Investment continues to flow to ed tech, with $803 million injected during the first six months of the year, according to the industry news website EdSurge. But half of that went to just six companies, including the celebrity tutorial provider MasterClass, the online learning platform Udemy and the school and college review site Niche.
From the outside, the ed-tech sector may appear as if “there’s a bonanza and it’s like the dot-com boom again and everybody’s printing money,” said Michael Hansen, CEO of the K-12 and higher education digital learning provider Cengage. “That is not the case.”
Even if they want to buy more ed-tech tools, meanwhile, schools and colleges are short on cash. Expenses for measures to deal with Covid-19 are up, while budgets are expected to be down.
Analysts and industry insiders now expect a wave of acquisitions as already-dominant brands like these seek to corner even more of the market by snatching up smaller players that provide services they don’t.
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Tech-based contact tracing could put schools in murky privacy territory
A white paper from the Surveillance Technology Oversight Project (STOP) suggests the use of contact tracing technology by schools could erode student privacy and may not be effective in preventing the spread of coronavirus.
Despite the pandemic, schools still must conform to the Family Educational Rights and Privacy Act (FERPA) and other laws governing student privacy. Districts can disclose information to public health officials, for example, but information can’t be released to the general public without written consent from parents.
The Safely Reopen Schools mobile app is one tool available for automating contact tracing. The idea is that if two mobile phones are close enough to connect via Bluetooth, the phone owners are close enough to transmit the virus. The app includes daily health check-ins and educational notifications, but no personal information is exchanged between the phones, and the app won’t disclose who tested positive.
Colleges are also using apps to help trace and track students’ exposure to coronavirus. In August, 20,000 participants from the University of Alabama at Birmingham were asked to test the GuideSafe mobile app, which will alert them if they’ve been in contact with someone who tested positive for COVID-19. The app determines the proximity of two people through cell phone signal strength. If someone reports they contracted the virus, an alert will be sent to anyone who has been within six feet of them for at least 15 minutes over the previous two weeks.
Critics of the technology claim these apps aren’t actually capable of contract tracing and could undermine manual efforts to do so.
Use of students’ mobile phones during the lesson, when instructed properly, can be an effective tool when learning foreign languages and many other subjects.
Santiago, P., et al. (2016), OECD Reviews of School Resources: Estonia 2016, OECD Reviews of School Resources, OECD Publishing, Paris, http://dx.doi.org/10.1787/9789264251731-en.
Juxtapose JS from Knight Lab is a free tool for making and hosting side-by-side comparisons of images. The tool was designed to help people see before and after views of a location, a building, a person, or anything else that changes appearance over time. Juxtapose JS will let you put the images into a slider frame that you can embed into a webpage where viewers can use the slider to reveal more or less of one of the images.
Storyline JS is one of the newer Knight Lab offerings. This beta product is designed to help students tell stories with data. The basic purpose of Storyline JS is to help students can create interactive line graphs. Students add annotations to the data points their line graphs. Those annotations are used to tell the story of the data represented in the graph.
Scene VR is another beta product from Knight Lab. The purpose of Scene VR is to enable users to stitch together panoramic images and VR images to create an immersive photo story. Stories published through Scene VR can be embedded into websites and viewed on desktop computers as well as on tablets and mobile phones.
If you want to embed audio into a written story, Soundcite JS is the tool for you. Soundcite JS lets you add audio clips to a written story. When Soundcite JS is properly used, a play button appears where you specify in the text. For example, if I wrote a story that included a scene in which a dog barks, I could have “the dog barks at the stranger” be highlighted with a play button that when clicked plays the sound of a dog barking.
StoryMap JS lets you combine elements of timelines and maps to create mapped stories. On StoryMap JS you create slides that are matched to locations on your map. Each slide in your story can include images or videos along with text. As you scroll through your story there are simple transitions between each slide. StoryMap JS integrates with your Google Drive account. To get started with StoryMap JS you have to grant it access to your Google Drive account. StoryMap JS will create a folder in your Google Drive account where all of your storymap projects will be saved. With StoryMap JS connected to your Google Drive account you will be able to pull images from your Google Drive account to use in your StoryMap JS projects. Here’s a good tutorial video made by Jan Serie Center’s Digital Liberal Arts initiative at Macalester College.
despite China’s many technological advances, in this new cyberspace race, the West had the lead.
Xi knew he had to act. Within twelve months he revealed his plan to make China a science and technology superpower. By 2030 the country would lead the world in AI, with a sector worth $150 billion. How? By teaching a generation of young Chinese to be the best computer scientists in the world.
Today, the US tech sector has its pick of the finest minds from across the world, importing top talent from other countries – including from China. Over half of Bay Area workers are highly-skilled immigrants. But with the growth of economies worldwide and a Presidential administration hell-bent on restricting visas, it’s unclear that approach can last.
In the UK the situation is even worse. Here, the government predicts there’ll be a shortfall of three million employees for high-skilled jobs by 2022 – even before you factor in the immigration crunch of Brexit. By contrast, China is plotting a homegrown strategy of local and national talent development programs. It may prove a masterstroke.
In 2013 the city’s teenagers gained global renown when they topped the charts in the PISA tests administered every three years by the OECD to see which country’s kids are the smartest in the world. Aged 15, Shanghai students were on average three full years ahead of their counterparts in the UK or US in maths and one-and-a-half years ahead in science.
Teachers, too, were expected to be learners. Unlike in the UK, where, when I began to teach a decade ago, you might be working on full-stops with eleven-year-olds then taking eighteen-year-olds through the finer points of poetry, teachers in Shanghai specialised not only in a subject area, but also an age-group.
Shanghai’s success owed a lot to Confucian tradition, but it fitted precisely the best contemporary understanding of how expertise is developed. In his book Why Don’t Kids Like School? cognitive Dan Willingham explains that complex mental skills like creativity and critical thinking depend on our first having mastered the simple stuff. Memorisation and repetition of the basics serve to lay down the neural architecture that creates automaticity of thought, ultimately freeing up space in our working memory to think big.
Seung-bin Lee, a seventeen-year-old high school graduate, told me of studying fourteen hours a day, seven days a week, for the three years leading up to the Suneung, the fearsome SAT exam taken by all Korean school leavers on a single Thursday each November, for which all flights are grounded so as not to break students’ concentration during the 45 minutes of the English listening paper.
Korea’s childhoods were being lost to a relentless regime of studying, crushed in a top-down system that saw them as cyphers rather than kids.
A decade ago, we consoled ourselves that although kids in China and Korea worked harder and did better on tests than ours, it didn’t matter. They were compliant, unthinking drones, lacking the creativity, critical thinking or entrepreneurialism needed to succeed in the world. No longer. Though there are still issues with Chinese education – urban centres like Shanghai and Hong Kong are positive outliers – the country knows something that we once did: education is the one investment on which a return is guaranteed. China is on course to becoming the first education superpower.
Troublingly, where education in the UK and US has been defined by creativity and independent thinking – Shanghai teachers told me of visits to our schools to learn about these qualities – our direction of travel is now away from those strengths and towards exams and standardisation, with school-readiness tests in the pipeline and UK schools minister Nick Gibb suggesting kids can beat exam stress by sitting more of them. Centres of excellence remain, but increasingly, it feels, we’re putting our children at risk of losing out to the robots, while China is building on its strong foundations to ask how its young people can be high-tech pioneers. They’re thinking big – we’re thinking of test scores.
soon “digital information processing” would be included as a core subject on China’s national graduation exam – the Gaokao – and pictured classrooms in which students would learn in cross-disciplinary fashion, designing mobile phones for example, in order to develop design, engineering and computing skills. Focusing on teaching kids to code was short-sighted, he explained. “We still regard it as a language between human and computer.” (My note: they are practically implementing the Finland’s attempt to rebuild curricula)
“If your plan is for one year,” went an old Chinese saying, “plant rice. If your plan is for ten years, plant trees. If your plan is for 100 years, educate children.” Two and half thousand years later chancellor Gwan Zhong might update his proverb, swapping rice for bitcoin and trees for artificial intelligence, but I’m sure he’d stand by his final point.
students were caught cheating with smart watches over the period examined, and cases of students using hidden earpieces or miniature cameras were reported at multiple universities.
The Guardian found multiple websites that openly targeted students with devices that could be used for cheating.
new forms of human-computer interaction (HCI) such as augmented reality (AR),virtual reality (VR) and mixed reality (MR).
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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.
1. Can you find apps and sites suitable for all students’ devices? 2. Can your network handle the number of devices that will be added to it? 3. Are you going BYOD to save money by not providing computers to students? 4. How are your students going to share files and or print files? 5. How will you handle inappropriate use of mobile phones?