Drones, Fruit Pianos and Internet of Learning-Things in San Luis, Argentina

Argentina is recognized by the World Bank as one of the top 10 countries with big education laptop projects to learn from, and San Luis – a province in the heart of Argentina – is leading the way. San Luis is home to one of the most impactful education technology initiatives in Latin America, and I was fortunate to be invited to give the keynote for the education track at San Luis Digital 2013 – their annual festival of technology. The presentation was entitled ‘Technical Creativity’ – a whistle-stop tour of the Internet of Learning-Things.

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A key part of the presentation was a demo of the Parrott 2 Drone…

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This ARM powered drone connects to a mobile phone via a local Wi-Fi link and sends live video feeds back to the phone or to a USB stick, which allowed me to shoot this aerial view of the audience –

I was joined on stage by Alejandro Munizaga, Dean of Universidad de La Punta, who demonstrated his piano playing abilities on a banana keyboard using MaKey MaKey and Scratch.

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Slides from the event can be downloaded here –

English version

San Luis Keynote, Internet of Learning Things

Spanish version

San Luis Keynote, Internet Educativa – Spanish

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This, the 7th San Luis Digital, saw a crowd of 30,000 people attend a feast of events ranging from hackerthons and robotics competitions, to DJ sets. The event gave a 360 degree view of the social use of technology – health, security, environment, traffic management etc.

Education was very well represented there, and justifiably so. The province of San Luis is well into a One-to-One initiative as part of their investment in education, science and technology. All citizens have free WiFi internet access from anywhere – a right enshrined in law and delivered through WBS-2400 base stations across the entire region.

wifi base station

The government aims to increase maths, reading, writing, science, and ICT skills to prepare future engineering and science professionals. Most children now have a Classmate laptop, and over the next 10 years, the government plans to purchase 10,000 laptops each year until all 104,000 school-age children have a device. According to an IDB evaluation, results have demonstrated notable improvements in language, math, and science achievement following the integration of One-to-One programs in San Luis classrooms.

A notable area of success on display at San Luis Digital 2013 is robotics. A project called “Robotics for All” which is run from the University of La Punta supplies the schools with robotics kits. Each kit has an Arduino board and custom software resembling Scratch runs on Classmates to allow the students to program their robots.

The results are highly impressive. Students from San Luis, represented Argentina and came in the top 5 at the recent Robotics World Cup in the Netherlands. Children as young as 7 explained how they made a model city with working traffic lights, whilst older students battled it out with Arduino based robots.

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The event was completely packed with children eager to learn about the latest in technology and robotics, and sessions lead by the wonderful Gonzalo Zabala –

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San Luis is a shining example of where a combination of clear vision, political will, government backing, organizational capability, and a socially integrated higher education sector come together for the good of all.

I was lucky to be able to visit some schools there including the Isaac Newton and Nelson Mandela schools. Schooling in San Luis certainly lives up to its reputation for being best in class for the creative use of technology.

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Thanks to all the children and teachers that I met in the San Luis Digital and Nelson Mandela schools; Alejandro Munizaga, Marcela Magallanes, Daniel Rivas, Cristian Moleker and the team at La Punta University; Marcelo Sosa, Minister of Education; Silvina Peralta; Gonzalo Zabala for inspiring presentations; Jimena Jacubovich, Hernan Muhafara, Mariana Maggio, Angel Dubon, and Miguel Ayerza from Microsoft; Axel Esteban Seleme for terrific photos; and Leticia Martinez and Elina Pascucci, Translation San Luis, for translation services.

What is Ubiquitous Learning?

There is a lot of talk at the moment about Ubiquitous Learning. But what exactly is it, should we care, and how should it be implemented? This article by Edutech Associates member Nick Fekos explores these questions.

Ubiquitous computing is a model of human computer interaction in which computer processing has been integrated fully into daily activities, and also integrated into objects with which we routinely interact.  A Ubiquitous Learning Environment enables learning at any time, at any place.

Imagine you are a high school physics teacher and you are teaching concepts like gravity, friction, velocity and inertia. In a classic learning environment, you would be in your classroom with your students at a preset school period. But what if you could teach these concepts by taking your students to a soccer game or baseball game –

Origins of UL  

Mark Weiser from the Xerox PARC Lab ‘fathered’ UL more the twenty years ago. He envisioned three computer waves: mainframes which were prevalent at the time, personal desktop computers which were just appearing, and ‘Ubiquitous’ computing (also known as ‘ubicomp’), as the future. This third step is often referred to as reaching a point where the user is not aware of the computer, whatever form it has taken, but focuses only learning and the related materials.

Weiser identified three types of computer devices:

  • Wearable
  • Handheld
  • Interactive Boards

And their main characteristics would be:

  • Helpers/Servants
  • Quite and Invisible
  • User not necessarily aware of their presence, just the interaction
  • Should not demand attention

Key characteristics of Ubiquitous Learning

The main characteristics of ubiquitous learning are: (Chen et al., 2002; Curtis et al., 2002)

  • Permanency: Learning materials are always available unless purposely deleted.
  • Accessibility:  Access from everywhere as personally required
  • Immediacy:  Wherever a student is, he/she can immediately access learning materials.
  • Interactivity: Online collaboration with teachers and/or peers (chat/blogs/forums)
  • Situated instructional Activities: Learning in context (on-site).
  • Adaptability: Getting the right information at the right place for the right student.

Pedagogical Basis of UL

The main pedagogical premise of Ubiquitous Learning is related to ‘situated learning’ (see J. Lave and E. Wenger, 1991) which is a general theory of knowledge acquisition that is based on the notion that ‘true’ learning occurs in the context of real life activities. In contrast, formal classroom learning implies knowledge abstraction and decontextualization. This abstraction may not be such a problem, but learning in context (as illustrated at the beginning of the article) can certainly improve learning (as does engaging learners in authentic tasks).

Another pedagogical premise of UL would be collaborative learning (involving social interaction), again undoubtedly improving the learning process.

UL in the Context of Today’s and Tomorrow’s Technology 

Today’s technology seems to be trending towards the actualization of the original UL concepts as described by Mark Weiser.  Two out of the four essential components have already been established, and two are just now appearing as described below.

1. Mobile Devices: powerful, personal mobile communication, processing and storage devices

The proliferation of personal mobile devices, starting from smart mobile phones and currently progressing to tablets, has created an important shift in the direction of innovation as an intrinsic aspect of technology.  Perhaps not yet widely apparent in terms of the potential, but the shift has happened and is irreversible.

We now have a hardware device (a tablet) that is highly ‘personal’, similarly to how personal a mobile phone is, but much more personal than a desktop pc or a laptop.

This computing device, although in exchange for a certain degree of ‘personalization’ compared to mobile phones, is able to powerfully communicate, store, process and access information. It has the mobility and autonomy of a mobile phone, but the processing power and screen of a computer, and so it is much more suitable for broader and more fundamental use. Importantly, it provides the opportunity to move away from an ‘Angry Birds’ takeover of mobile technology

2. Cloud Computing

Cloud platforms can now provide the server side ‘omnipresent’ aspects of UL.  Any system with UL characteristics would have to be fully cloud based so as to ensure reliability and seamless scalability.  If design and development is originally geared towards maximizing efficiency by keeping required cloud power low, ‘lean’ cloud applications can be developed that can then be scaled much more powerfully, thus enabling efficient and robust UL.

Intelligent Personal Agents/Knowledge Objects

Given that we now have widespread truly mobile hardware devices, the next step is intelligent personalized software.

In order to truly implement UL and make ‘real’ use of available hardware and software platforms, the implementation of a personal knowledge object/agent that is ‘intelligent’ is essential.  Using Artificial Intelligence Techniques, this object/agent would take part in a ‘learning network’ (i.e. learn automatically) and would contain a rule base from which to make decisions.

This knowledge object/agent would model the ‘learner’ and would be dynamic.  It would have attached processes that would implement functionality like the ability to interface with other objects like itself, or to other non-intelligent objects (e.g. Word document) or to other systems (e.g. SharePoint) or devices (e.g. a telescope).

This interface functionality would be implemented using standardized file formats and access languages, like HTML5, SQL, RDF and OWL which are available today. The latter two introduce the idea of semantic processing, moving beyond the ‘text’ level into concepts and conceptual organization schemes (Ontologies).  Once we move into the conceptual processing realm (Artificial Intelligence), then very important and exciting functionality, like knowledge inference (reasoning) can be provided, which will mark a true technological turning point.

In summary, this platform independent knowledge object/agent would be the main vehicle for implementing Ubiquitous Learning (as described above) as it would know:

  • Who you are
  • Where you are
  • What device you are using
  • Dynamic skills and ability profile
  • Whether it is night or day
  • What time its
  • Who is near you
  • What devices are near you

Although seemingly too ‘futuristic’, the proliferation of wearable online devices will further the implementation of UL. A good example is Google Glasses (http://en.wikipedia.org/wiki/Project_Glass), with many more on the way.

A specific example

A student carrying a tablet approaches a telescope at school. The telescope ‘broadcasts’ its availability to the tablet which then informs the student of this. If the student agrees, the tablet connects to the telescope and sends information through its intelligent personal learning agent about the student, for example age, class, learning profile, interests, past projects and so on.

The telescope then transfers information that is appropriate for that particular student about itself, what it can do, and perhaps showing on the tablet screen what it is seeing right now. Also, the telescope connects to a cloud astronomy app, or to the Microsoft World Wide telescope for added experience and information.

Finally the telescope proposes a small interactive game from which it can assess the student to see what has been learned or not, and then perhaps contacting a fellow student to join the game online.

One thing is certain: the students would enjoy this, and so learning and assessment will have been achieved. This of course would be part of a broader educational strategy that would include other forms of learning, including classic learning paradigms.

Many of the pieces of the UL puzzle are now starting to fall into place, as summarised in the diagram below:

Please contact nikos@edutechassociates.net for more information.

What can we learn from South Korea?

Of all the places I’ve visited, I’ve not seen technology so deeply embedded into daily life anywhere as much as in South Korea. Boasting technology giants such as Samsung and LG, South Korea places a conspicuous high value on technology in practically all aspects of life.

Korea’s remarkable technology driven growth has also been accompanied by improvements in social equity. How? Investment in human capital – as evidenced by their PISA results in recent years.

South Korea is well known for their results in the OECD PISA survey

Korea rides high in PISA (pic c/o Wikipedia)

Unlike Finland, whose high ranking in PISA can be attributed to excellent public schooling, Korea’s investment in human capital is significantly influenced by private investment. Parents with school-age children spend close to 25 percent of their income on education and all parents spend a large portion of their income on supplementary educational materials. Private education cost 3.95% of GDP in 2006. According to colleagues in South Korea, students acquire about 30 percent of their formal learning through their schooling, and the rest through supplementary measures.  

So what motivates parents to spend such large amounts of money on private tutoring outside the state schooling system? The main driver is that education is viewed as being crucial for success. At three or four years old, Korean children begin the long and strenuous race to higher education where Science and Engineering dominate.

Examination time is a very serious times of the year and the whole pattern of society changes. Businesses often start at 10AM to accommodate parents who have helped their children study late into the night and on the evenings before exams. The entire schooling system is geared to college entrance, so the curriculum of most schools is structured around the content of the entrance examination.

The Korean government spends generously on education (4.5% GDP in 1986); children spend a lot of days in school (220 days in Korea vs 180 days in the US); and school children work very long hours too. While these factors help with test scores, Korea is remarkably inefficient at a PISA criterion known as “study effectiveness”. South Korea ranks only 24th out of 30 developed nations in this measure. Top in study effectiveness is Finland, where time in school and hours spent studying is significantly less than Korea.

While many if not most other countries look on Korean performance on international tests like PISA with envy, in Korea itself there appears to be an intense pressure to do better, and in this highly technocratic country, its little surprise that technology is seen to be an important component.  

Technology Developments

Korea has been ‘computerizing’ schools for the last 15 years or so, and was the first country in the world to provide high-speed internet access to every primary, junior, and high school. ICT is also an increasing focus in the Korean Government’s education strategy, and in recognition of their progress, Korea won 1st prize from UNESCO for ICT in Education in 2007. So you’d be forgiven for thinking that this lead to Korea coming top in PISA Digital Literacy tests in June 2011 – however computer use is often restricted to teachers presenting information to students.

The real reason Korean students do so well in Digital Literacy is the intense use of technology after school – in Internet cafes, “cram schools” and the home where children can use the world’s fastest home Internet connections – on average 100 Mbps now, and with plans to increase this to 1 Gbps.

Several government initiatives have been set up to bridge the gap between the different levels of effectiveness of learning at home and at school. The overall goal of Government ICT initiatives is to ensure that by 2014 Korean school children will be competent with 21st century skills and are talented at innovating with future digital technology.

Much of the government’s initiative in ICT is channelled through KERIS – a Government Research Institute that acts as the country’s national ICT/education agency. KERIS’ Future Schools programme has conducted 39 research projects and 14 development projects focussed on new learning methods based on new technology. 

Infrastructure Development

The current priority from a budget standpoint is the acquisition of hardware and modernising class facilities. By 2010 there was a ratio of 5 students per PC – the intent of this investment was to support the development of creativity and problem-solving.

IT Expenditure Priorities

A second budget priority is to increase the number of classrooms that have been transformed to achieve “ubiquitous-learning” (u-learning).

Digital Textbook Project

KERIS has been piloting ‘digital textbooks’ in various forms in preparation for the move by 2015 to using digital textbooks in all schools in all subjects at all levels. The idea is that digital textbooks will be accessed/viewed on many different types of devices, from tablets to desktops to laptops to phones.

Cyber Home Learning System

In an attempt to reduce the cost of private education KERIS also developed content for the Cyber Home Learning System. Launched in 2004, CHLS is an online learning service supporting student’s self-directed learning. Click here to find out more – http://www.youtube.com/watch?v=CF8XdvA4ajk

Cyber Home Learning System

The next generation of the CHLS will include community, e-portfolio and analytical functions.

Next Generation of CHLS

EDUNET

KERIS set up and operates EDUNET, an educational information service which distributes a diverse range of high quality educational content. Content ranges from sound, photo, image, animation, module and video and is all specified by curriculum. As of October, 2010, the number of EDUNET users reached 6.17 million out of a school student population of 7.7m. To see a sample of the content, view a short video here. 

Education Broadcasting Services on the Internet (EBSi)

A service that has seen a sharp rise in growth recently is EBSi. This is where key education broadcasting service assets are made available for download. In 2010, daily usage of video-clips of lectures was 574,461, a 78% increase from the same period of the previous year.  

Teacher Training

Advances have been made too in teacher training. Not only are increasing numbers of teachers licenced to teach ICT, distance education training based on e-Learning has become the core method of teachers training. Distance learning is available to students too via “Air and Correspondence High School”.

NEIS (National Education Information Service)

The Korean Government is keen to develop the use of data systems in education. In a drive to reduce teacher workload, an administration system called NEIS (National Education Information Service) was developed. By streamlining procedures, many administrative processes can now be done in one-step. The system connects all stakeholders of the student, to allow them to get “to Know Our Children Better”. NEIS integrates student records across a range of fields including assessments, examination and health data.

The first task in creating NEIS was to develop the physical infrastructure. The aging facilities of the overall education management centre and 16 Metropolitan and municipal education offices were replaced. 3,800 servers with databases were installed in schools and integrated into a datacentre comprising 100 servers in upstream education offices.

To help teachers adapt, training is provided, and structured guides are available on the teacher area of Edunet.

 

(MPOE – Metropolitan and Provincial Offices of Education)

(MEST – Ministry of Education, Science and Technology)

After infrastructure, the next key ingredient was Business Process Reengineering and Information Strategy Planning (BPR/ISP) for constructing the business management system for the MPOEs. A transmission system for electronic funds transfer (EFT) system was created at the Korea Financial Telecommunications and Clearings Institute.

The School Information Disclosure System allows anyone including students and parents to easily receive information about schools. The system is designed to increases parents and the local community’s interest and participation in the schooling system. In addition, the government and the Offices of Education are expected to boost policy achievements by establishing even more efficient policies through situational reality analysis of school units using the School Information Disclosure System.

Where next?

Whilst Korea is developing one of the best IT infrastructures in the world, there are three key areas that need focus:

  • According to “Adapting Education to the Information Age”, Software Infrastructure in Korea is behind to developed countries and a change is required to develop capacity in this area.
  • A second area for development is lifelong learning. 28% of adults participated in the lifelong learning in 2009, which is lower than major advanced countries – eg EU average participation rate is 37.9%.
  • Perhaps the most important area of focus is 21st century skills. Korea has few programs in this area, and with Communication and Collaboration now part of the PISA 2012 framework, this area is in need of development.

To learn more:

Excellent blog article by Michael Trucano with links to in-depth resources: http://blogs.worldbank.org/edutech/e-learning-in-korea-in-2011-and-beyond

BYOD / BYOC?

The question of “Bring Your Own Device” (BYOD) is dividing opinion across the world of Ed Tech – and increasing scrutiny over how schooling budgets are spent is fuelling the debate. In essence, BYOD is about letting students bring their own devices – from mobile phones to full blown laptop PCs – into school as part of formal learning. Regardless of whether this approach is right or wrong, increasing numbers of schools – particularly in the United States – are adopting this approach.

In the US, BYOD is often seen as a strategy for schools to do more with less. EdWeek reported that one US State paid $56k in repairs for the computers they lease for $175k annually, so it’s easy to see how BYOD can seem an obvious approach for some. However, shifting the ownership of devices has many complex implications for how schooling systems operate. BYOD has complex and hidden costs which need to be considered carefully.

This article sets out the arguments for and against BYOD, highlights key considerations and proposes some potential ways forward.

What is BYOD?

In adopting BYOD, schooling is following a broader trend in the world of business. Monica Basso, Research VP at Gartner, predicts that by 2014 “90% of organizations will support corporate applications on personal devices.” At companies like Kraft Foods, rather than providing some employees with a standard laptop configuration, money is offered to let staff go out and get what they want.

Delloite observes that “most [business] users strongly believe they should be allowed to install any mobile application, visit any mobile website, and store any personal data they want on their personal device regardless of who paid for it”.

According to Forbes, reported on Yahoo, the adoption of technologies in the enterprise is increasingly being driven by consumer preference, not corporate initiative. “Many organizations are considering allowing personally-owned mobile devices to access business applications in order to drive employee satisfaction and productivity, while reducing their mobile expenses”.

In schooling, BYOD has different goal – it’s about enabling students and teachers to bring their own devices into school to support formal learning and productivity.

Why Should BYOD Be Considered?

From just a utility perspective, BYOD makes perfect sense. Why have a computer gather dust in the student’s bedroom while they are in school, and why have a school computer gathering dust in the 85% of time that students are not in school? Consolidating two resources into one has great potential for cost savings. Where the number of computers in a school is low, BYOD can be a quick way to boost access levels.

BYOD saves the school having to buy all the children a device, allowing school funds to be focused on providing access to the less well-off pupils.

Cary Harrod writing on the AALF blog –

“We launched our BYOL program this past January with our 7th graders. It was an overwhelming success in several key ways:

Out of 559 7th graders, we had 353 students bring in their own laptop, netbook or tablet pc. Add that to the 160 district owned devices and it’s easy to see that one of our major goals was met…to increase access to technology for ALL 7th graders… we successfully increased access to students who were unable/unwilling to purchase their own device access to technology without the barrier of having to check out a cart of laptops”.

Carry’s school didn’t’ service the computers either. “It was made clear to the parents that they owned the device… it was no different to when I take my device to Starbucks; Starbucks does not assume responsibility for my device…I do”.

Carry’s school is teaching their students “how to select the best computer and the most appropriate tools for their individual needs” and “through intensive professional development “we were able to move our teachers towards a student-centered way”

Why not BYOD?

Not everyone supports the BYOD concept. In fact, many people do not. Jim Wynn, former Headteacher and now senior Director at Promethean doesn’t believe BYOD is a viable concept for the classroom yet.

Imagine the possibility of 25 students walking into a classroom with what could amount to 25 different devices – with a teacher who is afraid of computers! Imagine the kinds of things that teachers could potentially hear in a BYOD environment:

“Miss, how can I get my phone to see the Wi-Fi”

“Sir, my battery has run out”

“Sir, a big boy put my computer in the bin”

Even the most advanced adult technology users frequently suffer from common technical issues such as getting Bluetooth devices to connect, so letting students loose across a range of technologies during classes is a recipie for potential chaos.

There are other factors to consider too:

  • The most commonly owned mobile device is mobile phones. Not everyone has got a phone that is powerful enough to enable high quality research, homework, coursework, revision, etc
  • Variation in the different types of student-owned devices, from Blackberries to i-Pads to Laptops, may make it hard for teachers to run lessons where they may want all the students to undertake the same tasks
  • Health & safety liability and requirement for all devices to be tested for suitability for use in a schooling environment

Gary Stager writing in AALF news asks “BYOD – Worst Idea of the 21st Century?” and says that BOYD:

  • Enshrines inequity
  • Narrows the learning process to information access and chat
  • Increases teacher anxiety
  • Diminishes the otherwise enormous potential of educational computing to the weakest “device” in the room
  • Contributes to the growing narrative that education is not worthy of investment

“Of course teachers should welcome any object, device, book or idea a student brings to class that contributes to the learning process. However, BYOD is bad policy that constrains student creativity, limits learning opportunities and will lead to less support for public education in the future”.

Towards BYOC

Gary Stager, asks “when was the last time you walked into a computer store and said, “I’d like to buy a device please?” Nobody does that. You buy a computer….. BYOD simplistically creates false equivalencies between any object that happens to use electricity… Repeat after me! Cell phones are not computers! They may both contain microprocessors and batteries, but as of today, their functionality is quite different”.

“Kids need a personal computer capable of doing anything you imagine they should be able to do, plus leave plenty of room for growth and childlike ingenuity”.

Whilst Cloud computing and HTML 5 will make the type of computer that you are using less important in the longer run, let’s be clear – effective learning with and through technology requires that students have computers. Ultimately, we want students to produce content – not just consume it – and develop their own learning experiences.

Ideally, every student should have their own computer for use both in and out of school. There will be many places where this just isn’t practical for all students, so in these cases there should be an appropriate progression towards increasingly available and increasingly powerful computing, so by the time a student leaves school, they are fully IT literate and ready to enter the university or the jobs market with a computer that they know how to use, and with a portfolio of high quality materials, applications and resources – online and on their hard-drive.

“Hybrid BYOC”

Clearly, BYOD or even BYOC as a blanket approach in any schooling system is going to be problematic.

Bruce Dixon again – “We are most likely going to see a gradual shift of the responsibility for the provision of a personal portable computer for our students from schools to families, as costs come down further, and computers are commoditized even more. But it will take time for the most effective funding, implementation and management models to be developed, and I expect they will, for the most part, be blended models”.

According to the e-learning Foundation, “In some areas all the pupils might have a suitable device they can bring in, so there’s no stigma attached to those who don’t have their own”.

There’s a crucial point here – BYOC may work in some areas – particularly where consumer technology usage amongst students is high and consistent. In other areas BYOC may not work at all because of a lack of appropriate devices in the hands of students.

There is no need to think of BYOC as a “blanket” approach at single school level either. E.g. at West Hatch School, London, just those students between 16 and 18 years old who have elected to stay at school for an extra two years can bring their own computers to school and access school resources.

Practical Considerations

Whether BYOC is the right approach or not, there is an increasing number of schooling systems under extreme budget pressures so there’s a practical reality that has to be addressed right now.

For those schools wishing to consider BYOC, an understanding of complex issues such as trust and liability is essential.

Trust

Which users do I trust with which data and applications and under what circumstances? Every organization should have its data classified in terms of who has access to it. However, BYOC adds another layer of complexity to the trust models because BYOC computers are not locked down as tightly as school owned computers, so can easily fall in and out of compliance.

Acceptable Use Policies will vary, and user expectations will differ. On school owned devices, users may accept not being able to use social networking apps, but that type of policy is unacceptable for personal devices.

West Hatch gets around this problem for student-owned devices, to an extent at least, by using a role based portal. Alan Richards – “the only reason this [BYOC] works is the fact that all resource are available through SharePoint, so as well as shared documents they can access their email, home drives, media etc”.

Liability

Whilst schools should have risk assessments covering actions such as unsecured use of organizational data to accessing inappropriate applications or websites, BYOC introduces new complexities:

  • Different protections may be required on different devices, depending on type of device and the OS that they run on.
  • A teacher or student who brings in their own device may have the expectation that they can use it however they wish. Is inappropriate use still a liability for the school, even if it doesn’t affect its data?
  • How is liability affected when computers are partly funded by the school?
  • There is a risk – albeit a small risk perhaps – of the school accessing and damaging personal data (for example, if IT inadvertently wipes a user’s personal data or applications)

On teacher-owned computers, at least, both the trust and liability issues can be addressed in part by if end-point data encryption implemented.

Regardless of how robust and secure the IT system, every school wanting to implement BYOC should seek their own legal advice on how to frame and assess liability between BYOC and more traditional access programs.

Equity And Finance

A key risk of BYOC is increasing the digital divide, so a BYOC program would need to be combined with effective initiatives to acquire or upgrade ICT, for those students that need this, including subsidized models.

Bruce Dixon, Founder of AALF, has given advice on 1:1 access programmes for nearly 15 years – “one of the benefits from an effective 1:1 program would be to provide 24/7 access, and there is a reasonable expectation that parents should make some contribution for the 80% of the time their son or daughter could now use a laptop for personal use outside school. However, I’m not sure why we can now suddenly expect parents to pick up 100% of the cost.”

According to the “e-learning Foundation” – a trust supporting the 1:1 access initiatives in the UK -“schools will need to provide all students who cannot bring their own device into school with something suitable, otherwise the school will create a digital divide, favouring wealthier pupils”.

Beware Of Potential Unintended Consequences

Transferring the burden of purchase to the students’ parents can be a “double-edged sword”. For example, organisations in consortia have purchasing power that can potentially drive costs down when ordering large volumes of IT goods and services. Passing on the cost of PC ownership to the student reduces the volume of IT purchased by the institution and therefore reduces negotiating power. When purchasing occurs on a large enough scale, a widespread BYOC policy could potentially drive up the net cost of providing computers to those who the schooling system will still need to provide a computer to.

There could be other unintended consequences too. As Microsoft’s Edgar Ferrer Gil points out, if a school depends heavily on Flash based learning content, then a whole subset of devices will not be able to utilize those resources, so a BYOC policy in isolation could reduce the value of investments in devices, IT resources and content.

There’s a cost too in supporting different technologies. For example, in the world of business the widespread adoption of RIM Blackberry’s required an expensive Blackberry server.

Consistency

If several students have different types of software, then it will mean that teachers need to adjust to that. For instance, a teacher won’t simply be able to set up a lesson where the students collaborate using a single application or service. Imagine the scenario when an LMS won’t accept certain file formats leaving students to figure out how to turn in their assignments if its not in the correct file format.

If a BYOD or BYOC implementation allows any device to be brought in, then the organization can expect to see old, second-hand and possibly even stolen devices – which pose legal, and security risks from viruses or malware.

Edgar Ferrer Gil again – “Schools need to think carefully what BYOC means to them. There are things that are going to run fantastically well on the right kind of device – eg standards-based cloud services, internet connectivity, file sharing and in some cases virtualized desktops. But today, I think that the ROI of a fully-open BYOC policy will be extremely poor”.

IT System Architecture

BYOC can quickly lead to 1:1 access ratios, and this has significant implications for infrastructure and IT services –

Physical Environment

Cleary, having appropriate furniture, benching, electrical sockets for charging and extensive wireless access points, is a key first step. It’s also important to provide secure lockers for storage of computers when not in use.

Network

As device choice becomes fluid, confirming identity of user and device, usually through the use of certificates, becomes more important.

Proxy servers are required to present login requests to users when using their own computers in the same way as you would filter usage for students using a school-owned computer.

At West Hatch, all routes for external traffic from the school’s data switches point to a Smoothwall box which deals with proxying. Computers that are on the school domain point to the same box but to a specific port. Computers that students bring into the school don’t point to a port and are captured by Smoothwall, which presents the user with an SSL login page asking for their domain credentials. This gives the same kind of user experience as you would get when using an Internet connection in a hotel or public space. At West Hatch, this approach works across any device or OS.

Optimised Core Infrastructure

Managing the extra workloads that a BYOC program would place on a school’s IT infrastructure requires that the infrastructure is optimized – ie made more robust and secure. Infrastructure Optimisation is a program that should be applied to the school IT infrastructure if BYOC is being implemented.

Key elements covered in Core Infrastructure optimization include:

  • Client Services
    • Management
    • Security
  • Identity & Security Management
  • IT Process & Compliance

Another key technical consideration is support. Whilst, as already discussed, some schools are passing-off technical support to parents, the danger with this approach is inequity – some students will have to wait longer than others for their computers to be up and running. On the other hand, it’s completely unreasonable to expect schools to be able to support just about any device on the market.

The only realistic way around this is to have a BYOC policy that narrows the range of computers accepted in the school environment to reflect capacity of local support services – both inside and beyond the school. In other words, if neither the school nor local computer repair shop can support a particular Operating System or computer, it’s best not to include these in the BYOC policy.

Remote Desktop Services (RDS, formerly Terminal Services)

Working with mixed computers in a classroom can be made a lot easier if schools were able to “push” desktops to those computers. In other words, regardless of computer type or its Operating System, the student would get a desktop provided by the school. Such a desktop could contain a full range of applications and resources needed to cover the curriculum. As the desktops would be delivered from a Server, the only requirement on the device would be a browser and possibly a small client application.

The first and easiest way to do this is through Presentation Virtualization, which was covered in detail in the “From Virtualization to Private Cloud” article. A relatively straightforward way to deliver Presentation Virtualization is Windows Remote Desktop Services (RDS).

RDS applications run in Virtual Sessions, each projecting a Windows user interface to a remote client computer. For non-Windows computers, a Citrix client application can be installed and this will allow the same user experience as with a Windows device. (There are also 3rd party RDP clients available for slates and phones). In a Remote Desktop Session, the device processes only screen refreshes sent from the server, and mouse clicks and keyboard strokes are being sent back to server. Whilst users will get a Windows interface, it won’t be a Windows 7 interface. Administrators should be careful not to assign administration rights to RDS users.

Virtual Desktop Interface

VDI offers a more sophisticated approach to remote desktops. From the client device perspective much is the same as with RDS, but there is added sophistication on the server which gives additional scope for flexibility.

With VDI, sessions are delivered through Virtual Machines run within a Hypervisor such as Hyper-V. Each virtual machine can contain a different Operating System and a different set of applications. This allows school to offer each student has their own specific desktop, subject/topic specific desktops. As each virtual machine (VM) runs in its own environment trust relationships are easier to manage. Each VM is a file enabling easy backup and portability. The entire desktop “estate” can be run through a management product such as System Center.

West Hatch School is evaluating VDI, looking at it eventually as a web-based resource for access beyond the school gates.

Classroom orchestration

Ideally, a teacher would not only be able to push out a common virtualized desktop, but orchestrate a class too. This means having control over the computers whilst they are in the classroom. For BYOC schemes that stipulate bringing in Windows devices, Multipoint server can be used to combine old and new school-owned computers with student owned computers in a single, orchestrated network.

Conclusion

The net is that BYOC is really not the silver bullet to widespread access that it appears on the surface. The argument that IT can’t be funded is a not a budget question – it’s a prioritization question! BYOC won’t come free – it will require investment, and as always, the most important question to ask with any IT investment is “what outcome do you want?”

Bruce Dixon, writing in the AALF blog, observes – “Seems the last thing anyone wants to ask is, ‘What will they want to do with it?’”

Full BYOC, partial or no BYOC at all, it makes no sense to decide on an approach without first being crystal clear about what results or impacts are wanted.

Once the intended learning and operational outcomes are clear, Schooling Enterprise Architecture offers a formal process for developing impactful learning solutions. Whether BYOC is an appropriate approach or not depends entirely whether it fits with higher level organizational goals, circumstances and capacity. BYOC, ultimately, should be part of the process of simplifying ICT, and if adopted at all, it should be very carefully thought through.

Thanks to:

Sven Reinhardt, Edgar Ferrer Gil, Dan MacFetridge, Erik Goldenberg, Bruce Dixon, Jim Wynn, and Alan Richards for contributions to this article; and to Brad Tipp/Howard Gold for graphics.

Putting the “i” into Singapore Schooling

With top rankings in PISA and TIMMS, Singapore is the envy of many schooling systems around the world. Whilst ICT is just one of a range of factors that affect learning outcomes, it is a key tool for meeting at least two of the four key desired outcomes of the Singapore schooling system – for all students to become self-directed and collaborative learners.

Singapore was one of the first countries in the world to have a national strategy for ICT in Schools. A succession of well-planned, funded and executed programmes focussing initially on infrastructure and training, and more recently focussing on self-directed learning – has driven effective use of ICT. For details of Singapore’s main ICT projects, see http://wp.me/P16Iyp-46

A great showcase for the effectiveness of this investment is Crescent Girls’ School, a member of the “Future School” programme, and recently awarded the status of Mentor School by Microsoft. Crescent also hosted the CRADLE conference on 1st – 3rd August.

On the surface, Crescent could be any other Secondary School, but a quick glance at the trophy cabinet next to the reception makes it clear that this school is totally committed to high performance. Crescent’s aim is to be at the forefront of harnessing technology to enhance learning outcomes. ICT is used extensively in both delivery and assessment and the school’s 1300 students each have their own Tablet PC. The goal of using ICT is to give students a degree of choice over what they learn and how they learn.

The students engage in a wide range of activities including 2D, 3D animation and robotics; multimedia production; photo-shooting and editing; and development and use of e-books. Particularly impressive is the use of Tablet PCs’ “inking” features for a range of activities including highly impressive manga artwork.

Crescent is moving towards project based learning with a series of “Integrated Secondary Curricula” programmes.

Virtual Reality is used at the school too. For example, in Geography, students experience immersive content showing erosion in a river – a concept that is much easier to grasp when viewing 3d animated rocks being swept along by the current from the perspective of the river bed.

Particularly impressive at Crescent is the way that teachers engage in the content creation process. For example, a complete suite of applications and content have been developed for the Tablet PC that not only exploits the pen and inking technologies but also address a range of different learning styles.

Taking this process further, teachers specified collaborative games to take advantage of the MultiTouch features in Windows 7 and HueLabs’ “Heumi” multitouch (Surface) devices. This means that students can now engage in a wide range of collaborative learning experiences, such as learning to write Chinese. As impressive as the technology itself is the way in which the room in which the Heumi devices are deployed. Here, in the “iCove”, strong colour coding of the devices and the seating, enable teachers to group learners according to their learning objectives.

More recently the school has introduced a biometric system that not only automatically records the students as present but takes their temperatures as they come into the school in the morning, enabling their health to be monitored.

The infrastructure that sits behind Crescent’s ICT provision is highly impressive. The infrastructure foundation is a Campus-wide wireless network with 100 Mbps Broadband. Tablet PCs are stored in steel lockers, and batteries are charged at charging stations.

Approximately 30 on-premises servers perform a range of essential back-end functions from authentication to content management. The Server infrastructure – based on a Microsoft platform – supports a rich tapestry of capabilities including:

  • i-Connect Learning Space – a role based portal for organising student’s learning and activities
  • Pearson’s Write to Learn – a system that helps “automate” the marking of essays
  • HeuX – Huelabs Classroom Management System – with lesson management, digital book library, real-time Communication and Collaboration include notes-sharing and social media; screen monitoring and broadcasting; Presence awareness; attendance; Video Conferencing
  • i-Media – content management system.
  • Interactive books

These solutions are supported by Windows Server; SQL Server; Microsoft SharePoint Portal Server; System Center; Live Communications Manager; Hyper-V and Live@Edu. Much of the learning that takes place at Crescent happens after school hours, and the Virtual Private Network enables students to have 24×7 access. It’s not uncommon to see the portal being used by students at home at 2.00AM.

Singapore schools benefit from very high quality teachers (only 10% of applicants get admitted into teacher training). This is reflected in the staff at Crescent. Principal, Mrs Eugenia Lim, supported by Chief Technology Architect for Learning, Mr Lee Boon Keng, have a highly structured and team orientated approach, underpinned by a strong focus on continuous professional development.

Every hour, the chimes of Big Ben ring across the school signifying a change of lesson. As with Cornwallis School in Kent in the UK, I was totally inspired by what I saw at Crescent but couldn’t help wondering whether a shift from time-based to a performance-based model would better fit such a technology rich approach to learning. Nonetheless, Crescent’s use of ICT is without doubt world leading.

Whilst Crescent Girls’ School is clearly a leader amongst leaders, it’s far from unique in Singapore in the way in which it innovates with technology. Singapore schools benefit from long term, consistent policy and investment in ICT in schooling. With their structured approaches, strong management and deep understanding of how ICT can make learning more effective, Singapore schools look set to continue to show the world how it’s done.

Fortunately for us all, Crescent Girls’ School are “giving back” by encouraging people to visit the school – both physically and virtually.

Thanks to Eugenia Lim, Lee Boon Keng and all the staff and students at Crescent Girl’s School.

CRADLE Conference, Singapore

On August 1st I was fortunate to be given the opportunity to deliver the Keynote at the CRADLE conference in Singapore.

The presentation contained a mix of material contained in “Schooling at the Speed of Thought” and some of the articles in this blog, especially the Transformation Phase article. Here’s the key points:

ABSTRACT

Introduction

Singapore was one of the first countries in the world to have a national strategy to roll out ICT to all schools. Key challenges addressed in this initiative are to:

  • Prepare students to meet the challenges of the 21st Century
  • Bring about improved learning and increased engagement through the use of ICT
  • Enable more self-directed learning

In summary, the challenge is to make schooling in Singapore even more effective through the use of ICT.

To address this, we need to ask three key questions:

1. How can software accelerate the learning process?

Computers in learning are increasingly being used as tools for creativity rather than as machines to deliver the curriculum. So, with a proliferation of new hardware and software developments, what new creative options are there for learning? How can software help to personalise the learning experience and open up completely new learning opportunities?

2. How can software be used to make better decisions?

How can schooling information and data be leveraged to get maximum impact from precious resources; what do we mean by “intelligent intervention” and why it is so important; how can we empower all stakeholders with information; and how do we drive alignment and performance towards strategic goals?

3. How can Cloud Computing be exploited to cheaply deliver massive-scale, high-quality learning solutions?

We don’t normally expect a school to generate its own electricity – but we have expected our education institutions to be experts at running their own “IT Power Stations”. How can Cloud Computing change this?

With the advent of Cloud Computing, also comes the realistic prospect of providing anytime anywhere learning for all. So how can massive, cheap, and highly available computing services be combined with a range of access technologies and high quality learning content to open up learning opportunities to all citizens of Singapore – and especially those who are in the greatest need of it?

Conclusion

With highly developed infrastructure, talent and innovation, Singapore is in a great position to exploit technology even further. The concluding part of this presentation asked what world-leading innovations and software solutions can be leveraged in Singapore and how we can architect “anytime anywhere learning for all?

For a copy of the presentation please go to: http://bit.ly/pRZUMJ

Thanks to my colleages in Singapore – Horng Shya Chua; Jason Trump; Gerald Tan; Puay San Ng; Eugenia Lim, Lee Boon Keng and the staff and students at Crescent Girls’ School. Thanks also to all those who attended the CRADLE event.

The Transformed Phase

This is the fourth and final article on the phases of transformation that schooling systems go through. The first was “Taking the First Steps”, and this phase is characterized by access. The second, Taking the Next Steps – The ‘Enhanced’ Phase, is where technology is used to enhance existing processes. The third -“The Strategic Phase” – is characterized by using technology to meet strategic goals and help determine what those goals should be.

Feedback that readers have kindly sent me had prompted me to adjust the overall maturity framework so each of the main characteristics of each phase now look like this:

Four Stages of Schooling System Maturity

Whilst the three preceding phases were about applying technology to schools as they currently are, the Transformed Phase is about fundamentally changing the nature of schooling itself.

Using ICT to transform schooling allows us to ask questions such as “where is school”, “how do we deliver personalised and engaging learning experiences”, and “how can we develop highly effective and efficient schooling systems”?

Whilst transformation will mean many different things to many different people, there are three main ingredients to a transformed schooling system.

The first is providing anytime, anywhere learning for all citizens. The second is providing highly personalised experiences to all learners. The third is about building a culture of high performance throughout the entire schooling system.

Anytime Anywhere Learning For All

The first principle in transforming schooling is to redefine its “customer” base. At present, schooling reaches learners between the ages of 5 to 18, within narrowly defined geographic boundaries, and for around 18% of the year only. Now, there is a significant opportunity to deliver learning services to entire populations at relatively low costs. This is because the cost of digital content and software only marginally increases with the number of users, and because the cost of delivering e-learning services at massive scale through Cloud computing is increasingly cheap and getting cheaper.

To date we have thought about learning in the physical sense of going to a place called a school. Going forward, schools will facilitate learning less as a physical experience and more as one that can take place across different locations. Increasingly, we can expect the process of schooling to become less dependent on learners regularly attending a single campus over a long period of time.

Schooling will spread out of the physical confines of the school campus, and into ‘found space’ such as offices; high street locations; apartments; and even the homes of children.

The youngest learners need somewhere near their own home where they can physically go to access learning facilities; to learn with other groups of learners and access richer materials than those which they have in their own home. Older learners need learning spaces to interact with their tutors, counsellors and learning managers, but also need to learn in environments that are appropriate to their learning tasks. For example, a specialist science learning module – say optics, for example – may well be based in a traditional (campus) school laboratory, but equally there could be a company in the local community specialising in optics that would be willing for students to learn at their facilities.

In this model, there is still room for the traditional “Campus School”, but as a social, intellectual and resource hub – a place for those specialist learning facilities which might not be available in the local community such as laboratories, workshops, libraries, art studios and gymnasia. The Campus School is also a place from which to organise and manage learning and produce learning content.

The Campus School of the future will be a community resource; it will be open for 52 weeks a year, 7 days a week from 7.30 am (with breakfast clubs, computer clubs, gym facilities etc.), and will stay open until 10.00 pm (with after school clubs, homework clubs, sports facilities, cyber cafes etc). Its pupils will be aged 1 to 100. The four walls of a classroom/school will be replaced with online classrooms/schools/homes, ensuring access to technology and information for all.

Many university towns reflect this approach, where university learning facilities are embedded in the local community. Schooling is catching up. In “First Steps” we’ve already seen the ‘Kiosk’ model in India, where learning is simply put out onto the street to be consumed by self-organising groups of children. On the other side of the world, in New Zealand, Discovery Learning has schooling facilities deeply embedded in the community with locations in shopping malls and central business districts. Here, “school” isn’t a building and children are given “trust licences” to learn where they need to in the local community.

In this model, there is a vast spectrum of types of learning spaces, from traditional classrooms to cyber cafes, each type able to facilitate different levels of collaboration and self-directed learning.

Learning Spaces (C/O lookred)

New types of learning spaces will facilitate a much wider spectrum of learning methods too:

Technology Enabled Learning Styles. C/O lookred

Where Is School?

“Anytime Anywhere Learning for All” means exactly that. Every citizen, anywhere, able to access organised learning.  Not everyone will need to, or be able to, attend school in order to receive schooling services, which poses the question “where is school?” In the transformed schooling model, schooling is embedded deeply into the local community in the following way.

Anytime Anywhere Learning for All

1. Community Learning Spaces

Community Learning Spaces are places in which formal, organised schooling takes place for school age learners, that are not within the walls of the traditional Campus School. These spaces are, in effect, “franchises” of the Campus School, and firmly embedded into the Campus School’s systems. Learners in Community Learning Spaces have managed internet access, and plug their personal learning devices straight into e-Learning Service. Even the youngest children can learn with ICT – e.g. games based learning, immersive environments, interactive whiteboards and programmable toys. Learning to write with a Tablet PC helps young children to acquire basic skills long before they can type or use a mouse.

Learners are registered as members of the Connected Learning Community and the process of data collection begins. Managed learning pathways and dynamic timetables ensure that students work on the tasks that are most appropriate for their stage of learning. A spectrum of creativity, productivity and learning tools ensure that the optimal blend of computer and teacher mediated learning takes place. The ICT infrastructure comprises wireless network, workstations, display, scanners. Infrastructure and Core Sofware Services mean that computers joining the wireless network are managed via a Virtual Private Network. Users and devices are authenticated, and policies – especially security and filtering policies – are imposed.

Teachers, assistants and other responsible adults – connected to peers and experts through the technology – directly support the learning process. Learners progress through the curriculum as quickly as their learning performance permits, and move to different learning spaces when appropriate. Staff and learners alike access the Connected Learning Community portal to get information, content and tools. Learners can see their assignments, feedback, learning materials and web links from a single site, and populate an e-portfolio with their work. Community Learning Spaces are extensions of
the Campus School, and both staff and learners will spend some time at there.

2. Campus School

The Campus School acts as a central point for organising, managing and creating Anytime Anywhere Learning in the community. The Campus School in effect “franchises” learning operations in Community Learning Spaces, so ICT is used to drive alignment; manage performance; and ensure high quality, paperless administrative processes. Live communications ensure that expertise within and beyond the Campus School can be “piped” into the Community Learning Spaces (CLS) on demand.

The IT Infrastructure of the CLSs are supplied as a service from the Campus School.

Learners – of all ages – visit the Campus School to use specialist facilities and IT equipment that are unavailable in the Community Learning Spaces. Whilst learners bring their personal learning devices into the campus, the site has a proliferation of multi-touch interactive displays and these enable learners to access a vast array of information and content from anywhere on the site.

In the Schooling Enterprise Architecture model, Campus Schools are branch sites from the Local Education Authority hubs and as such receive the full range of Schooling Enterprise Services for Student Relationship Management, intelligent intervention, performance management, planning, operations and administration.

A master database of resources – people, spaces, equipment and content – enables the Campus School to dynamically timetable learners so their precise learning needs can be met immediately. Predictive analysis of learning pathways enables the system to book or purchase resources well in advance.

Underpinning the IT infrastructure at the school and its “franchises” is a set of Core Software Services including Security, Identity, Comms & Collab, System Management and Directory services. Services are either delivered through on-premises servers or relayed from data centres, private and public clouds “upstream” at LEA and/or MoE levels.

3. Local Education Authority

As a Hub in the Schooling Enterprise Architecture, the Local Education Authority’s main role is to deliver Schooling Enterprise Services to Campus Schools. Their managerial functions, facilitated by ICT, are to drive accountability, alignment and performance.

Another key role is to run large scale access programmes. Using aggregated buying power and regional connections the LEA is in an ideal position to acquire devices, infrastructure components and support for the best price-to-quality ratio. As a Hub for the MoE, LEAs should be able to ‘enforce’ MoE mandates on standards, quality and Service Level Agreements.

The LEA can also be an aggregation point for data held on children by different authorities – health, social care, the police and education – to be aggregated to give a secure ‘big picture’ on children,
particularly those who may be at risk.

4. Workplace

Anytime anywhere learning for all means delivering learning experiences to all, including those in work. Online vocational courses are available through the Connected Learning Community portal. Workplaces offer valuable learning opportunities to learners of all ages, especially where specialised equipment is beyond the financial reach of the Campus School. The workplace can also be used to house Community Learning Spaces. Being part of the Connected Learning Community Portal; local businesses can have direct dialogue with – and receive relevant learning services from – their local Campus School, FE College and University to better meet the learning needs of their organisations.

5. University

Universities offer a rich extension to the Campus School learning community by offering online access to lectures, experts and learning resources. Within the Anytime anywhere learning model, Higher Education is made available to students who are ready to take learning modules offered by the University – virtually or otherwise.

6. Off-Site Learning Environments

With community-wide Wi-Fi coverage, homes, cyber cafés, hospitals, and recreation areas can all be turned into learning environments.

Personalised Learning

Transformed schooling organises the learning around the individual, not the other way around.

Learning, by definition, is personal—no one else can learn for you. People learn different things at different speeds and in different ways. When students walk into a learning space, they bring very different sets of attributes, abilities, knowledge, skills, understandings and attitudes with them.

Over recent years, the concept of personalising learning has gained considerable ground.

From a technical perspective, personalising learning is about:

  • Delivering an extended range of opportunities to learn – individually and collaboratively
  • Delivering content that addresses precise learning needs
  • Managing learning pathways

Extending Opportunities to Learn

The wider and deeper the choice of content, the more personalised the learning experience can be. When providing learning to an entire community, the type of learning experience consumed will range from informal learning to structured and accredited courses.

Extended Learning Opportunities for All

With a wide and deep supply of learning content, learners can have a wide choice of learning experiences, modalities, pathways and assessments. For example, being able to pick from a menu of languages to learn is a more personalised experience than just having one to choose from. To be able to choose what level to study a language at – from beginner to advanced – again adds to the degree of personalisation.

Personalised learning is not about learning in isolation, however.  It is quite the opposite in, fact.  Learning is a social activity and personalising the learning experience is to do with providing opportunities to collaborate as well as to learn independently. A learning task that has been personalised for somebody could involve them working in a team, and part of the assessment could be how well they have managed to collaborate with other people. Therefore, another technical requirement here is to provide Communication and Collaboration tools – the more sophisticated these tools, the
greater the possible degree of personalisation.

Addressing Precise Learning Needs

Learners learn in completely different ways, and at different rates depending on prior knowledge and their learning styles. Therefore personalised learning systems need to deliver content so that different learning styles are addressed and different learning speeds are catered for. For example, in learning about the skeleton of dinosaurs, one learner might learn best by listening to a recording, another through looking at pictures, another by using a Tablet PC to kinaesthetically piece together the bones with a stylus.

From a technical point this means that content needs to be packaged so that learners can access it through multiple learning modes. Increasingly there will be automated agents that scour the internet and deliver content that precisely matches learning needs.

The relative length of time that it takes a learner to acquire the expected learning in each module shouldn’t matter as the e-learning services will adjust the personal learning pathway that the learner takes accordingly.

Managing Personal Learning Pathways

The extent to which a learning task has been personalised is a function of the extent to which that individual’s prior knowledge, skills, preferred learning styles, and attitudes have been taken into account when assigning the task.

In this model, learners are constantly assessed as they move through the learning programme, and the pathways that they take continuously evolve as they work their way through. This relies on feedback loops and systems which can dynamically adapt to the twists and turns of the learning process, and set challenging learning goals and tasks. This is essentially about using “business logic” which in turn uses data to decide what students need to learn next and manage the learning process.

Setting the learning task automatically is something that intelligent tutoring systems and learning management systems such as “Success Maker” have been doing for many years. However, if completing the learning task needs more than just a computer, managing the process dynamically becomes complicated.

This is where dynamic timetabling comes in. Dynamic timetabling starts with the premise that learning should be organised on a ‘performance’ as opposed to a ‘time’ basis (see Schooling at the Speed of Thought for more details). The core idea is that dynamic timetabling matches the optimal learning experience for a learner to the resources needed to deliver it. For example, if the learner has  mastered the concept of soil erosion in Geography, the next task may be to apply that learning in a practical experiment. This involves working with others who are at the same learning stage, using equipment, a physical space and teacher/assistant supervision. Ideally, the dynamic timetabling system will have predicted when these resources will be needed, organised them ahead of schedule and matched the learner to what they need to complete the next task.

Dynamic Timetabling

Today, this can be at least partially accomplished through resource scheduling within CRM.

Once the learning task is completed, a record of achievement builds in the learner’s e-portfolio.

Culture of Performance

In the Transformed Phase the entire schooling system is working at optimum efficiency and effectiveness – what Joey Fitts and Bruno Aziza (Driving Business Performance, 2008) call a “Culture of Performance”. To get to this stage schooling systems will have gone through the following stages:

  • First Steps: Increasing visibility
  • Enhanced: Moving beyond gut feel, and planning for success
  • Strategic: Executing on strategy

A culture of performance is goal orientated; results are measured and members of the Connected Learning Community are competitive in a constructive way. A culture of performance is
about transparency, predictability, and the ability to adapt to changing conditions. With capabilities to monitor, analyse, and plan, performance orientated organisations can create a culture where information is a prized asset, aligned execution is the norm, and accountability is embedded.

From a learner’s perspective, this is about friction-free administration regarding courses, options and assessments. It’s about micro payments, and cashless vending, and not having to repeatedly enter the same basic data for silo’d administrative processes. It’s also about the seamless escalations of issues – such as requests for special support.

From a teacher’s perspective this is about doing the lowest possible levels of administrative tasks, confident in the knowledge that the system is dealing with the administrative mechanics of running the schooling operations. For those administrative tasks that teacher have to do, reporting, administration, productivity and communication & collaboration tools ensure that the tasks are efficiently executed and add real value to the organisation.

Administrators and managers get the benefit of using processes that have been integrated. For example, when new staff join the organisation, background checks, basic data collection, terms and conditions, salary and on-boarding systems all work together as a single function, crossing organisational boundaries automatically. When strategy is set at the highest organisational level, this cascades down automatically into the objective setting process, ensuring organisational alignment. Performance management tools linked to in-depth data about learner performance ensure that teaching staff are rewarded fairly. Business intelligence is available to provide deep insights into operations to ensure that resources are being used to maximum effect.

Bringing it All Together

The key difference between a transformed schooling system and any of the other phases is the degree to which the entire system is architected around the student.

Learner at the Centre

The Transformed schooling system will integrate a spectrum of services and processes, many which would have been in silos before the transformation process, around the student. The result of this is that the student experiences a range of highly individualised services, delivered by a high performance, highly connected, lean, efficient and cost effective schooling system.

Getting to Transformed schooling is a long journey. In most countries there will be significant inertia from legacy systems. Paradoxically, one of the drivers for transformation is diminishing budgets. In the United States, for example, there is a strong surge towards anytime anywhere, personalised learning for all – delivered from outside the formal schooling system, driven by collapsing schooling budgets and widespread dissatisfaction with the current system.

Ultimately, the point of investing in transforming a schooling system is to get an order-of-magnitude improvement in return on education budget investment, and this cannot be done in isolation. The whole enterprise of transforming schooling needs to be organised within the framework of a Schooling Enterprise Architecture, as described in detail in Schooling at the Speed of Thought.

Schooling Enterprise Architecture

Focusing on the “IT Platform Architecture”, the Transformed phase has 5 interconnected layers:

Tranformed phase - five layer Schooling Enterprise Technology Architecture

And finally, across each layer are the following key technology levers:

Schooling Enterprise Technical Concept Architecture - Transformation Phase

This is the last in this series of articles on the phases through which schooling systems evolve, but watch this space for related articles. All comments, feedback, questions and suggestions for articles will be very welcomed.

Thanks to Matthew Woodruff and Chris Poole from lookred for contributions to this article.

The “Strategic” Phase

This is the third in a series of articles that aim to help schooling systems develop their technology, the first being “Taking the First Steps“ and the second, Taking the Next Steps – The ‘Enhanced’ Phase.

There are four distinct phases through which technology in schooling evolves. The first phase is characterized by access. In the next phase, technology is used to enhance existing processes. The third phase is characterized by using technology strategically. No longer is technology considered a “bolt-on”, or “veneer” on top of existing processes – it now helps drive schooling towards strategic goals such as significantly improved learning and better return on investments. In the final phase, leading edge schools use ICT to transform their operations, using it to personalize learning, integrate deeply with the wider community, run extremely efficient administration systems and develop a culture of performance.

‘Strategic’ Phase Vision

In the Strategic phase, technology becomes a key asset in achieving the strategic goals of an organisation. It’s about restructuring work and processes and doing things differently.

Typically in this phase, the strategic goals of an organisation would include raising standards and improving performance, and technology is a strategic tool for achieving these strategic goals by enabling:

  • Intelligent intervention – data driven support for learners
  • Connected Learning Communities – fully exploiting all available resources, and integration with the local community
  • Monitoring, analysis and planning – data driven decision making
Four phases of ICT implementation

Goals

Intelligent Intervention

This is essentially about using data to make well informed decisions about what students need to learn or do next. To fully personalise the learning experience students should be constantly assessed as they move through their schooling, and their learning pathways should continuously evolve. This relies on highly effective feedback loops and systems which dynamically adapts to the twists and turns of the learning process, and sets challenging learning goals and tasks. This is extremely difficult to do within a paper-based setup, but can be made a lot easier through using IT systems that provide analytic and workflow capabilities.  Intelligent tutoring systems, and managed learning environments, are becoming more commonplace and increasingly sophisticated.

Monitoring, Analysis and Planning

To manage an organisation strategically, as opposed to fighting fires, the ability to monitor performance, analyse results and plan for improvements is fundamental. Organisations wanting to manage strategically must have three key capabilities:

Monitoring

This capability provides managers with the ability to know “what is happening” and “what has happened.” Organisations implement dashboards, scorecards, or reports to monitor their performance. These visual applications allow managers to keep an eye on important indicators of their organisation’s health.

Analysis

This capability provides managers with the ability to know what is happening and why. To analyse performance, organisations implement solutions that are often very interactive in nature and allow managers to investigate the root cause of issues they see in their dashboards, scorecards, or reports.

Planning

This capability provides the organisation with the ability to model what should happen. Organisations develop processes and tools to conduct the essential planning, budgeting, and forecasting exercises. These processes allow managers to align groups and individuals around the metrics that drive the organisation—for instance: “what are our examination result targets?” or “what is our spending versus our revenue?”

Connected Learning Communities

Whilst there may be elements of learning that require independent work, learning only really acquires meaning in a social context, and the most immediate and direct social context for schooling is the local community.

ICT can be used to connect together all those who can make a contribution to students’ learning – e.g. local business, community resources (e.g. museums/libraries), parents and 3rd party learning services. It can connect students to inspiring individuals and inspirational speakers; promote debate and engagement between collaborators in face-to-face or virtual groupings; and provide mentoring opportunities. Connecting stakeholders together in a Connected Learning Community has enormous benefits such as engaging parents more deeply in the learning process, speeding-up processes and improving students’ connections with the outside world. The core of a connected learning community is a portal that can be accessed from anywhere.

Scenarios

Student Access

In the Strategic phase, students have continual access to their own learning devices. These devices need to enable a range of learning scenarios (not just content consumption), be rugged, easy to repair and support, manageable on a network.

Devices should be available to students so they can learn anytime anywhere, access content, learning management and communication and collaboration tools via the Connected Learning Community Portal.

Anytime Anywhere Learning = access to devices + learning services

Having access to their own devices enables students to experience a wide range of learning scenarios:

ICT enables a wide range of learning styles

Classroom

Classrooms need to accommodate an increasingly wide range of learning styles, and equipment needs to be laid out in quite different ways according to the demands of each different learning task, for example:

Different learning tasks require different floorplans

BECTA provided the following guidance to UK schools on different classroom layout options:

Pods – separate circular / hexagonal / octagonal benches with workstations
Hexagonal pods
Advantages
  • No corners with 2 computers, so no dead spots that cannot be used
  • No extra space required for 2 pupils to share a computer
  • Can support collaborative work as users working around ‘one pod’
Pods – squares with computers on two sides only
Square pods
Advantages
  • No corners with 2 computers, so no ‘dead spots’ that cannot be used
  • No extra space required for 2 pupils to share a computer
  • Can support collaborative work as users working around ‘one pod’
Bays built along walls
Bays
Advantages
  • Teacher can more or less see all computer screens from the centre of the room
  • Provides opportunity to use the centre of the room for tables enabling work away from the computer, and to gather groups for discussion
  • Cabling and electrical work is cheaper and easier than ‘pod’ designs as along the room edge.

School

In the Strategic phase, IT has become a strategic asset to schools. With the infrastructure optimised in the Enhanced phase, we now turn our focus on workloads delivered by servers.

The following services are core in the Strategic phase:

  • Optimised Infrastructure – including File and Print, Database Services, Directory Services, Security, Device Management, and Data Protection and Recovery
  • MIS – Management Information Systems
  • Portal
  • Unified Communication
  • Virtualisation – centralizing computing tasks to improve scalability and system performance

These, typically, will be delivered through three layers:

  • On-Premises – the school hosts key functions on their own servers
  • Data Centre/Private Cloud – the Local Education Authority (LEA) delivers services to schools from their servers
  • Public Cloud – the school receives services from the LEA, Ministry of Education and private suppliers from Public Cloud Services
School Server Infrastructure

Portal

The Strategic phase is characterised by the Connected Learning Community, the core of which is a portal that can be accessed from anywhere. For it to be effective it needs to be “role based” i.e. present users with information and tools relevant to their role and to them as individuals. In other words a teacher in the community sees the information relevant to all teachers, their fellow subject specialists, and also information specific to their particular group of students, their particular HR information, and their particular teaching content, tasks, calendar, e-mail etc.

A portal should give students, parents, managers, teachers, their own “spaces” and deliver to them the resources that are important individually to them through a single web page.  It aggregates information from diverse systems into one interface with a single sign-on ID – and organisation-wide search capabilities so that users can access relevant information quickly.  Teaching and administration staff can use the portal to distribute information to students based on their enrolment, classes, security group or other membership criteria, while enabling them to personalise the portal content and customise the layout to suit their needs.

A great Portal reference architecture is Twynham School. Twynham is a 1600+ Secondary school in Christchurch UK, built  a powerful collaboration platform – “Learning Gateway” – which allows students, staff and parents to work efficiently; develop independent and inter-dependence in their learning strategies; and support children in achieving their full potential. Twynham School won the BECTA ICT Excellence Award in 2008 for learning Beyond the Classroom and the schools works with over 400 schools internationally to support the development of their Learning Platforms.

Twynham School Portal Navigation bar

Mike Herrity at Twynham has published a detailed e-book explaining how the Learning Gateway is used: http://bit.ly/qJohiL

Microsoft have also published a full architectural guide explaining how Twynham built their Learning Gateway – http://bit.ly/qORAW5

Enabling many of the functions in the portal are 2 sub-systems – Content Management and Unified Communications & Collaboration.

Content Management Systems (CMS)

When ICT is fully implemented, vast amounts of content gets created.  In order to get maximum efficiencies from ICT, this content needs to be organised and managed in a way that means that people don’t replicate one another’s work.

A content management system in a connected learning community helps education institutions organise and facilitate the collaborative creation of documents and other content. They enable the full life cycle of content – from initial creation to delivery to end users.  CMS comprise document and records management, web content management, forms, search, library systems, curriculum frameworks, curriculum systems, curriculum exemplars and resource assemblers.

Unified Communications (UC) & Collaboration

Today it is typical that people will have multiple contact addresses – direct line phone number; mobile phone number;  e-mail; Instant Messenger; home number; personal mobile number; home e-mail, etc. Unified Communications (UC) takes identity and presence and then has all of these other ways of interacting simply connect up to that.

A single integrated identity can simplify how you find and communicate with others.  One integrated desktop application can provide easy access to all the ways users are likely to want to communicate.  Another key advantage to UC is that in using Voice over IP (VOIP) for telephone calls, it has the potential to significantly reduce communication costs.

UC enables students, teachers, parents and other stakeholders to confer and consult in the way that suits their work style by switching seamlessly between videoconferencing, telephone, email and instant messaging.

Also within UC are task and calendaring functions.

Data Driven Decision Making

In a schooling system, data driven decision making is supported by a huge number of information systems.  Any process that involves the creation and transmission of information can be considered an information system – even informal discussions.

The collective term for the information systems in schooling is Management Information Systems (MIS).

Functions Supported by an MIS

The functions that a Management Information System need to support are:

Improving Student Performance Progression Management
Learning Management Intelligent Intervention
Parents Engagement In Learning Better Teaching Decisions
Make Better Management Decisions Monitor, Analyse and Plan
Tactical Decision Making Data Visualisation
Manage Resources More Effectively Planning and budgeting
Financial Control Asset Control
Reporting Accountability and Alignment
Performance and Assessment Data KPIs, Scorecards, Dashboards and Reports
Key Performance Indicators (KPIs) Drive Administrative Efficiencies
Planning Organising
Controlling Co-ordinating
Management Information Systems – Functional Architecture

In this context, an information system really means an organised hierarchy of information sub-systems. Management Information System (MIS) is a term used as a container for all of the electronic information systems within a schooling system.  These systems vary in size, scope and capability, from packages that are implemented in relatively small organisations to cover student records alone, to enterprise-wide solutions that aim to cover most aspects of running large multi-site organisations.

A MIS includes the following sub-systems:

  • Decision Support Systems (DSS)
    • Finance
    • Performance Management
    • HR
    • Student Relationship Management (SRM)
    • Enterprise Resource Planning (ERP)
    • Analytics and Business Intelligence (BI)
    • Timetabling
  • Student Information Systems (SIS)
    • Integrated Student Record
    • Electronic grade book
    • Attendance Management
    • Automated workflows
    • E-Forms
  • Learning Platform
    • Learning Management Systems (LMS)
    • Managed Learning Environment (MLE)
    • Virtual Learning Environments (VLE)
    • Content Management Systems (CMS)

For a full description, see Schooling at the Speed of Thought, Chapter 6, Managing Information.

Local Education Authority

In the Strategic Phase, the goal of service provision at Local Education Authority level is to deliver those services which when aggregated improve in quality and price.

Local Education Authorities can use their scale to negotiate the best prices for content, communication, support services etc. Many of the services requiring the most maintenance and management – e.g. learning services, system management, business intelligence, and administrative tasks such as payroll and HR, are delivered more cost effectively from a centralised point.  Other benefits include the use of greater amounts of data for decision making – an LEA with data from many schools can perceive more patterns than a single school with its limited pool of data.

Many LEA services are delivered through data centres built on top of optimised infrastructures. Increasingly data centres will become Private Clouds – essentially Infrastructure as a Service (IaaS) within the data centre. The large scale and pay-as-you-go economics of Public Clouds aren’t available in typical Private Clouds. However, Private Clouds offer at least some of the scalability and elasticity benefits of Public Cloud but with additional control and customisation. Increasingly many of these services will be also be delivered from Public Clouds.

The services delivered by the LEA can be split into two main categories:

  • Schooling Enterprise Services
    • Monitoring, Analysis and Planning
    • Intelligent Intervention
    • Student Relationship Management
    • Administrative Processes
    • Operations
  • E-Learning Services
Local Education Authority Schooling Enterprise Architecture (SEA)

Ministry of Education

Some of the Schooling Enterprise Services delivered by LEAs to their schools and communities could be provided at National level from the Central Ministry of Education. Services such as strategy, policy, budgets, and curriculum are usually set and delegated at national level.

Computing functions at Ministry of Education level can be grouped into three main categories:

  • Internal departments – Curriculum, Policy, Research etc.
  • Regional Services – Resources and BI
  • National Services – Content (information services) and infrastructure – e.g. national level schooling enterprise internet backbone
Ministry of Education perspective

One of the most important functions at Ministry level is to have a “clear line of sight” of the performance of the schooling system. This enables BI analysis and for resources to then be focussed on the areas where they will have most impact.

Fitts and Aziza (Joey Fitts and Bruno Aziza, 2008) talk of a “line of sight” from strategic to operational to tactical decisions as the discipline that drives aligned execution. “Line of sight” means clear visibility of goals, and progress towards them at executive (strategic), management (operational), employees (tactical) levels.

“Clear line of sight” is about performance metric alignment across organisational layers. This can be thought of as an organisation chart for performance metrics, indicating how the various levels of the organisation’s performance metrics relate to one another. At school level, classroom teacher’s metrics roll up to their Head of Department, which in turn roll up to Deputy Principals, which in turn roll up to the Principal. In turn, and depending on the mode of operations, performance metrics for Principals should roll up to those of Local Authority Directors, which in turn finally roll up to the Ministry of Education.

Clear Line of Sight enables strategic allignment

Technology Building Blocks

Finally, pulling these building blocks together we get the following high level architecture:

Technology Building Blocks for Strategic Phase

Conclusion

Moving from the Enhanced Phase to the Strategic Phase is as much about management as ICT. In this phase, the technology is used a tool for getting better allignement between strategy set at MoE level to exectution at school level. At all levels, there are strategic decisions that ICT can help monitor, analyse, plan and execute.

In the next article in this series, we will explore the final phase – Transformation.

Taking the Next Steps – the “Enhanced” Phase

This is the second in a series of articles that aim to help schooling systems develop their technology, the first being “Taking the First Steps“.

There are four distinct phases through which technology in schooling evolves. The first phase is characterized by access. In this phase, giving students and teachers access to computers to improve some aspects of lesson delivery and administration is the main focus. In the next phase, technology is used to enhance existing processes. It’s about providing content and tools to increase learning, organising communications and starting to manage data and information. The third phase is characterized by using technology strategically. No longer is technology considered a “bolt-on”, or “veneer” on top of existing processes – it now helps drive schooling towards strategic goals such as significantly improved learning and better return on investments. In the final phase, leading edge schools use ICT to transform their operations, using it to personalize learning, integrate deeply with the wider community, run extremely efficient administration systems and develop a culture of performance.

Four phases of ICT development in schooling

The “Enhanced” Phase

Goals

The goals of the Enhance Phase of ICT development are to:

  • Increase learning
  • Improve communications with parents
  • Manage data and information

Increasing Learning

In this phase, computers are available in several areas of the school, some in labs, and others scattered in classrooms and other learning spaces. These computers are connected together in a network and key resources, such as content, printers, scanners, and users are managed centrally.

Students use computers as a learning tool – e.g., using multimedia learning packages; solving maths problems; researching; reading from e-books; developing writing skills; learning languages; and developing 21st Century skills.

Curriculum Area Examples

Language
Hyperlinks allow more creativity in narrative construction
  • Word structure and spelling
    • A great example of how to help children remember how to spell individual words is the “Look Cover Write and Check” web application on the Ambleside School site   
  • Composing and presenting
  • Learning foreign languages
    • Bilingual audio books combine rich graphics with spoken word for foreign language learning. Award winning Mantra Lingua have combined traditional print media with a “talking pen”.    
Mathematics
Making visualisations easy in Mathematics
  • Learning from feedback
    • Word processing software now enables students to “word process” maths to clearly show complex formulae, along with 2d and 3d graphs, making it easier to communicate their thinking and get feedback on it. Check out the free Math add-in for Word and OneNote.
  • Creating patterns
    • Students can use Logo software to draw patterns students quickly learn the importance of expressing their commands unambiguously and in the correct order
  •  Seeing connections
    • A software Graphing Calculator can be a great tool for teaching maths when used with a data projector for whole class teaching, or better still when given to students to use.  A lesson can be built up and stored then each stage “replayed”. Check out the free Microsoft Math 4.0 
  • Exploring data
    • Students can design surveys, such as the heights of their peers and teachers, and enter the data into a spreadsheet to learn about averages and correlations.
Science
 
  • Assisting observation
    • Electronic telescopes enable pupils to collect images from different locations on Earth and at different times of the day. Telescope sites also provide learning resources and galleries of images.  
  • Recording and measuring
    • USB microscopes and data loggers can be used in the classroom to observe, record results, plot graphs and analyse data. E.g. see this data logging programme from Kent which explores topics such as: most effective sunglasses; which surface will slow down the car? Who has the hottest hands; where is the noisiest place in school?
  • Providing models or demonstrations
    • Simulating experiments can enable students to experiment with phenomena that may be too slow, too fast, too dangerous or too expensive to experience in school. Check out Crocodile Clips’ Yenka for example.

An essential consideration is accessibility for all. For students with some disabilities, technology can open up new windows of learning opportunities. For a full explanation go to: http://edutechassociates.net/2011/03/08/accessibility/

A fantastic resource exploring different ways in which ICT can be used across the curriculum can be found here: http://archive.naace.co.uk/direct2u/indexbysubject.html

Additionally, worksheets with practical examples and screenshots explaining how to use ICT in Primary Schools are available here

Other resources developed for classroom use by teachers, for teachers can be found in the Teachers Toolbox and here.   

Managing Learning Content

When ICT is implemented, lots of content gets created.  In order to get maximum efficiencies from ICT, this content needs to be organised and managed in a way that means that people don’t replicate one another’s work.

At school level, content can be managed through a file sharing system on a server on a network. For example, Windows Server 2008 enables files to be centrally shared and managed. The “Shared Folders” feature enables file-shares to be created and permissions set, which will allow students and teachers to store their work.

At a more advanced level, content can be better managed using a portal such as SharePoint Server 2010. Combining content management with collaboration tools and powerful search, SharePoint makes information easy to find, share, and use.

Beyond the school, regions or even whole countries are beginning to provide organised learning content, as explored in the articles on SULINET and managing learning content.

In Brazil, for example, Educopedia is a learning content portal run by the City of Rio. Users are presented with a list of all of the elementary and middle school grades and under each of these they can access all the school curricula for each discipline.

Educopedia - learning content access made easy

For example, a teacher can click on a subject area link, and see a content index consisting of the school year course plan which contains the lessons and related curriculum standards.

Educopedia - making it easy to select resources related to curriculum standards

From there, they can download lesson plans with suggestions on how to make the best use of the resource materials available; a list of the skills and competences addressed; a PowerPoint presentation for classroom use; and a quiz with questions about the class content.

Educopedia - access to learning tools made easy

Educopedia also provides users with communication and collaboration functions through live@edu, which provides a mechanism for user authentication.

Parent Connection

The usual way in which schools communicate directly with parents is via “parent evenings” – many parents end up seeing a teacher once or twice a year for 5 minutes. Hardly enough time to say “hello” and “goodbye”. 

Research demonstrates that active parental involvement in educational activities delivers a positive impact on attainment. Technology can be used to connect parents with information regarding the educational progress of their child, and a range of supplemental activities in which the parent can support the learning process. For example, ICT can be used to:

  • Enable parents and teachers to communicate more frequently with each other
  • Identify problems and issues at an early stage and involve parents in rectifying them
  • Give parents the tools to support learning activities at home
  • Provide parents with immediate news about the school and its activities.

At a basic level, ICT can contribute:

  • E-mail news bulletins
  • Digital learning resources to assist the student with homework
  • Educational resources for parents, such as behavioural management guidance
  • Alerts on critical issues such as lack of attendance, dropping attainment levels, behavioural issues, etc
Miami Dade - enabling parents to see how their children are progressing and help with work at home
Miami Dade - essential information about children's school day made easily accessible
Managing Data and Information

Teacher Administrative Tasks

ICT can really help with reducing the time spent on teacher’s basic administrative tasks including:

  • Lesson plans and materials
  • Producing class lists
  • Keeping and filing records
  • Analyses of attendance and results
  • Writing reports
  • Ordering supplies and equipment.
  • Producing formal minutes of meetings
  • Submitting bids 

In Latvia, the Ministry of Education were able to achieve time savings of 30% by deploying SharePoint Server across 100 schools. This allowed them to automate routine grading tasks and reporting, delivering significant time savings for teachers. 

For a report on how ICT helped UK teachers reduce administrative burdens, click here.

Managing Baseline Administrative Data and Information

Whilst different countries have different mandatory requirements for essential data that they expect schools provide, UNESCO (2003) has set out a recommended specification of essential data to collect at the national level from each education establishment.

Data on students Data on teachers and other categories of personnel
Distribution by grade, gender and age Distribution of teachers by level of qualification and certification, by grade and by gender
Distribution of repeaters by gender and grade Distribution of teachers by age and by gender
Number of learners attending double-shift classes by grade. Number of teachers working double shifts
Data on education establishments Number of teachers in multi-grade classes
Number of classrooms Number of non-teaching personnel by categories, age and gender.
Places available in schools Distribution of teachers by level of qualification and certification, by grade and by gender
Education expenditures Distribution of teachers by age and by gender
The budget as part of the overall State budget (budget voted and budget disbursed) broken down by level Number of teachers working double shifts
The expenditures at the local level, of private organizations by level Number of teachers in multi-grade classes

Student Information Systems (SIS)

Schools need to keep records on their students which should, at the very least, include: 

  • Personal – name; address; photo; family contacts
  • Performance – actual and predicted grades; teachers comments
  • Attendance – by day, by lesson, over time
  • Risk profile – learning, social, medical and demographic
  • Intervention history – what assistance and guidance has been given to the student
  • Timetable

Scenarios

Student Access

Providing students with their own laptops for use at home has proven learning impact

A study by the UK Institute of Fiscal Studies in 2009, shows that “learners who use a computer at home for schoolwork could get as much as ½ a grade to their General Certificate of Secondary Education (GCSE) examination results and as much as a term on to their GCSE learning”. No surprise then to see the explosion of national level projects for the wide-scale introduction of ‘personal learning devices’. However, many of these schemes wrongly focus on a ‘blanket’ approach of providing huge numbers of cheap portable PC’s. Unfortunately most of these projects have been driven by getting the most computers for the lowest price, rather than focusing on getting the right device for the learning that needs to be done.

To get the best return on investment a device for students should have the following features:

  • Provide a platform for use of the widest range of productivity, creativity, and communication and collaboration tools
  • Result in users acquiring relevant knowledge and employability skills  
  • Have a display of around 13 to 15 inches
  • Have software that makes learning accessible to all, including those with disabilities
  • Capable of being managed remotely and as part of a managed network
  • Sharable with other users  
  • Battery life should exceed 3 hours under full CPU load with full screen brightness
  • Appropriate ports to allow them to connect to other equipment
  • ·Wireless networking capability
  • Be self-contained and work without needing high levels of internet access once set up
  • Protected from viruses, spyware, and other malicious software
  • Hard Drive encryption for security

One of the advantages of giving students a PC – as opposed to lower specification devices – is that they can share them with family and friends, amplifying the effects of the investment. For example, Mouse Mischief enables students to share applications extending the use of the device.

Classroom

Ideally, students will be able to bring their laptops into the school and make use of them within a managed network, but this takes time, so a more likely scenario in the Enhanced phase is that students use shared computer resources at school. In this phase, there is likely to be an ICT suite with enough computers to take at least 30 children sharing a computer in pairs. Computers will also be found in other learning spaces in the school to support the kind of learning scenarios mentioned above. The computers that were originally used in the school can now be distributed throughout the school, some of which can be used as Thin Clients networked to the Server and/or Windows Multipoint Server.

Of course, computers aren’t the only hardware devices used in the classroom. Digital cameras; video cameras; voting devices; interactive whiteboard tools; robotic kits; digital microscopes; and projectors all have a role to play in the learning process in the Enhanced phase.

School

With ICT across the school, there is need for an organised network to manage ICT services. Learning content, devices, peripherals, access, administrative processes and users. Connecting with a local authority, state or national level learning content service is crucial, and this has to take place within a secured environment. The school will also need to connect to secure Local Authority services within a Wide Area Network.

An important question in this phase is how to manage e-mail. This can be done “on-premises” using server software such as Exchange Server; as a ‘rented’ service such as Exchange Online; or as a free “commodity” type service such as Office 365 for Education. The answer depends on the amount of resource available to manage the service, and the degree of control that a school wants to have over e-mail policy. Increasingly email – along with services such as calendaring and personal file storage – are commodity services that institutions are happy to see moving into the Cloud.

School managed network conceptual design

For a useful document from BECTA that sets out key considerations for school ICT network design, click here.

 Another useful document that considers the full range of devices that a school in the Enhanced phase could use is the Computer Sustainability Toolkit.

Local Authority – MoE

With a system in place for collecting baseline administrative data, there now needs to be a continuous flow of information between schools, the Local Authority and Ministry of Education with budget allocations flowing downwards and reporting on performance flowing upwards. This has to be achieved through a Wide Area Network to ensure the secure transfer of data. Several technologies are available for this including “Leased Line”, “Circuit Switching”, “Packet Switching” and “Virtual Private Networks”.

Wide Area Network between school and "upstream" authorities

As we saw above, the Local Education Authority of Rio City also provides learning content and collaboration services to schools. These can be delivered as a web service from a data centre.

Technical Requirements

The foundation on which the entire schooling architecture is built is called “Optimised Infrastructure”. This provides a scalable, secure platform which can be built on to provide a growing number of services.

Key capabilities of an Optimised Infrastructure are:

Security

The key component without which none of this will work is stringent security and networking protocols. This is needed to protect students and employees from unauthorised users, viruses and unsuitable content. Security systems should automatically identify threats and respond automatically.

Local Area Network (LAN)

Computers need to be connected to a LAN – wired and/or wireless – with a server that controls the network, stores files and enables printing. A classroom might have just a few computers that all the students take turns using, so it’s important that an educational computer be configured just the way the teacher wants.  The teacher shouldn’t have to waste valuable teaching time troubleshooting.  Each PC in a LAN needs to be “locked down” and reset easily. 

Data Protection and Recovery

As ICT becomes increasingly “mission critical”, it’s important to manage data so it can be rapidly recovered.  When infrastructure is fully optimised, recovering information should be as simple as browsing the network. Backup devices are now very cheap to buy and manage, and will automatically run in the background.

Identity and Access management

Identity and Access Management can help organisations centrally manage user information and access rights. It allows administrators to manage each student, teacher, administrator individually by setting their role, access and functional level.  This enables individual users to have information and software tools that are specific to their individual requirements – a personalised IT service.  A directory service holds each user account and its access functions and allows the user to access various systems using the same set of credentials. Authentication can be by various mechanisms such as logon credentials, smartcards, and biometrics.

Desktop, Server and Device management

In an optimised infrastructure, those responsible for the management of networks have the tools to control their IT infrastructure; easing operations; reducing troubleshooting time; controlling quota; password re-setting; provisioning users; improving planning capabilities; and managing mobile devices.   

Integration and Interoperability

A key goal of optimising infrastructure is to integrate different systems so they can exchange data. The advantage of this is that data only has to be inputted once, and then used by multiple systems saving time and money.  Ideally data in Student Information Systems, Teacher Administration and Accounting Packages will interoperate, saving teachers and administration staff from having to re-key in data every time they wanted to update records or produce reports. 

Database Services

Databases are the “engines” of information management. They are used to capture, store, analyse and interpret a wide variety of information, and deliver this information to a range of different applications and devices including servers, desktops and mobile systems. Data includes text, numbers, pictures, video streams, audio content, and geo-spatial information. Not only do databases store data but they interpret, index and enable it to be searched.  

Technical Support

Schooling system networks need to be reliable to encourage user confidence and to support learning and teaching, as well as school management and administration.  This requires access to technical support, which can come from technicians within the school, or from another provider, or sometimes from students themselves. In an optimised infrastructure, schooling systems need to move away from a reactive system in which incidents are dealt with only as they arise. Instead they need to create a more pro-active system where technical support prevents problems occurring and ensures that individual ICT systems are robust and reliable and available when required.

Architecture

Bringing all this together the overall architectural model for a school in the “Enhanced” phase looks like this:  

Schooling Technical Architecture - essential building blocks

Conclusion

It’s often harder to take the second step than the first. Indeed, moving from PCs in a single location to an integrated and managed network has many challenges. The advantages well outweigh the challenges because by developing the school’s technology in this way, students gain access to a wider range of learning opportunities, develop more skills and knowledge. Teachers can use ICT to engage better with students and their parents, and school administration can improve enabling more effective use of resources.

In the next article in this series, we will explore the next phase – moving from using ICT to enhance existing operations to using ICT to drive strategic change.   

Taking the First Steps

Year-on-year $64bn is spent on ICT for schooling, but many schools around the world have yet to take their first steps to introducing ICT. Whilst the most advanced schools in the world can take full advantage of ICT, large tracts of the planet still don’t have grid electricity.

Figure 1. Huge areas of the world have no electricity, leave alone Internet and ICT

In 2007, the number of people with PCs passed the one billion mark – still a relatively small portion of the overall world population. The digital divide is still a defining characteristic of our age, and introducing ICT into schools is one way that governments are attempting to tackle this.

When technology is first introduced into schools, it tends to be used to supplement existing operations and processes. Schools begin to see the potential for ICT but operate in a typical “factory” approach with most learning, teaching and operational activities based on paper and students “receiving” their learning from their teachers. Typically it starts with teachers using a single computer with a projector, merely enhancing traditional teaching methods. The focus of computer use is to develop basic skills and students take turns to use the computers in computer labs.

Figure 2. Throughout the world, “computer labs” are considered an important first step

Challenges

Whilst OLPC was commendable for a number of reasons, the programme has proved that there is a lot more to introducing ICT into schools than simply “dumping” large numbers of laptops into the system. A recent study highlighted the kinds of challenges that need to be addressed in order to take full advantage of ICT in challenging areas.

“What happens when a school located 40km from the nearest town is suddenly burdened with the impossible task of providing power to 300 OLPC laptops?”. One school visited on the study, had only one low-voltage outlet located in the principal’s office… Many off-the-grid schools will not have Internet access either”.

A large scale ICT roll-out assumes high quality administrative processes, but this isn’t always available either – many countries still don’t keep central records of what schools are where, or how many students attended which schools. In some schools, teachers are even held personally responsible for any losses or damages, leading to lack of deployment. Finding trained technicians, familiar with local infrastructure and technology who can install and maintain ICT is often difficult too.

After a deployment of nearly half a million laptops to Peru’s poorest schoolchildren, most children didn’t even bring the devices home. In Peru’s roll-out, children were held responsible for reimbursing the school for any damages, many of which could easily occur during long treks or drives in mountainous terrain. Parents of these children soon asked their children to use the laptops as little as possible, rather than risking losing an entire year’s salary paying for broken devices. Another problem in Peru was lack of literacy. “A large majority of the kids have no idea where keys are located and sometimes don’t even know the letters.” For ICT to be useful, software and keyboards need to be in the local native language.

According to the same study, “the vast majority of teachers only care about one program: PowerPoint. Without training and incentives, the use laptops in the classroom just reinforce old techniques”.

Figure 3. Often ICT introduction will just enhance old techniques

Schools often deploy their first computing equipment for up to 10 years. This means that multiple generations of software need to run on single instances of hardware deployments. Computer technology must therefore be able to handle old content as well as new content – including curriculum materials, multimedia content, as well learning software titles.  Running all that content on a PC is a key challenge. Combine these issues with the various support challenges associated with ageing PC hardware and the result is an environment where the challenges seem to outweigh the benefits.

Schools taking the first steps towards ICT usgage tend to be price sensitive and because of this, cheap devices are widespread and common, e.g. refurbished computers >5 years old. In some cases low cost hardware designed specifically for schooling use processors and other key components that are roughly 5 years behind a new mid-range device.

Power, internet, and air quality are all factors in the deployment of technology solutions into schools. PCs and devices have to ‘just work’ in the face of highly variable power sources – often going down for hours and then spiking up to 10X the voltage levels upon resumption. In addition, internet connectivity to schools may be non-existent or at best highly variable – maybe Dial-up speeds, and only for certain hours a day, week, or month. In addition, internet connectivity could arrive in a non-uniform way such as over a satellite downlink, a DVD update, or an offline cache of static internet content. Air quality can be highly variable also, which in computing terms means there might be significant dust, sand, salt, and moisture build up which can affect a device’s longevity if not properly designed for.

Technical Requirements

Technology for schooling in challenging environments needs to have two key characteristics:

  • Resiliency. Uninterruptable power supply and surge protection are good places to start. At the beginning of a school day all the computers in the school need to start from a last known good state. When a problem arises, logical choices and low-risk options need to be presented to the user.
  • Adaptability. A key requirement is that when the school wants to connect a new client device it should easily detect it on the school network and provide the client with access to all appropriate network services (file storage, printer access, Internet access, etc.). When a school wants to connect an LCD projector, the appliance should recognize and pre-configure this device so that it is truly plug-and-play without the user having to know what resolution it should be set at or the make or model number.  If a school has a lab with ageing PC hardware and software the option to turn that PC into a thin client will help to extend the value of the school’s existing investment and limit exposure to future technical frustrations of dealing with older configurations. As new form factors emerge, it should be easy for them to be assimilated into the school network.

Students need straightforward user experiences such as easy storage and access of their files, and straightforward ways to log-in and store and retrieve their work. Even at the most basic levels, students like to personalise their PC experience to create a greater sense of ownership.

Teachers are focused on achieving a teaching objective and have little time for experiment and discovery. They need tools that require little training to understand and use, and resilient devices that when support is required it can be applied with “one-click” – e.g. easy restore, reset student PC, etc.

ICT decision makers at municipality, state or country level will want to be able to show an impact on learning outcomes – ideally during their term in office – from their investments in ICT. They will want to be able to increase economic opportunity by increasing academic achievement, building ICT skills and enabling access to online information to “bridge the digital divide”. Total cost of ownership will be a key factor in making these decisions.

Adoption of technology will not happen at scale anywhere without local suppliers, system builders, system integrators (SIs) and independent software vendors (ISVs). In rural towns and villages, these are likely to be “small shops” and may be responsible for a full 360 degree service – deploying, training and supporting the school. Suppliers need systems that don’t require extensive additional training to sell, customise and deploy. Flexibility for what devices can connect to network allows local system builders to offer “system + devices” packages.

Scenarios

Kiosk

In 1999, Sugata Mitra installed a computer connected to the Internet in a wall in a slum area in India and found that children below age 13 learned to use and surf the Internet without even knowing English. They taught themselves to use the mouse, learned many games and programs like Microsoft Paint, searched Hindi Web sites, and even removed viruses from files. Many were completely illiterate and could not understand word patterns or pronunciation; others had reading problems and low test scores in schools. Nevertheless, they could “read” the names of applications and explain their functions, even when their position on the screen was changed. They also learned many English words heard from the computer’s speakers. Children found solutions in groups and taught each other.

This kind of computer needs to be in a safe public place that the children associate with safety, free time, and play. Children in the “Hole in the Wall” project self-organise their learning. They develop computer literacy, Maths and English skills, improve their social values and get better at collaborating.

These results are replicable in many different parts of the world where “Hole in the Wall” experiments have been carried out, and “learning stations” can be provided in countries like India at an all-in cost of around $0.03 per child per day.

Another study conducted in low-income and rural areas of India found that students who had free computer access at public kiosks performed better on science and math tests than students without such access – Inamdar, P. and Kulkarni, A. (2007).

Mobile Classrooms

In rural areas from Cyprus to Tunisia to India and even in the United States, busses and vans are frequently used to provide mobile ICT classroom facilities. For example, The Commonwealth Youth Programme Technology Empowerment Centre on Wheels (CYPTEC) enables students in villages in India to acquire ICT skills and become more employable. CYTPEC uses a van fitted with several desktop computers, mobile internet, and sound systems – all powered by a generator.

A typical mobile classroom will be equipped with the around 10 workstations, appropriate furniture, a server, physical and virtual security, broadband satellite/Wi-Fi/3G, audio-visual, videoconference equipment and off-grid power generation – and ensure that people with disabilities can use the facilities.

In a particularly innovative solution, the time used to take children back-and-fore to school in busses is used for learning. In rural Arkansas school buses shuttle some students for over two hours a day, so Hector School District has teamed up with Vanderbilt University to make the buses into “mobile classrooms”. One school bus has received mounted television screens that show math and science programs to students. Seats are equipped with headphones for the children to use.

A few years ago, literacy rates in the Western Cape in South Africa needed boosting. The Western Cape has 2000 schools, almost all of which are difficult to get to and many have no electricity. There are few teachers so teaching children to read and write is extremely difficult. The solution here is a mobile unit, a 4 wheel drive and a teacher trained to take children/adults through an intensive reading programme using voice recognition and basic literacy software on the laptops.

First School PCs

 

A good starting point for permanent ICT facilities in schools is a single PC in a shared space with a projector, screen and printer. A first step towards teachers exploiting the power of technology includes activities such as using a PC and printer to produce worksheets, and using the PC and a data projector to present learning content. Having soft copies of documents means that teachers are easily able to save and reuse resources, thereby saving time. In this model teachers have educational tools with immediate value, and this provides a foundation to grow the value of ICT investments. This scenario enables teacher-led activities using multimedia and educational content via an LCD projector where students are recipients of content (simulations, video clips, ppts, DVDs, etc.). Content can be delivered with or without access to the Internet through media-stored and cached Web-content.

Sharing applications is a good way to get maximum value from PCs. Using Mouse Mischief, approximately 5-25 students, each with his or her own mouse, can answer multiple choice questions or draw on a shared screen. Sample lessons can be found here.

In the first stages of implementing computers in schools, it’s critical that at least one computer is put to administrative use. This should be used for student and teacher records, funding, staff pay, course records, equipment inventory and operational purposes. Teacher’s time can be better used when replacing paper-based methods with electronic communication. Tasks such as basic record keeping, issuing standard letters and communications, and timetabling all become a lot easier when using ICT.

Computer Lab

 

Typically, a first step to providing classes of students with access will start with a “lab”. Decisions need to be made about arranging worktables, for example, U or L shapes allow group interaction. An “island” arrangement with two PCs on each side of a table works well and encourages students to share information. Students will typically use computers primarily for research – web, cached content, DVD – and productivity (e.g. word processing and spreadsheets). Computer labs need a server to enable:

  • File/print/back-up/restore
  • Teacher-driven classroom management & orchestration of client PCs
  • Labs to easily grow/upgrade with a range of different kinds of clients
  • Access to learning content

Making the computers available to the wider community when not being used by students has many benefits. A local pool of skills, knowledge and interest in ICT can be developed, and small charges for training can be made, helping to meet costs. To deliver this service to the community, schools need to provide secure access. PCs have high value, so physical and software security is also usually required – for example “Kensington® Locks”, burglar bars on windows, padlocked doors, biometrics, access controlled areas, storage units for laptops and other mobile technologies. Disablement and recovery security tools, and hard-disk encryption such as bit locker should also be used.

Building blocks

Electricity

In many parts of the world, the electricity supply to schools is a major issue, but there are a range of technologies that can address this. The main options for off-grid power solutions are solar power, diesel/biofuel generators, wind power, hydrogen fuel cell, moped and stove.

Figure 4. Solar panels in a school in South Africa

Of these, solar is an increasingly popular option, especially as the price of diesel fuel continues to rise, with companies such as Inveneo delivering solar based solutions. In a UNHCR deployment in a refugee camp, for which Microsoft provided the computing solution, electricity is provided through NAPS Universal Power Packs. One NAPS Power Pack provides power for an infrastructure module with server, printer, wireless router, and projector or teacher work station. Other NAPS Power Packs power 4 workstations, and these can be added to the network in groups.

No schooling system wants to waste electricity so several considerations need to be made:

  • Form factors matter. Even without adding a monitor, a typical desktop computer can consume at a minimum more than 3x the power that a laptop consumes. The extra electricity used by desktops tends to dissipate as heat, which in turn requires more power in the form of air conditioning to remove.
  • The age and price of the computer matter too. Typically cheaper and older desktop computers will consume more electricity than newer, better quality laptops.
  • The operating system. For example, Windows 7 was designed to be the most energy efficient operating system available and used in conjunction with the right hardware can deliver considerable savings, even on older hardware.

Internet Access

Figure 6. Wi-Fi in a school in South Africa

Where providing electricity is a challenge, providing Internet access can be even more so. For areas not able to get broadband/wired access, there are many Internet access solutions available, the key ones being:

Dial-up

This is one of the simplest and oldest forms of Internet access and uses a normal phone line to connect a computer to an Internet Service Provider. Its relatively inexpensive, and widely availability where phone lines are present, but it’s also the slowest form of access with a maximum speed of 56Kbps. Another problem is that in schools which have only one phone line, others cannot use the phone while the computer is connected to the Internet.

Cellular

Cellular-based access requires a cell phone network that offers 3G or CDMA 2000 data and voice services. A cellular modem is required to connect a computer or computer network to the Internet via a cell phone provider. Data services charge according to the length of time you are connected to the network and the amount of data transmitted and/or received. Access speeds range from 56Kbps to over 500Kbps. This speed depends on the type of service available, the strength of the cell signal, the distance from the nearest cell transceiver, and local physical environment factors. The advantage of cellular networks are that they are widely available, but relative costs and fluctuating speeds mean that it’s not the best option for always-on, shared access, and high volumes of data.

Satellite

Satellite access enables Internet access in rural and remote areas where copper wire and fibre based options are not available. This option requires installation of a satellite dish and receiver which is then connected to the Internet router. Speeds range from 64Kbps to 5Mbps uploading and 128Kbps to 11Mbps downloading. Because upload times are faster than download times, ‘latency’ (i.e. the time that it takes from mouse click to seeing content in the browser) is long. Satellite connections can also be affected by rain and dust storms. Whilst its available almost everywhere, a satellite link must be within the “line of sight” of transmitting satellites.

Wi-Fi, WiMax

These two forms of wireless Internet access are usually available in larger towns and cities. These can be used for the delivery of a service to a specific customer or to provide access across an entire city. Wi-Fi can provide “point-to-point” access to locations up to 30 Km away, but this demands clear-line-of-sight between the transceiver and the location it is serving, a directional antenna and wireless receiver. WiMax, which is less commonly available, only requires a WiMax receiver.

Caching

Regardless of what internet access model is used, caching can allow users to experience less of a delay when their PC requests data from the network. For example, Windows 7 BranchCache caches data locally, enabling a better user experience.

Devices

There is a huge temptation to buy cheap and low-impact devices, but a golden rule is to understand that you generally get what you pay for. For example, colour inkjet printers are usually the least expensive to buy but often have the highest per page printing costs. Same applies to computers – cheap computers are cheap for a reason and will probably end up costing more in the longer run through having to maintain sub-standard components and higher electricity consumption. As discussed, the best approach is laptops for which a typical entry-level specification is 3GHz (clock) speed, 500GB Hard Drive (HDD) with 2GB RAM.

There’s also a temptation to buy devices other than PCs, including some ‘slate’ devices which have been designed primarily for content consumption. As discussed in detail in the “Learning Software 2.0” article, enabling children to create content is far more important than just enabling them to consume it, so laptops have a far higher potential return on investment.

Projectors and screens are also essential hardware, and one clever solution from South Africa – the compujector – combines a computer and a projector in one device – see http://www.astralab.co.za

Wireless routers should be purchased with built in security, Virtual Private Network (VPN), Firewall, and Ethernet capabilities.

It’s important to consider cabinets for securely storing and charging laptops too. Sometimes called “Classroom on Wheels”, these enable computers to be taken to different parts of the school. Lapsafe, is one leading manufacture worth checking out.

Network Management

With power, internet access, security and the right kind of facilities in place, the next challenge is to manage the devices so they are used effectively. This means controlling how the computers are used – creating and managing accounts; sharing files and learning materials; installing applications; monitoring and managing usage and hardware; protecting computers from viruses etc.

Figure 7. Windows Mulitpoint Server – controlling a mix of client computers

Windows Multipoint Server 2011 provides a solution which enables one computer to be used by up to 10 users, each with their own monitor, keyboard and mouse. This approach lowers the total cost of ownership by 66% compared to a traditional PC deployment, which typically uses a model that requires separate servers to enable file and hardware sharing, and computer management. WMS 2011 also enables teachers to easily control a classroom network, including networked client devices such as laptops. This was put to great effect in Haiti where, following the recent earthquake there, computer labs were hastily assembled with off-grid power solutions to deliver learning services.

Training

At this stage, training is about two key things – acquiring basic computing concepts and learning new pedagogic methods. Microsoft Digital Literacy helps students learn and assess their understanding of basic computing concepts and acquire 21st Century skills; and training for teachers in new pedagogic methods, which organisations such as Education Impact can provide .

Architectures

The main building blocks for introducing ICT into schools are as follows:

Figure 8. Key building blocks for taking the first steps

Who owns the computer makes a lot of difference. This decision narrows the access option to 1:1 – one device per student. If students get to take them home, the need for secure storage and charging diminishes – on the assumption that the computers can be used throughout the school. This in turn leads to decisions about pedagogy – will usage be restricted to a single room, or will students use the devices from lesson to lesson?

Figure 9. Different access options

Finally, decisions about lab layout are important too. Here the options range from “traditional” to “collaborative”.

Figure 10. Traditional classroom layout

Figure 11. Collaborative classroom layout

Is it worth the effort?

Introducing ICT into schools for the first time is costly and time-consuming. In Queensland Australia, 20 preparatory steps are taken before laptops are introduced into schools. First-time ICT introduction into any organisation is a non-trivial task.

According to the World Bank, much of the rationale for using ICT to benefit education has focused on its potential for bringing about changes in the teaching-learning paradigm. In practice, however, ICT is most often used to support existing teaching and learning practices with new and expensive tools.

But the World Bank goes on to say “consensus seems to argue that the introduction and use of ICT in education can be a useful tool to help promote and enable educational reform; ICT is both an important motivational tool for learning, and can promote greater efficiencies in education systems and practices”. With $2.4trn/year spent on schooling, with some systems just 7% effective – YES! it simply has to be worth taking these first steps.

Resources:

Thanks to Nasha Fitter and Rob Bayuk.