A virtual reality headset can take students on an immersive journey to another world. But no matter how cool it is, if that $3,000 piece of equipment enters a classroom and doesn’t provide any real instructional value, it can quickly become a very expensive paperweight.
Most schools don’t do edtech procurement really well yet. Sometimes we buy products that end up in closets because they don’t fit the instructional needs of students, and we end up not being good stewards of taxpayer dollars.
Located in the district’s central office, where hundreds of teachers and staff members stop by each week for professional development, the playground offers a creative space that encourages teachers to explore new tools that have been vetted and approved by the district’s tech department.
In the United States, K-12 schools spend more than $13 billion a year on edtech — often without any idea whether it will make a difference in learning outcomes.
Teachers can bring VR stories into the classroom in many different ways for meaningful learning experiences. Imagine a scavenger hunt where students narrate a story based on what they find. Or consider using objects they see to identify vocabulary words or recognize letters. Students should have purpose in their viewing and it should directly connect to standards.
Similar to the new movie, Ready Player One, they provide an intense experience where the viewer feels like they are in the center of the story.
Using a mobile device or tablet, the student can start the story and look around the scene based on their interest, rather than the cameras focus. New apps such as Baobab VR have continued to appear with more interactions and engagement.
A creative way to have your students create their own virtual stories is using the app Roundme. Upload your 360 image and add directional sound, links and content. Upload portals to walk the viewer into multiple scenes and then easily share the stories by link to the story.
Newer augmented reality apps that work with ARKit have taken another approach to storytelling. Augmented Stories and My Hungry Caterpillar.Qurious, a company that is working on a release blending gaming, making and storytelling in one app.
Storyfab, turns our students into the directors of the show
A new AR book, SpyQuest, has moved the immersive experience a big step forward as it helps define the story by bringing the images to life. Through the camera lens on a device, the stories make students the agents in an adventure into the world of espionage. The augmented reality experiences on the images use the accompanying app to scan the scene and provide further insight into the story.
Media literacy. Differentiated instruction. Media literacy guide.
Fake news as part of media literacy. Visual literacy as part of media literacy. Media literacy as part of digital citizenship.
Web design / web development
the roles of HTML5, CSS, Java Script, PHP, Bootstrap, JQuery, React and other scripting languages and libraries. Heat maps and other usability issues; website content strategy. THE MODEL-VIEW-CONTROLLER (MVC) design pattern
Social media for institutional use. Digital Curation. Social Media algorithms. Etiquette Ethics. Mastodon
I hosted a LITA webinar in the fall of 2016 (four weeks); I can accommodate any information from that webinar for the use of the IM students
OER and instructional designer’s assistance to book creators.
I can cover both the “library part” (“free” OER, copyright issues etc) and the support / creative part of an OER book / textbook
“Big Data.” Data visualization. Large scale visualization. Text encoding. Analytics, Data mining. Unizin. Python, R in academia.
I can introduce the students to the large idea of Big Data and its importance in lieu of the upcoming IoT, but also departmentalize its importance for academia, business, etc. From infographics to heavy duty visualization (Primo X-Services API. JSON, Flask).
NetNeutrality, Digital Darwinism, Internet economy and the role of your professional in such environment
I can introduce students to the issues, if not familiar and / or lead a discussion on a rather controversial topic
Digital assessment. Digital Assessment literacy.
I can introduce students to tools, how to evaluate and select tools and their pedagogical implications
Wikipedia
a hands-on exercise on working with Wikipedia. After the session, students will be able to create Wikipedia entries thus knowing intimately the process of Wikipedia and its information.
Effective presentations. Tools, methods, concepts and theories (cognitive load). Presentations in the era of VR, AR and mixed reality. Unity.
I can facilitate a discussion among experts (your students) on selection of tools and their didactically sound use to convey information. I can supplement the discussion with my own findings and conclusions.
eConferencing. Tools and methods
I can facilitate a discussion among your students on selection of tools and comparison. Discussion about the their future and their place in an increasing online learning environment
Digital Storytelling. Immersive Storytelling. The Moth. Twine. Transmedia Storytelling
I am teaching a LIB 490/590 Digital Storytelling class. I can adapt any information from that class to the use of IM students
VR, AR, Mixed Reality.
besides Mark Gill, I can facilitate a discussion, which goes beyond hardware and brands, but expand on the implications for academia and corporate education / world
Instructional design. ID2ID
I can facilitate a discussion based on the Educause suggestions about the profession’s development
Microcredentialing in academia and corporate world. Blockchain
IT in K12. How to evaluate; prioritize; select. obsolete trends in 21 century schools. K12 mobile learning
Podcasting: past, present, future. Beautiful Audio Editor.
a definition of podcasting and delineation of similar activities; advantages and disadvantages.
Gender, race and age in education. Digital divide. Xennials, Millennials and Gen Z. generational approach to teaching and learning. Young vs old Millennials. Millennial employees.
Minecraft for Higher Ed? Try it. Pros, Cons, Recommendations?
Description: Why Minecraft, the online video game? How can Minecraft improve learning for higher education? We’ll begin with a live demo in which all can participate (see “Minecraft for Free”). We’ll review “Examples, Not Rumors” of successful adaptations and USES of Minecraft for teaching/learning in higher education. Especially those submitted in advance And we’ll try to extract from these activities a few recommendations/questions/requests re Minecraft in higher education.
Callaghan, N. (2016). Investigating the role of Minecraft in educational learning environments. Educational Media International, 53(4), 244-260. doi:10.1080/09523987.2016.1254877
Noelene Callaghan dissects the evolution in Australian education from a global perspective. She rightfully draws attention (p. 245) to inevitable changes in the educational world, which still remain ignored: e.g., the demise of “traditional” LMS (Educase is calling for their replacement with digital learning environments https://blog.stcloudstate.edu/ims/2017/07/06/next-gen-digital-learning-environment/ and so does the corporate world of learning: https://blog.stcloudstate.edu/ims/2017/03/28/digital-learning/ ), the inevitability of BYOD (mainly by the “budget restrictions and sustainability challenges” (p. 245); by the assertion of cloud computing, and, last but not least, by the gamification of education.
p. 245 literature review. In my paper, I am offering more comprehensive literature review. While Callaghan focuses on the positive, my attempt is to list both pros and cons: http://scsu.mn/1F008Re
246 General use of massive multiplayer online role playing games (MMORPGs)
levels of interaction have grown dramatically and have led to the creation of general use of massive multiplayer online role playing games (MMORPGs)
247 In teaching and learning environments, affordances associated with edugames within a project-based learning (PBL) environment permit:
These affordances develop both social and cognitive abilities of students
Nebel, S., Schneider, S., Beege, M., Kolda, F., Mackiewicz, V., & Rey, G. (2017). You cannot do this alone! Increasing task interdependence in cooperative educational videogames to encourage collaboration. Educational Technology Research & Development, 65(4), 993-1014. doi:10.1007/s11423-017-9511-8
Abrams, S. S., & Rowsell, J. (2017). Emotionally Crafted Experiences: Layering Literacies in Minecraft. Reading Teacher, 70(4), 501-506.
Nebel, S., Schneider, S., & Daniel Rey, G. (2016). Mining Learning and Crafting Scientific Experiments: A Literature Review on the Use of Minecraft in Education and Research. Source: Journal of Educational Technology & Society, 19(192), 355–366. Retrieved from http://www.jstor.org/stable/jeductechsoci.19.2.355
Cipollone, M., Schifter, C. C., & Moffat, R. A. (2014). Minecraft as a Creative Tool: A Case Study. International Journal Of Game-Based Learning, 4(2), 1-14.
Niemeyer, D. J., & Gerber, H. R. (2015). Maker culture and Minecraft : implications for the future of learning. Educational Media International, 52(3), 216-226. doi:10.1080/09523987.2015.1075103
Nebel, S., Schneider, S., & Daniel Rey, G. (2016). Mining Learning and Crafting Scientific Experiments: A Literature Review on the Use of Minecraft in Education and Research. Journal of Educational Technology & Society, 19(192), 355–366. Retrieved from http://www.jstor.org/stable/jeductechsoci.19.2.355
Wilkinson, B., Williams, N., & Armstrong, P. (2013). Improving Student Understanding, Application and Synthesis of Computer Programming Concepts with Minecraft. In The European Conference on Technology in the Classroom 2013. Retrieved from http://iafor.info/archives/offprints/ectc2013-offprints/ECTC2013_0477.pdf
Uusi-Mäkelä, M., & Uusi-Mäkelä, M. (2014). Immersive Language Learning with Games: Finding Flow in MinecraftEdu. EdMedia: World Conference on Educational Media and Technology (Vol. 2014). Association for the Advancement of Computing in Education (AACE). Retrieved from https://www.learntechlib.org/noaccess/148409/
Birt, J., & Hovorka, D. (2014). Effect of mixed media visualization on learner perceptions and outcomes. In 25th Australasian Conference on Information Systems (pp. 1–10). Retrieved from http://epublications.bond.edu.au/fsd_papers/74
Al Washmi, R., Bana, J., Knight, I., Benson, E., Afolabi, O., Kerr, A., Hopkins, G. (2014). Design of a Math Learning Game Using a Minecraft Mod. https://doi.org/10.13140/2.1.4660.4809
Augmented reality can be described as experiencing the real world with an overlay of additional computer generated content. In contrast, virtual reality immerses a user in an entirely simulated environment, while mixed or merged reality blends real and virtual worlds in ways through which the physical and the digital can interact. AR, VR, and MR offer new opportunities to create a psychological sense of immersive presence in an environment that feels real enough to be viewed, experienced, explored, and manipulated. These technologies have the potential to democratize learning by giving everyone access to immersive experiences that were once restricted to relatively few learners.
In Grinnell College’s Immersive Experiences Lab http://gciel.sites.grinnell.edu/, teams of faculty, staff, and students collaborate on research projects, then use 3D, VR, and MR technologies as a platform to synthesize and present their findings.
In terms of equity, AR, VR, and MR have the potential to democratize learning by giving all learners access to immersive experiences
downsides :
relatively little research about the most effective ways to use these technologies as instructional tools. Combined, these factors can be disincentives for institutions to invest in the equipment, facilities, and staffing that can be required to support these systems. AR, VR, and MR technologies raise concerns about personal privacy and data security. Further, at least some of these tools and applications currently fail to meet accessibility standards. The user experience in some AR, VR, and MR applications can be intensely emotional and even disturbing (my note: but can be also used for empathy literacy),
immersing users in recreated, remote, or even hypothetical environments as small as a molecule or as large as a universe, allowing learners to experience “reality” from multiple perspectives.
More data doesn’t automatically lead to better decisions. A shortage of skilled data scientists has hindered progress towards translation of information into actionable business insights. In addition, traditionally dense spreadsheets and linear slideshows are ineffective to present discoveries when dealing with Big Data’s dynamic nature. We need to evolve how we capture, analyze and communicate data.
Large-scale visualization platforms have several advantages over traditional presentation methods. They blur the line between the presenter and audience to increase the level of interactivity and collaboration. They also offer simultaneous views of both macro and micro perspectives, multi-user collaboration and real-time data interaction, and a limitless number of visualization possibilities – critical capabilities for rapidly understanding today’s large data sets.
Visualization walls enable presenters to target people’s preferred learning methods, thus creating a more effective communication tool. The human brain has an amazing ability to quickly glean insights from patterns – and great visualizations make for more efficient storytellers.
Grant: Visualizing Digital Scholarship in Libraries and Learning Spaces
Award amount: $40,000
Funder: Andrew W. Mellon Foundation
Lead institution: North Carolina State University Libraries
Due date: 13 August 2017
Notification date: 15 September 2017
Website: https://immersivescholar.org
Contact: immersivescholar@ncsu.edu
Project Description
NC State University, funded by the Andrew W. Mellon Foundation, invites proposals from institutions interested in participating in a new project for Visualizing Digital Scholarship in Libraries and Learning Spaces. The grant aims to 1) build a community of practice of scholars and librarians who work in large-scale multimedia to help visually immersive scholarly work enter the research lifecycle; and 2) overcome technical and resource barriers that limit the number of scholars and libraries who may produce digital scholarship for visualization environments and the impact of generated knowledge. Libraries and museums have made significant strides in pioneering the use of large-scale visualization technologies for research and learning. However, the utilization, scale, and impact of visualization environments and the scholarship created within them have not reached their fullest potential. A logical next step in the provision of technology-rich, visual academic spaces is to develop best practices and collaborative frameworks that can benefit individual institutions by building economies of scale among collaborators.
The project contains four major elements:
An initial meeting and priority setting workshop that brings together librarians, scholars, and technologists working in large-scale, library and museum-based visualization environments.
Scholars-in-residence at NC State over a multi-year period who pursue open source creative projects, working in collaboration with our librarians and faculty, with the potential to address the articulated limitations.
Funding for modest, competitive block grants to other institutions working on similar challenges for creating, disseminating, validating, and preserving digital scholarship created in and for large-scale visual environments.
A culminating symposium that brings together representatives from the scholars-in-residence and block grant recipient institutions to share and assess results, organize ways of preserving and disseminating digital products produced, and build on the methods, templates, and tools developed for future projects.
Work Summary
This call solicits proposals for block grants from library or museum systems that have visualization installations. Block grant recipients can utilize funds for ideas ranging from creating open source scholarly content for visualization environments to developing tools and templates to enhance sharing of visualization work. An advisory panel will select four institutions to receive awards of up to $40,000. Block grant recipients will also participate in the initial priority setting workshop and the culminating symposium. Participating in a block grant proposal does not disqualify an individual from later applying for one of the grant-supported scholar-in-residence appointments.
Applicants will provide a statement of work that describes the contributions that their organization will make toward the goals of the grant. Applicants will also provide a budget and budget justification.
Activities that can be funded through block grants include, but are not limited to:
Commissioning work by a visualization expert
Hosting a visiting scholar, artist, or technologist residency
Software development or adaptation
Development of templates and methodologies for sharing and scaling content utilizing open source software
Student or staff labor for content or software development or adaptation
Curricula and reusable learning objects for digital scholarship and visualization courses
Travel (if necessary) to the initial project meeting and culminating workshop
User research on universal design for visualization spaces
Funding for operational expenditures, such as equipment, is not allowed for any grant participant.
Application
Send an application to immersivescholar@ncsu.edu by the end of the day on 13 August 2017 that includes the following:
Statement of work (no more than 1000 words) of the project idea your organization plans to develop, its relationship to the overall goals of the grant, and the challenges to be addressed.
List the names and contact information for each of the participants in the funded project, including a brief description of their current role, background, expertise, interests, and what they can contribute.
Project timeline.
Budget table with projected expenditures.
Budget narrative detailing the proposed expenditures
Selection and Notification Process
An advisory panel made up of scholars, librarians, and technologists with experience and expertise in large-scale visualization and/or visual scholarship will review and rank proposals. The project leaders are especially keen to receive proposals that develop best practices and collaborative frameworks that can benefit individual institutions by building a community of practice and economies of scale among collaborators.
Awardees will be selected based on:
the ability of their proposal to successfully address one or both of the identified problems;
the creativity of the proposed activities;
relevant demonstrated experience partnering with scholars or students on visualization projects;
whether the proposal is extensible;
feasibility of the work within the proposed time-frame and budget;
whether the project work improves or expands access to large-scale visual environments for users; and
the participant’s ability to expand content development and sharing among the network of institutions with large-scale visual environments.
Awardees will be required to send a representative to an initial meeting of the project cohort in Fall 2017.
Maya Georgieva, an ed tech strategist, author and speaker with more than 15 years of experience in higher education and global education. Georgieva is co-founder of Digital Bodies, a consulting group that provides news and analysis of VR, AR and wearables in education
Microsoft has been collaborating with its partners, such as HP, Acer, Dell and Lenovo, to develop VR headsets that will work with lower-end desktops. Later this year, the companies will debut headsets for $299, “which is much more affordable compared to HoloLens
many Kickstarter crowdfunding efforts are bound to make high-end headsets more accessible for teaching.
the NOLO project. The NOLO system is meant for mobile VR headsets and gives users that “6 degrees of freedom” (or 6 DoF) motion tracking that is currently only found in high-end headsets.
2) Hand Controllers That Will Bring Increased Interactivity
AltspaceVR h uses avatars and supports multiplayer sessions that allow for socialization and user interaction.
Facebook has been continuing to develop its own VR platform, Facebook Spaces, which is in beta and will be out later this year. LectureVR is a similar platform on the horizon.
new forms of human-computer interaction (HCI) such as augmented reality (AR),virtual reality (VR) and mixed reality (MR).
p. 21
combining AR/VR/MR with cognitive computing and artificial intelligence (AI) technologies (such as machine learning, deep learning, natural language processing and chatbots).
Some thought-provoking questions include:
Will remote workers be able to be seen and interacted with via their holograms (i.e., attending their meetings virtually)? What would this mean for remote learners?
Will our smartphones increasingly allow us to see information overlaid on the real world? (Think Pokémon Go, but putting that sort of technology into a vast array of different applications, many of which could be educational in nature)
How do/will these new forms of HCI impact how we design our learning spaces?
Will students be able to pick their preferred learning setting (i.e., studying by a brook or stream or in a virtual Starbucks-like atmosphere)?
Will more devices/platforms be developed that combine the power of AI with VR/AR/MR-related experiences? For example, will students be able to issue a verbal question or command to be able to see and experience walking around ancient Rome?
Will there be many new types of learning experiences,like what Microsoft was able to achieve in its collaboration with Case Western Reserve University [OH]? Its HoloLens product transforms the way human anatomy can be taught.
p. 22 Extensive costs for VR design and development drive the need for collaborative efforts.
Case Western Reserve University, demonstrates a collaboration with the Cleveland Clinic and Microsoft to create active multi-dimensional learning using holography.
the development of more affordable high-quality virtual reality solutions.
AR game developed by the Salzburg University of Applied Sciences [Austria] (http://www.fh-salzburg.ac.at/en/) that teaches about sustainability, the environment and living green.
Whether using AR for a gamified course or to acclimate new students to campus, the trend will continue into 2017.
Google Expeditions This virtual reality field trip tool works in conjunction with Google Cardboard and has just been officially released. The app allows teachers to guide students through an exploration of 200 (and growing) historical sites and natural resources in an immersive, three-dimensional experience. The app only works on Android devices and is free.
Flippity This app works in conjunction with Google Sheets and allows teachers to easily make a Jeopardy-style game.
Google Science Journal This Android app allows users to do science experiments with mobile phones. Students can use sensors in the phone or connect external sensors to collect data, but can also take notes on observations, analyze and annotate within the app.
Google Cast This simple app solves issues of disparate devices in the classroom. When students download the app, they can project from their devices onto the screen at the front of the room easily. “You don’t have to have specific hardware, you just have to have Wi-Fi,”
Constitute This site hosts a database of constitutions from around the world. Anything digitally available has been aggregated here. It is searchable by topic and will pull out specific excerpts related to search terms like “freedom of speech.”
YouTube a database of YouTube Channels by subject to help educators with discoverability (hint subjects are by tab along the bottom of the document).
Zygote Body This freemium tool has a lot of functionality in the free version, allowing students to view different parts of human anatomy and dig into how various body systems work.
Pixlr This app has less power than Photoshop, but is free and fairly sophisticated. It works directly with Google accounts, so students can store files there.
uild With Chrome This extension to the Chrome browser lets kids play with digital blocks like Legos. Based on the computer’s IP address, the software assigns users a plot of land on which to build nearby. There’s a Build Academy to learn how to use the various tools within the program, but then students can make whatever they want.
Google CS First Built on Scratch’s programming language, this easy tool gives step-by-step instructions to get started and is great for the hesitant teacher who is just beginning to dip a toe into coding.
A new survey from Extreme Networks aimed to answer this question by polling nearly 350 schools within higher ed and K-12. According to the results, 23 percent of respondents have tested VR, while 77 percent have not (40 percent of schools polled still aren’t sure if they’ll use the technology in the future). Meaning that although virtual reality has an important and growing role in education, it may take several years to get all institutions on board.
The survey notes that one challenge to implementation is that nearly two-thirds of schools are “somewhat or not sure” their IT infrastructure can currently support VR technology.
Respondents also had concerns about the lack of VR content available, as well as a lack of student resources, with 43 percent of respondents saying that VR is too expensive or difficult to implement. However, one respondent is taking this approach to providing VR to students at low or no cost: “We are putting out a call for old smartphone donations in our [community for those] who no longer need them. With the donations, we’re making sets of Google Cardboard and phones to create traveling VR stations for classes in all of our buildings.”
1. For new research: According to the Wall Street Journal, Professor Jeremy Bailenson, founding director of the Virtual Reality Human Interaction Lab at Stanford University, is using a state-of-the-art “haptic” floor of aeronautic metal that vibrates and moves to stimulate the physical world for research on how VR has the potential to change the way users feel and behave. For example, spending time flying around the world like Superman in virtual reality has been shown to increase participants’ altruistic actions outside of the lab. There may also be implications for confronting racism, sexism, and aiding in empathy and humanitarian efforts, says Bailenson. (see more in about empathy and VR in this IMS blog: https://blog.stcloudstate.edu/ims/2015/11/18/immersive-journalism/)
2. For coding and 3D design:
a class on virtual reality that gives students the opportunity to design their own interactive world, work with 3D audio and experiment with immersive technology through a combination of hands-on learning and case studies. Also, the University of Georgia is offering similar classes where students design and explore applications for VR.
3. For anatomy and dissection:
4. For engagement: A whopping 68 percent of survey respondents said the major benefit of using VR in education is to excite students about the subject matter. 39 percent said it’s great for encouraging creativity.
1. For new research: using a state-of-the-art “haptic” floor of aeronautic metal that vibrates and moves to stimulate the physical world for research on how VR has the potential to change the way users feel and behave. There may also be implications for confronting racism, sexism, and aiding in empathy and humanitarian efforts, says Bailenson.
2. For coding and 3D design: According to Bob Nilsson, director of Vertical Solutions Marketing for Extreme Networking, the University of Maryland, College Park, now offers a class on virtual reality that gives students the opportunity to design their own interactive world, work with 3D audio and experiment with immersive technology through a combination of hands-on learning and case studies. Also, the University of Georgia is offering similar classes where students design and explore applications for VR. Conrad Tucker, an assistant professor of engineering at Pennsylvania State University, has received funding to build a virtual engineering lab where students hold, rotate, and fit together virtual parts as they would with their real hands.
3. For anatomy and dissection: Said one Extreme Networks survey respondent, “Our students have been developing a VR model of a cow’s anatomy for dissection and study. You have the ability to drill down to the circulatory system, brain, muscle, skeleton, etc. Our applied tech program is using VR in conjunction with Autocad for models of projects they design.”
4. For engagement: A whopping 68 percent of survey respondents said the major benefit of using VR in education is to excite students about the subject matter. 39 percent said it’s great for encouraging creativity.
5. For field trips: Google has eliminated restrictions on Expeditions, their VR field trips program. Google Expeditions was cited in the survey as one of the most popular sources of VR content, but with the complaint that it was a restricted program.
Virtual reality may have its place, but until traditional education moves away from their 20th century teaching methodology and replaces it with educationally innovative, 21st century learning methodology, within a blended and flipped learning environment, virtual reality is currently, much ado about nothing.
Unless any new application is educationally innovative and directly and measurably contributes to effective, efficient, consistent, affordable, relevant advanced student success outcomes for ALL students, future innovations must wait for current innovations to be implemented.
This process of appriate choice and appropriate implemention must start at the top and be beta tested for measured student success before its rolled out system wide.
