computer-science, 2018.
Newton, D., How Blockchain Will Come to Campus, Forbes, accessed June 12, 2019, from https://www.forbes.com/sites/dereknewton/2018/09/17/how-blockchain-will-come-to-campus/#334b1f6b488d, 2018.
Pomerantz, J., Brown, M., and Brooks, D.C., Foundations for a Next Generation Digital Learning Environment: Faculty, Students, and the LMS, ECAR, Louisville, CO, https://library.educause.edu/~/media/files/library/2018/1/ers1801.pdf, 2018.
Protopsaltis, S., and Baum, S. Does Online Education Live up to Its Promise? A Look at the Evidence and Implications for Federal Policy, accessed May 2, 2019, from https://mason.gmu.edu/~sprotops/OnlineEd.pdf, 2019.
Office of the Provost, Georgia Institute of Technology, Deliberate Innovation, Lifetime Education, accessed February 27, 2019 from http://www.provost.gatech.edu/cne-home, 2018.
Ou, C., Joyner, D., and Goel, A., Designing and Developing Video Lessons for Online Learning: A 7-Principle Model, J. Online Learning, in press, 2019.
Shendy, J.E., Grann, J., Leuba, M., Green, T., and Parks, R., 7 Things You Should Know About the Comprehensive Learner Record, EDUCAUSE Learning Initiative, Louisville, CO, https://library.educause.edu/resources/2019/1/7-things-you-should-know-about-the-comprehensive-learner-record, 2019.
Techradar, What is 5G? Everything You Need to Know, accessed March 6, 2019, from https://www.techradar.com/news/what-is-5g-everything-you-need-to-know, 2019.
Tonin, D., Malta Becomes First Country to Issue All Diplomas on the Blockchain, Coingeek, accessed February 27, 2019, from https://coingeek.com/malta-becomes-first-country-issue-diplomas-blockchain/, 2019.
U.S. Department of Education, Negotiated Rulemaking for Higher Education 2018-19, accessed May 2, 2019, from https://www2.ed.gov/policy/highered/reg/hearulemaking/2018/index.html, 2019a.
U.S. Department of Education, Institutional Eligibility Under the Higher Education Act of 1965, As Amended, accessed May 2, 2019, from https://www2.ed.gov/policy/highered/reg/hearulemaking/2018/600institutionaleligibility.docx, 2019b.
U.S. Department of Education, Database of Accredited Postsecondary Institutions and Programs (DAPIP), accessed April 29, 2019 from https://ope.ed.gov/dapip/#/agency-list, 2019c.
Weise, M.R., Hanson, A.R., Sentz, R., and Saleh, Y., Robot-Ready: Human+ Skills for the Future of Work, Indianapolis: Strada Institute for the Future of Work, 2018.
WiFi Alliance, Wi-Fi CERTIFIED 6, accessed March 6, 2019, from https://www.wi-fi.org/discover-wi-fi/wi-fi-certified-6, 2019.
Wikipedia, List of Unrecognized Higher Education Accreditation Organizations, accessed April 29, 2019, from https://en.wikipedia.org/wiki/List_of_unrecognized_higher_education_accreditation_organizations, 2019.
Joyner David A., Eicher Bobbie, Taking Stock of MOOCs and Credit Substitutability, 2022 IEEE Learning with MOOCS (LWMOOCS), 2022 Crossref
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