Like all of 8th Wall’s WebAR capabilities, projects created using Curved Image Targets work across iOS and Android devices with an estimated reach of nearly 3 billion smartphones, and can be immediately experienced with the tap of a link or by scanning a QR code.
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.
Back in the 1960s, an experimental form of teaching made a big splash at colleges. It was called PSI, or the Personalized System of Instruction. https://en.wikipedia.org/wiki/Keller_Plan
the case that colleges should do more to professionalize teaching, which might help reduce the number of fads that emerge. But he also acknowledges that there are risks. “If you start creating elaborate bureaucracies to measure and judge [teaching], might you actually depersonalize it? Might you take some of the charisma, idiosyncrasy and serendipity out of it?”
my note: the LITA publication about the Emporia State University (see below) pursues the same goals of the project two SCSU librarians, Susan Hubbs, MLIS, and Plamen Miltenoff, Ph.D. MLIS, have developed:
Virtual reality (VR) has emerged as a popular technology for gaming and learning, with its uses for teaching presently being investigated in a variety of educational settings. However, one area where the effect of this technology on students has not been examined in detail is as tool for new student orientation in colleges and universities. This study investigates this effect using an experimental methodology and the population of new master of library science (MLS) students entering a library and information science (LIS) program. The results indicate that students who received a VR orientation expressed more optimistic views about the technology, saw greater improvement in scores on an assessment of knowledge about their program and chosen profession, and saw a small decrease in program anxiety compared to those who received the same information as standard text-and-links. The majority of students also indicated a willingness to use VR technology for learning for long periods of time (25 minutes or more). The researchers concluded that VR may be a useful tool for increasing student engagement, as described by Game Engagement Theory.
AUTHOR BIOGRAPHY
Brady Lund, Emporia State University
Brady Lund is a doctoral student at Emporia State University’s School of Library and Information Management, where he studies the intersection of information technology and information science, among other topics.
GIGXR, Inc., a provider of extended reality (XR) learning systems for instructor-led teaching and training, announced today the availability of its GIG Immersive Learning System for the Fall 2020 Northern Hemisphere academic year. The cloud-based System was created to dramatically enhance learning outcomes while simplifying complex, real-life teaching and training scenarios in medical and nursing schools, higher education, healthcare and hospitals.
The EDUCAUSE XR (Extended Reality) Community Group Listserv <XR@LISTSERV.EDUCAUSE.EDU>
Greetings to you all! Presently, I am undertaking a masters course in “Instruction Design and Technology” which has two components: Coursework and Research. For my research, I would like to pursue it in the field of Augmented Reality (AR) and Mobile Learning. I am thinking of an idea that could lead to collaboration among students and directly translate into enhanced learning for students while using an AR application. However, I am having a problem with coming up with an application because I don’t have any computing background. This, in turn, is affecting my ability to come up with a good research topic.
I teach gross anatomy and histology to many students of health sciences at Mbarara University, and this is where I feel I could make a contribution to learning anatomy using AR since almost all students own smartphones. I, therefore, kindly request you to let me know which of the freely-available AR app authoring tools could help me in this regard. In addition, I request for your suggestions regarding which research area(s) I should pursue in order to come up with a good research topic.
Hoping to hear from you soon.
Grace Muwanga Department of Anatomy Mbarara University Uganda (East Africa)
One limitation with Spark and Snap is that file sizes need to be small.
If you’re interested in creating AR experiences that work directly in a web browser and are up for writing some markup code, look at A-Frame AR https://aframe.io/blog/webxr-ar-module/.
For finding and hosting 3D models you can look at Sketchfab and Google Poly. I think both have many examples of anatomy.
I’ve been using Roar. They have a 99$ a year license.
++++++++++++
I have recently been experimenting with an AR development tool called Zappar, which I like because the end users do not have to download an app to view the AR content. Codes can be scanned either with the Zappar app or at web.zappar.com.
From a development standpoint, Zappar has an easy to use drag-and-drop interface called ZapWorks Designer that will help you build basic AR experiences quickly, but for a more complicated, more interactive use case such as learning anatomy, you will probably need ZapWorks Studio, which will have much more of a learning curve. The Hobby (non-commercial) license is free if you are interested in trying it out.
You can check out an AR anatomy mini-lesson with models of the human brain, liver, and heart using ZapWorks here: https://www.zappar.com/campaigns/secrets-human-body/. Even if you choose to go with a different development tool, this example might help nail down ideas for your own project.
Hope this helps,
Brighten
Brighten Jelke Academic Assistant for Virtual Technology Lake Forest College bjelke@lakeforest.edu Office: DO 233 | Phone: 847-735-5168
Presentation 1: Inspiring Faculty (+ Students) with Tales of Immersive Tech (Practitioner Presentation #106)
Authors: Nicholas Smerker
Immersive technologies – 360º video, virtual and augmented realities – are being discussed in many corners of higher education. For an instructor who is familiar with the terms, at least in passing, learning more about why they and their students should care can be challenging, at best. In order to create a font of inspiration, the IMEX Lab team within Teaching and Learning with Technology at Penn State devised its Get Inspired web resource. Building on a similar repository for making technology stories at the sister Maker Commons website, the IMEX Lab Get Inspired landing page invites faculty to discover real world examples of how cutting edge XR tools are being used every day. In addition to very approachable video content and a short summary calling out why our team chose the story, there are also instructional designer-developed Assignment Ideas that allow for quick deployment of exercises related to – though not always relying upon – the technologies highlighted in a given Get Inspired story.
Presentation 2: Lessons Learned from Over A Decade of Designing and Teaching Immersive VR in Higher Education Online Courses (Practitioner Presentation #101)
Authors: Eileen Oconnor
This presentation overviews the design and instruction in immersive virtual reality environments created by the author beginning with Second Life and progressing to open source venues. It will highlight the diversity of VR environment developed, the challenges that were overcome, and the accomplishment of students who created their own VR environments for K12, college and corporate settings. The instruction and design materials created to enable this 100% online master’s program accomplishment will be shared; an institute launched in 2018 for emerging technology study will be noted.
Presentation 3: Virtual Reality Student Teaching Experience: A Live, Remote Option for Learning Teaching Skills During Campus Closure and Social Distancing (Practitioner Presentation #110)
Summary: During the Coronavirus pandemic, Ithaca College teacher education majors needed a classroom of students in order to practice teaching and receive feedback, but the campus was closed, and gatherings forbidden. Students were unable to participate in live practice teaching required for their program. We developed a virtual reality pilot project to allow students to experiment in two third-party social VR programs, AltSpaceVR and Rumii. Social VR platforms allow a live, embodied experience that mimics in-person events to give students a more realistic, robust and synchronous teaching practice opportunity. We documented the process and lessons learned to inform, develop and scale next generation efforts.
Sunday, June 21 • 8:00am – 9:00am Escape the (Class)room games in OpenSim or Second Life FULLhttps://ilrn2020.sched.com/event/ceKP/escape-the-classroom-games-in-opensim-or-second-lifePre-registration for this tour is required as places are limited. Joining instructions will be emailed to registrants ahead of the scheduled tour time.The Guided Virtual Adventure tour will take you to EduNation in Second Life to experience an Escape room game. For one hour, a group of participants engage in voice communication and try to solve puzzles, riddles or conundrums and follow clues to eventually escape the space. These scenarios are designed for problem solving and negotiating language and are ideal for language education. They are fun and exciting and the clock ticking adds to game play.Tour guide(s)/leader(s): Philp Heike, let’s talk online sprl, Belgium
Presentation 1: Evaluating the impact of multimodal Collaborative Virtual Environments on user’s spatial knowledge and experience of gamified educational tasks (Full Paper #91)
Authors: Ioannis Doumanis and Daphne Economou
>>Access Video Presentation<<
Several research projects in spatial cognition have suggested Virtual Environments (VEs) as an effective way of facilitating mental map development of a physical space. In the study reported in this paper, we evaluated the effectiveness of multimodal real-time interaction in distilling understanding of the VE after completing gamified educational tasks. We also measure the impact of these design elements on the user’s experience of educational tasks. The VE used reassembles an art gallery and it was built using REVERIE (Real and Virtual Engagement In Realistic Immersive Environment) a framework designed to enable multimodal communication on the Web. We compared the impact of REVERIE VG with an educational platform called Edu-Simulation for the same gamified educational tasks. We found that the multimodal VE had no impact on the ability of students to retain a mental model of the virtual space. However, we also found that students thought that it was easier to build a mental map of the virtual space in REVERIE VG. This means that using a multimodal CVE in a gamified educational experience does not benefit spatial performance, but also it does not cause distraction. The paper ends with future work and conclusions and suggestions for improving mental map construction and user experience in multimodal CVEs.
Presentation 2: A case study on student’s perception of the virtual game supported collaborative learning (Full Paper #42)
Authors: Xiuli Huang, Juhou He and Hongyan Wang
>>Access Video Presentation<<
The English education course in China aims to help students establish the English skills to enhance their international competitiveness. However, in traditional English classes, students often lack the linguistic environment to apply the English skills they learned in their textbook. Virtual reality (VR) technology can set up an immersive English language environment and then promote the learners to use English by presenting different collaborative communication tasks. In this paper, spherical video-based virtual reality technology was applied to build a linguistic environment and a collaborative learning strategy was adopted to promote their communication. Additionally, a mixed-methods research approach was used to analyze students’ achievement between a traditional classroom and a virtual reality supported collaborative classroom and their perception towards the two approaches. The experimental results revealed that the virtual reality supported collaborative classroom was able to enhance the students’ achievement. Moreover, by analyzing the interview, students’ attitudes towards the virtual reality supported collaborative class were reported and the use of language learning strategies in virtual reality supported collaborative class was represented. These findings could be valuable references for those who intend to create opportunities for students to collaborate and communicate in the target language in their classroom and then improve their language skills
Presentation 1: Reducing Cognitive Load through the Worked Example Effect within a Serious Game Environment (Full Paper #19)
Authors: Bernadette Spieler, Naomi Pfaff and Wolfgang Slany
>>Access Video Presentation<<
Novices often struggle to represent problems mentally; the unfamiliar process can exhaust their cognitive resources, creating frustration that deters them from learning. By improving novices’ mental representation of problems, worked examples improve both problem-solving skills and transfer performance. Programming requires both skills. In programming, it is not sufficient to simply understand how Stackoverflow examples work; programmers have to be able to adapt the principles and apply them to their own programs. This paper shows evidence in support of the theory that worked examples are the most efficient mode of instruction for novices. In the present study, 42 students were asked to solve the tutorial The Magic Word, a game especially for girls created with the Catrobat programming environment. While the experimental group was presented with a series of worked examples of code, the control groups were instructed through theoretical text examples. The final task was a transfer question. While the average score was not significantly better in the worked example condition, the fact that participants in this experimental group finished significantly faster than the control group suggests that their overall performance was better than that of their counterparts.
Presentation 2: A literature review of e-government services with gamification elements (Full Paper #56)
Authors: Ruth S. Contreras-Espinosa and Alejandro Blanco-M
>>Access Video Presentation<<
Nowadays several democracies are facing the growing problem of a breach in communication between its citizens and their political representatives, resulting in low citizen’s engagement in the participation of political decision making and on public consultations. Therefore, it is fundamental to generate a constructive relationship between both public administration and the citizens by solving its needs. This document contains a useful literature review of the gamification topic and e-government services. The documents contain a background of those concepts and conduct a selection and analysis of the different applications found. A set of three lines of research gaps are found with a potential impact on future studies.
Presentation 1: Connecting User Experience to Learning in an Evaluation of an Immersive, Interactive, Multimodal Augmented Reality Virtual Diorama in a Natural History Museum & the Importance of Story (Full Paper #51)
Authors: Maria Harrington
>>Access Video Presentation<<
Reported are the findings of user experience and learning outcomes from a July 2019 study of an immersive, interactive, multimodal augmented reality (AR) application, used in the context of a museum. The AR Perpetual Garden App is unique in creating an immersive multisensory experience of data. It allowed scientifically naïve visitors to walk into a virtual diorama constructed as a data visualization of a springtime woodland understory, and interact with multimodal information directly through their senses. The user interface comprised of two different AR data visualization scenarios reinforced with data based ambient bioacoustics, an audio story of the curator’s narrative, and interactive access to plant facts. While actual learning and dwell times were the same between the AR app and the control condition, the AR experience received higher ratings on perceived learning. The AR interface design features of “Story” and “Plant Info” showed significant correlations with actual learning outcomes, while “Ease of Use” and “3D Plants” showed significant correlations with perceived learning. As such, designers and developers of AR apps can generalize these findings to inform future designs.
Presentation 2: The Naturalist’s Workshop: Virtual Reality Interaction with a Natural Science Educational Collection (Short Paper #11)
Authors: Colin Patrick Keenan, Cynthia Lincoln, Adam Rogers, Victoria Gerson, Jack Wingo, Mikhael Vasquez-Kool and Richard L. Blanton
>>Access Video Presentation<<
For experiential educators who utilize or maintain physical collections, The Naturalist’s Workshop is an exemplar virtual reality platform to interact with digitized collections in an intuitive and playful way. The Naturalist’s Workshop is a purpose-developed application for the Oculus Quest standalone virtual reality headset for use by museum visitors on the floor of the North Carolina Museum of Natural Sciences under the supervision of a volunteer attendant. Within the application, museum visitors are seated at a virtual desk. Using their hand controllers and head-mounted display, they explore drawers containing botanical specimens and tools-of-the-trade of a naturalist. While exploring, the participant can receive new information about any specimen by dropping it into a virtual examination tray. 360-degree photography and three-dimensionally scanned specimens are used to allow user-motivated, immersive experience of botanical meta-data such as specimen collection coordinates.
Presentation 3: 360˚ Videos: Entry level Immersive Media for Libraries and Education (Practitioner Presentation #132)
Authors: Diane Michaud
>>Access Video Presentation<<
Within the continuum of XR Technologies, 360˚ videos are relatively easy to produce and need only an inexpensive mobile VR viewer to provide a sense of immersion. 360˚ videos present an opportunity to reveal “behind the scenes” spaces that are normally inaccessible to users of academic libraries. This can promote engagement with unique special collections and specific library services. In December 2019, with little previous experience, I led the production of a short 360˚video tour, a walk-through of our institution’s archives. This was a first attempt; there are plans to transform it into a more interactive, user-driven exploration. The beta version successfully generated interest, but the enhanced version will also help prepare uninitiated users for the process of examining unique archival documents and artefacts. This presentation will cover the lessons learned, and what we would do differently for our next immersive video production. Additionally, I will propose that the medium of 360˚ video is ideal for many institutions’ current or recent predicament with campuses shutdown due to the COVID-19 pandemic. Online or immersive 360˚ video can be used for virtual tours of libraries and/or other campus spaces. Virtual tours would retain their value beyond current campus shutdowns as there will always be prospective students and families who cannot easily make a trip to campus. These virtual tours would provide a welcome alternative as they eliminate the financial burden of travel and can be taken at any time.
These scenarios omit two critical components of the campus: the many men and women who can’t work from home and extracurricular activities.
Layoffs and furloughs must be the last option; pay cuts/freezes and other cost-saving opportunities must be exhausted before even one person is laid off this fall.
Extracurricular activities must be undertaken with an abundance of caution. Only those activities that are essential and can’t take place virtually must be held. Social distancing must be practiced, no matter the health conditions that exist at the particular time.
++++++++++++++++
How the Coronavirus Will Change Faculty Life Forever
As the pandemic wears on, expect heavier teaching loads, more service requirements, and more time online
Spatial is a startup that enables people to meet through augmented or virtual reality. It’s a little similar to the now defunct Facebook Spaces, except it has much broader support. You can use VR or mixed-reality headsets from a myriad of brands—from Microsoft’s HoloLens and Nreal’s Light to the Oculus Quest—as vehicles to meet in virtual spaces.
Spatial is announcing that it’s launching support for web browsers on desktops, Android, and iOS. Oh, and the platform is now completely free and open to everyone.
Click here to 