Different types of badging platforms and technology
How to partner with industry to deliver in-demand competencies
Considerations for monetizing microcredentials
Current issues impacting badges during COVID-19
Identifying Badges that Add Value to Your Institution 11:30 a.m. – 12:30 p.m.
Our faculty will establish a shared terminology, discuss the benefits and challenges of various badges, and explain how each type can advance the goals of your institution and best serve students. You will share your purposes for pursuing a badging initiative, identify the types of badges that could add the most value to your institution, and set goals for the conference.
Designing Quality Alternative Credentials 2:30 – 3:15 p.m.
What goes into developing, designing, assessing, and maintaining quality microcredentials? In this session, you will learn about:
Standardization and rigor in development
Curriculum design and assessment
Developing a governance process
Continuous maintenance and improvement
Funding and Monetizing Badges 11:00 a.m. – 12:00 p.m.
Many institutions are looking into badging as a potential revenue stream during lean times. During this hour, you will learn strategies for monetization. We will also look at various fee-based and tuition-based funding models to financially operationalize microcredentialing.
Marketing and Branding 1:30 – 2:15 p.m.
How do you articulate the value proposition of badges to internal and external stakeholders? During this session you will learn how to brand and market your microcredentials. You will study badge images and stacking considerations that will help you create the best design for your circumstances.
Jeff Bohrer
Technical PM, IMS Global Learning
Jeff currently serves as a program manager for digital credentials initiatives at IMS Global Learning Consortium. Jeff leads projects and programs related to digital badges, comprehensive learner records, and the interoperability of learning technologies. Jeff is also co-chair of the EDUCAUSE Microcredentials and Badges Constituent Group.
Looking for different ways for students to share their knowledge. I’ve done Jamboard, Google Slides, Discussion posts, padlet…I just want something different and am not able to come up with any great ideas here. Anyone come up with anything else fun or interesting? This is for an asynchronous course.
In a time of growing and increasingly complex challenges, too many top administrators, leadership teams and boards are focusing on tactics rather than strategy
how should presidents begin to think strategically about the content and the pedagogy of the education their institutions will offer going forward? How should they lead their institutions to take concrete steps to eliminate systemic inequities on their campuses? How can they facilitate a commitment to combat racism not only on their campuses but also in their local communities and beyond? How can they manage all this as many face daily threats to their institution’s financial health?
Some of the presidents with whom I talked, along with several trustees and faculty members, have inspired the following suggestions for how at least some campus leaders may begin to think about the future.
Move even more online.
Rethink goals in light of demographic realities, concerns about costs and shifting student interests.
Reconceptualize and streamline institutional structures to better serve faculty and student realities.
Consolidate student support services.
Embrace the virtue of the out-of-doors.
Budget for mission, with long-term strategies in mind.
Address systemic racism, sexism, homophobia and other biases.
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Responding to Susan Resneck Pierce’s excellent Views piece, “Beyond Incrementalism.”
As we enter the Fourth Industrial Revolution (4IR), we must be vigilant to keep our classes relevant to the rapidly changing workplace and the emerging digital aspects of life in the 2020s.
deployment of 5G delivery to mobile computing
Certainly, 5G provides a huge upgrade in bandwidth, enabling better streaming of video and gaming. However, it is the low latency of 5G that enables the most powerful potential for distance learning. VR, AR and XR could not smoothly function in the 4G environment because of the lag in images and responses caused by a latency rate of 50 milliseconds (ms). The new 5G technologies drop that latency rate to 5 ms or less, which produces responses and images that our brains perceive as seamlessly instant.
A growing body of evidence has found strong consumer interest in recent months in skills-based, online credentials that are clearly tied to careers, particularly among adult learners from diverse and lower-income backgrounds, whom four-year colleges often have struggled to attract and graduate.
For years the demographics of higher education have been shifting away from traditional-age, full-paying college students while online education has become more sophisticated and accepted.
That has amplified interest in recent months among employers, students, workers and policy makers in online certificates, industry certifications, apprenticeships, microcredentials, boot camps and even lower-cost online master’s degrees.
Moody’s, the credit ratings firm, on Wednesday said online and nondegree programs are growing at a rapid pace.
Google will fund 100,000 need-based scholarships for the certificates, and said it will consider them the “equivalent of a four-year degree” for related roles.
Google isn’t alone in this push. IBM, Facebook, Salesforce and Microsoft are creating their own short-term, skills-based credentials. Several tech companies also are dropping degree requirements for some jobs, as is the federal government, while the White House, employers and some higher education groups have collaborated on an Ad Council campaign to tout alternatives to the college degree.
One of the most consistent findings in a nationally representative poll conducted by the Strada Education Network’s Center for Consumer Insights over the last five months has been a preference for nondegree and skills training options.
Despite growing skepticism about the value of a college degree, it remains the best ticket to a well-paying job and career. And data have shown that college degrees have been a cushion amid the pandemic and recession.
Experts had long speculated that employer interest in alternative credential pathways would wither when low employment rates went away,…. Yet some big employers, including Amazon, are paying to retrain workers for jobs outside the company as it restructures.
Abrizah, A., Inuwa, S., & Afiqah-Izzati, N. (2016). Systematic Literature Review Informing LIS Professionals on Embedding Librarianship Roles. Journal of Academic Librarianship, 42(6), 636–643. https://doi.org/10.1016/j.acalib.2016.08.010
identifies and documents embedding librarianship roles as reported in the Library and Information Science (LIS) literature.
Findings The roles of embedded librarians were identified, especially in the context of service delivery, all of which reported to be applied to academic libraries. Information literacy instruction, research and other scholarly activities, distance and online learning as well as embedding in classrooms, were described as ways of ensuring successful embedding librarianship. Implications The roles reported in the literature should inform practicing librarians contemplating embedding practices, guide formal embedded librarianship programs, and encourage other librarians to consider new skills in support of embedding roles.
p. 637 The idea behind EL model is to demonstrate librarians’ expertise asinformation specialists and to apply this expertise in ways that willhave a direct and deep impact on the research, teaching or otherworks being done (Carlson & Kneale, 2011).Carlson and Kneale(2011)pointed out that as librarians seek to redefine themselves, themodel of EL is generating interest as an effectual way of applying theknowledge and skills of librarians towards the information challengesof the digital age.
Faculty collaboration with the embedded librarian is the core of em-bedded information literacy instruction. Faculty-librarian relationshipbuilding is of great significance because the two must work closely to-gether over an extended period of time, it is essential that librarianschoose their partnership carefully. Several librarians stress the need towork only in partnerships where there is trust and mutual respect(Carncross, 2013). Librarians build these relationships in differentways, while collaborative relationship can be built in numerous ways,it is essential that bothparties have common goals and know the impor-tance of developing information literacy skills in their students. The most significant collaboration are from campuses in which librarian and university administrators have made information literacy a priority on campus, and have provided librarians and faculty with the time re-quired to make the collaboration successful (Cramer, 2013).
The embedded librarian is focused on course goals and learning objectives outside of the library and across the curriculum
The review designates that EL in courses, classrooms and depart-ments see librarians conducting the following specific tasks: teach stu-dents how to be savvy searchers using computer and laptops (Boyer,2015); collaborate where librarian and faculty member teach eachother, exchanging favors, and the librarian selecting useful resourcesfor the faculty (Ivey, 2003); take part in meetings to promote librarian’spresence and establish communication with the students, researchersand faculty (Jacobs, 2010); provide access to course-related library re-sources, in-class instruction sessions, library instructional handouts, in-formation on referencing style, library Webinar information as well asteach note-taking (Bezet, 2013).
The review shows that academic libraries that engage their distancelearning communities through an embedded librarian as online co-instructors to deliver technological applications such as instant messag-ing, e-mail, and wikis. This EL model facilitates direct interaction be-tween students and librarians regardless of physical proximity.Edwards and Black (2012)andEdwards et al. (2010)evaluated the pro-gram of embedded librarians in an online graduate educational technol-ogy course and found that students were helped with their onlineassignments.
Got a new open access article out on the ways AI is embedding in education research. Well-funded precision education experts and learning engineers aim to collect psychodata, brain data and biodata as evidence of the embodied substrates of learning. https://t.co/CbdHReXUiz
This article presents an examination of how education research is being remade as an experimental data-intensive science. AI is combining with learning science in new ‘digital laboratories’ where ownership over data, and power and authority over educational knowledge production, are being redistributed to research assemblages of computational machines and scientific expertise.
Research across the sciences, humanities and social sciences is increasingly conducted through digital knowledge machines that are reconfiguring the ways knowledge is generated, circulated and used (Meyer and Schroeder, 2015).
Knowledge infrastructures, such as those of statistical institutes or research-intensive universities, have undergone significant digital transformation with the arrival of data-intensive technologies, with knowledge production now enacted in myriad settings, from academic laboratories and research institutes to commercial research and development studios, think tanks and consultancies. Datafied knowledge infrastructures have become hubs of command and control over the creation, analysis and exchange of data (Bigo et al., 2019).
The combination of AI and learning science into an AILSci research assemblage consists of particular forms of scientific expertise embodied by knowledge actors – individuals and organizations – identified by categories including science of learning, AIED, precision education and learning engineering.
Precision education overtly uses psychological, neurological and genomic data to tailor or personalize learning around the unique needs of the individual (Williamson, 2019). Precision education approaches include cognitive tracking, behavioural monitoring, brain imaging and DNA analysis.
Expert power is therefore claimed by those who can perform big data analyses, especially those able to translate and narrate the data for various audiences. Likewise, expert power in education is now claimed by those who can enact data-intensive science of learning, precision education and learning engineering research and development, and translate AILSci findings into knowledge for application in policy and practitioner settings.
the thinking of a thinking infrastructure is not merely a conscious human cognitive process, but relationally performed across humans and socio-material strata, wherein interconnected technical devices and other forms ‘organize thinking and thought and direct action’.
As an infrastructure for AILSci analyses, these technologies at least partly structure how experts think: they generate new understandings and knowledge about processes of education and learning that are only thinkable and knowable due to the computational machinery of the research enterprise.
Big data-based molecular genetics studies are part of a bioinformatics-led transformation of biomedical sciences based on analysing exceptional volumes of data (Parry and Greenhough, 2018), which has transformed the biological sciences to focus on structured and computable data rather than embodied evidence itself.
Isin and Ruppert (2019) have recently conceptualized an emergent form of power that they characterize as sensory power. Building on Foucault, they note how sovereign power gradually metamorphosed into disciplinary power and biopolitical forms of statistical regulation over bodies and populations. Sensory power marks a shift to practices of data-intensive sensing, and to the quantified tracking, recording and representing of living pulses, movements and sentiments through devices such as wearable fitness monitors, online natural-language processing and behaviour-tracking apps. Davies (2019: 515–20) designates these as ‘techno-somatic real-time sensing’ technologies that capture the ‘rhythms’ and ‘metronomic vitality’ of human bodies, and bring about ‘new cyborg-type assemblages of bodies, codes, screens and machines’ in a ‘constant cybernetic loop of action, feedback and adaptation’.
Techno-somatic modes of neural sensing, using neurotechnologies for brain imaging and neural analysis, are the next frontier in AILSci. Real-time brainwave sensing is being developed and trialled in multiple expert settings.
Holland, B. (2020). Emerging Technology and Today’s Libraries. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 1-33). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch001
The purpose of this chapter is to examine emerging technology and today’s libraries. New technology stands out first and foremost given that they will end up revolutionizing every industry in an age where digital transformation plays a major role. Major trends will define technological disruption. The next-gen of communication, core computing, and integration technologies will adopt new architectures. Major technological, economic, and environmental changes have generated interest in smart cities. Sensing technologies have made IoT possible, but also provide the data required for AI algorithms and models, often in real-time, to make intelligent business and operational decisions. Smart cities consume different types of electronic internet of things (IoT) sensors to collect data and then use these data to manage assets and resources efficiently. This includes data collected from citizens, devices, and assets that are processed and analyzed to monitor and manage, schools, libraries, hospitals, and other community services.
Makori, E. O. (2020). Blockchain Applications and Trends That Promote Information Management. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 34-51). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch002
Blockchain revolutionary paradigm is the new and emerging digital innovation that organizations have no choice but to embrace and implement in order to sustain and manage service delivery to the customers. From disruptive to sustaining perspective, blockchain practices have transformed the information management environment with innovative products and services. Blockchain-based applications and innovations provide information management professionals and practitioners with robust and secure opportunities to transform corporate affairs and social responsibilities of organizations through accountability, integrity, and transparency; information governance; data and information security; as well as digital internet of things.
Hahn, J. (2020). Student Engagement and Smart Spaces: Library Browsing and Internet of Things Technology. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 52-70). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch003
The purpose of this chapter is to provide evidence-based findings on student engagement within smart library spaces. The focus of smart libraries includes spaces that are enhanced with the internet of things (IoT) infrastructure and library collection maps accessed through a library-designed mobile application. The analysis herein explored IoT-based browsing within an undergraduate library collection. The open stacks and mobile infrastructure provided several years (2016-2019) of user-generated smart building data on browsing and selecting items in open stacks. The methods of analysis used in this chapter include transactional analysis and data visualization of IoT infrastructure logs. By analyzing server logs from the computing infrastructure that powers the IoT services, it is possible to infer in greater detail than heretofore possible the specifics of the way library collections are a target of undergraduate student engagement.
Treskon, M. (2020). Providing an Environment for Authentic Learning Experiences. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 71-86). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch004
The Loyola Notre Dame Library provides authentic learning environments for undergraduate students by serving as “client” for senior capstone projects. Through the creative application of IoT technologies such as Arduinos and Raspberry Pis in a library setting, the students gain valuable experience working through software design methodology and create software in response to a real-world challenge. Although these proof-of-concept projects could be implemented, the library is primarily interested in furthering the research, teaching, and learning missions of the two universities it supports. Whether the library gets a product that is worth implementing is not a requirement; it is a “bonus.”
Rashid, M., Nazeer, I., Gupta, S. K., & Khanam, Z. (2020). Internet of Things: Architecture, Challenges, and Future Directions. In Holland, B. (Ed.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 87-104). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch005
The internet of things (IoT) is a computing paradigm that has changed our daily livelihood and functioning. IoT focuses on the interconnection of all the sensor-based devices like smart meters, coffee machines, cell phones, etc., enabling these devices to exchange data with each other during human interactions. With easy connectivity among humans and devices, speed of data generation is getting multi-fold, increasing exponentially in volume, and is getting more complex in nature. In this chapter, the authors will outline the architecture of IoT for handling various issues and challenges in real-world problems and will cover various areas where usage of IoT is done in real applications. The authors believe that this chapter will act as a guide for researchers in IoT to create a technical revolution for future generations.
Martin, L. (2020). Cloud Computing, Smart Technology, and Library Automation. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 105-123). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch006
As technology continues to change, the landscape of the work of librarians and libraries continue to adapt and adopt innovations that support their services. Technology also continues to be an essential tool for dissemination, retrieving, storing, and accessing the resources and information. Cloud computing is an essential component employed to carry out these tasks. The concept of cloud computing has long been a tool utilized in libraries. Many libraries use OCLC to catalog and manage resources and share resources, WorldCat, and other library applications that are cloud-based services. Cloud computing services are used in the library automation process. Using cloud-based services can streamline library services, minimize cost, and the need to have designated space for servers, software, or other hardware to perform library operations. Cloud computing systems with the library consolidate, unify, and optimize library operations such as acquisitions, cataloging, circulation, discovery, and retrieval of information.
Owusu-Ansah, S. (2020). Developing a Digital Engagement Strategy for Ghanaian University Libraries: An Exploratory Study. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 124-139). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch007
This study represents a framework that digital libraries can leverage to increase usage and visibility. The adopted qualitative research aims to examine a digital engagement strategy for the libraries in the University of Ghana (UG). Data is collected from participants (digital librarians) who are key stakeholders of digital library service provision in the University of Ghana Library System (UGLS). The chapter reveals that digital library services included rare collections, e-journal, e-databases, e-books, microfilms, e-theses, e-newspapers, and e-past questions. Additionally, the research revealed that the digital library service patronage could be enhanced through outreach programmes, open access, exhibitions, social media, and conferences. Digital librarians recommend that to optimize digital library services, literacy programmes/instructions, social media platforms, IT equipment, software, and website must be deployed. In conclusion, a DES helps UGLS foster new relationships, connect with new audiences, and establish new or improved brand identity.
Nambobi, M., Ssemwogerere, R., & Ramadhan, B. K. (2020). Implementation of Autonomous Library Assistants Using RFID Technology. In Holland, B. (Ed.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 140-150). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch008
This is an interesting time to innovate around disruptive technologies like the internet of things (IoT), machine learning, blockchain. Autonomous assistants (IoT) are the electro-mechanical system that performs any prescribed task automatically with no human intervention through self-learning and adaptation to changing environments. This means that by acknowledging autonomy, the system has to perceive environments, actuate a movement, and perform tasks with a high degree of autonomy. This means the ability to make their own decisions in a given set of the environment. It is important to note that autonomous IoT using radio frequency identification (RFID) technology is used in educational sectors to boost the research the arena, improve customer service, ease book identification and traceability of items in the library. This chapter discusses the role, importance, the critical tools, applicability, and challenges of autonomous IoT in the library using RFID technology.
Priya, A., & Sahana, S. K. (2020). Processor Scheduling in High-Performance Computing (HPC) Environment. In Holland, B. (Ed.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 151-179). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch009
Processor scheduling is one of the thrust areas in the field of computer science. The future technologies use a huge amount of processing for execution of their tasks like huge games, programming software, and in the field of quantum computing. In real-time, many complex problems are solved by GPU programming. The primary concern of scheduling is to reduce the time complexity and manpower. Several traditional techniques exit for processor scheduling. The performance of traditional techniques is reduced when it comes to the huge processing of tasks. Most scheduling problems are NP-hard in nature. Many of the complex problems are recently solved by GPU programming. GPU scheduling is another complex issue as it runs thousands of threads in parallel and needs to be scheduled efficiently. For such large-scale scheduling problems, the performance of state-of-the-art algorithms is very poor. It is observed that evolutionary and genetic-based algorithms exhibit better performance for large-scale combinatorial and internet of things (IoT) problems.
Kirsch, B. (2020). Virtual Reality in Libraries. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 180-193). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch010
Librarians are beginning to offer virtual reality (VR) services in libraries. This chapter reviews how libraries are currently using virtual reality for both consumption and creation purposes. Virtual reality tools will be compared and contrasted, and recommendations will be given for purchasing and circulating headsets and VR equipment. Google Tour Creator and a smartphone or 360-degree camera can be used to create a virtual tour of the library and other virtual reality content. These new library services will be discussed along with practical advice and best practices for incorporating virtual reality into the library for instructional and entertainment purposes.
Heffernan, K. L., & Chartier, S. (2020). Augmented Reality Gamifies the Library: A Ride Through the Technological Frontier. In Holland, B. (Ed.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 194-210). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch011
Two librarians at a University in New Hampshire attempted to integrate gamification and mobile technologies into the exploration of, and orientation to, the library’s services and resources. From augmented reality to virtual escape rooms and finally an in-house app created by undergraduate, campus-based, game design students, the library team learned much about the triumphs and challenges that come with attempting to utilize new technologies to reach users in the 21st century. This chapter is a narrative describing years of various attempts, innovation, and iteration, which have led to the library team being on the verge of introducing an app that could revolutionize campus discovery and engagement.
Miltenoff, P. (2020). Video 360 and Augmented Reality: Visualization to Help Educators Enter the Era of eXtended Reality. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 211-225). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch012
The advent of all types of eXtended Reality (XR)—VR, AR, MR—raises serious questions, both technological and pedagogical. The setup of campus services around XR is only the prelude to the more complex and expensive project of creating learning content using XR. In 2018, the authors started a limited proof-of-concept augmented reality (AR) project for a library tour. Building on their previous research and experience creating a virtual reality (VR) library tour, they sought a scalable introduction of XR services and content for the campus community. The AR library tour aimed to start us toward a matrix for similar services for the entire campus. They also explored the attitudes of students, faculty, and staff toward this new technology and its incorporation in education, as well as its potential and limitations toward the creation of a “smart” library.
Firstly, we need to resolve the so-called digital divide
Secondly, this will mean that teachers must reconsider all their methodologies and prepare them for this new, blended learning environment.
Thirdly, institutions, both educational and normative, must understand that, in this new context, some ways of teaching no longer make sense.
Online teaching will not consist of turning a handle while students learn on their own. On the contrary: it will require teachers to engage more than ever, who will spend many hours in forums moderating conversations and opening new threads.
