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augmented reality takeover. It’s played out at Snapchat and Facebook, at Google and Apple. Companies are using AR to design cars, sell furniture, make little digital sharks swim around your breakfast table. What if Prezi could apply that same technology to make better presentations?
the product isn’t ready for a public launch yet. Prezi has enlisted a select group of influencers to try out the AR tools and offer feedback before the company releases a beta version.
Oculus Connect, starting Wednesday in San Jose, California. Facebook’s Oculus VR division promises discussions on how health care, movies and video games are adapting to this still nascent technology. One panel will explore how the disability community can benefit from VR gear and presentations.
Over the summer, Apple and Google announced new technologies called ARKit and ARCore, respectively, that are designed to help iPhones and iPads or any device powered by Google’s Android software marry computer-generated images with the real world.
A $2.99 app, Star Guide AR, highlights stars and constellations in the sky once you point your phone at them. Another, Ikea Place, previews furniture in your home with a tap. Walk around your living room and you can see the furniture you placed while looking through the screen on your phone. So far, both are available only for the iPhone.
App developers I spoke with say they’re excited by augmented reality and believe it may help spur people to buy VR systems as well.
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.
Canada will see the fastest growth, with a CAGR of 145.2 percent over the forecast period. Other leaders in terms of growth include Central and Eastern Europe at 133.5 percent, Western Europe at 121.2 percent and the U.S. at 120.5 percent.
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Leslie Fisher Thinks Augmented Reality First, Then VR in the Classroom
An interview with the former Apple K–12 systems engineer, who will participate in multiple sessions during ISTE.
THE Journal: What do you think about virtual reality (VR) and augmented reality (AR) in the classroom? Is the cost point for VR prohibitive?
In virtual reality, one of my favorite apps is CoSpaces. It allows anyone to design a 3D space, and then interact with it in virtual reality.
Virtual reality can be quite affordable with Google Cardboard. We can get into basic interaction in VR with Cardboard. There are 40 or 50 VR apps where you can simply use Cardboard and explore. Google Street View allows you to do virtual viewing of many different locations. That technology augments what the teacher is doing.
Most kids can’t afford to buy their own Oculus headset. That price point is quite a bit higher. But we don’t need to have 30 kids using Oculus all of the time. Two or three might work
We’re now seeing a move toward mid-range, standalone VR headsets with everything built into the device. Some include their own processors, while others, like the forthcoming Microsoft headset, will work with current desktops. Microsoft’s device claims to do both VR and a modified version of mixed reality
The low end of the VR spectrum has been dominated by Google Cardboard, with over 10 million distributed
Augmented Reality
AR burst into the public’s consciousness with the Pokemon Go craze in 2016. And Snap (formerly Snapchat) expanded the range of their social media platform with the release of Spectacles, their wearable glasses and World Lens filters that add digital objects to your environment. A second version of Spectacles may include far more extensive AR capabilities.
At Facebook’s spring F8 conference, Mark Zuckerberg made the case that our mobile cameras will be the first popular AR platform. Apple just announced ARKit for iOS at their June WWDC developers conference.
Mixed Reality
Meta Glasses has been developing its own mixed reality unit that offers a wider field of view than the 40° of HoloLens. And Intel’s Project Alloy promises a “Merged Reality” headset prototype combining both VR and AR by the end of this year.
Kickstarter Projects
Aryzon which is creating a Google Cardboard-like device for simple AR experiences. Another is the NOLO Project, which offers an HTC Vive-like experience with full freedom of movement using only a plastic headset and your phone.
Market research firm Technavio has identified the top five vendors in the global augmented reality (AR) in education market. The companies are EON Reality, DAQRI, GAMOOZ, Magic Leap and QuiverVision, according to a newly published report.
The Internet of Things (IoT), augmented reality, and advancements in online learning have changed the way universities reach prospective students, engage with their current student body, and provide them the resources they need.
The Internet of Things has opened up a whole new world of possibilities in higher education. The increased connectivity between devices and “everyday things” means better data tracking and analytics, and improved communication between student, professor, and institution, often without ever saying a word. IoT is making it easier for students to learn when, how, and where they want, while providing professors support to create a more flexible and connected learning environment.
Virtual/Augmented Reality
Virtual and augmented reality technologies have begun to take Higher Ed into the realm of what used to be considered science fiction.