How technology may help shape the future of education

A novel learning platform that uses a variety of mature technologies to support and expand teaching practices has recently completed testing, proving popular among high school students and teachers.


“The main part of the project used established pedagogical theories, such as the activity theory and the theory of expansive learning in a normal school environment. Of course we used technology to support this,” says Dr Costas Davarakis, project manager at Systema Technologies, the coordinating company for the IST-programme funded Lab@Future project. The project used four subjects, science, mathematics, history and environmental awareness, to apply the theory in a variety of situations.

Activity theory in dialogue with social constructivism maintains that people learn better when they participate in tasks themselves, rather than in a lecture situation where they just take notes.

“We introduced the activity model to try and understand the motivation behind the teachers’ work and the students’ learning. We were faced with cultural issues and systemic issues. For example, when students are facing an examination their motivation is entirely different from an educational and leisure situation,” says Davarakis.

Expansive learning is an element of activity theory, where students and teachers take advantage of unplanned events to deepen and broaden the educational goal. The team used expansive learning in the laboratory, whether it was a physics laboratory or a history laboratory, such as visiting a historical museum. In expansive learning, the broad outcome of the class is generally enhanced with the unexpected, Davarakis says. In other words, when something goes wrong, the students need to discover why, and the process of learning becomes more active.

For example, in physics a result might not turn out as expected, and the students have to figure out why. In history, students found that, when they visited a museum specialising in Byzantine history, all the exhibits referred to the Roman Empire. Later they discovered that the empire centred on Constantinople, modern day Istanbul, was always called The Roman Empire and that Byzantine is a modern term to differentiate the two phases of Roman history.

While the primary outcome of the project was to test whether these theories apply in the real world, technology was a major element of the project’s execution.

Technologies used to assist these aims included mechatronics, the combination of mechanical and electronic devices, augmented reality, virtual reality and mobile technologies (WiFi, GPRS on PDAs and Tablet PCs). In addition, the team experimented on haptic, or force feedback, devices and virtual reality gloves to enhance the virtual and augmented reality functionality. The team also developed a collaboration system to link students and teachers in a shared learning framework.

“It was really a technology integration project, and we used a lot of innovative yet mature technologies to achieve the pedagogical aims. Even so, during the project we did not focus on providing enough evidence to evaluate technology appropriateness,” says Davarakis, though work will continue among the partners to assess this over time.

The platform demonstrated specific experiments for fluid dynamics in science, geometry in mathematics, Byzantine history and archaeology and the effects of pollution for environmental awareness. These topics acted as test cases for teaching and learning in each field, providing the partners with an idea of the different applications performed with a broad range of topics from a typical school curriculum.

The fluid dynamics was available in a mixed reality environment, combining virtual reality with real objects. Here computer models combined with a mechatronics ’table’ that moved fluids in particular ways, so students could compare the computer modelling with a real experiment.

The geometry was available in an augmented reality environment, with geometrical shapes presented in three dimensions, while the history module was based on mobile learning set-up. Students learned about environmental awareness by using a three-dimensional game about pollution.

Technology proved to be more amenable to some subjects. “We found that for science using technology was a lot more straightforward. But in history lessons, using extensive virtual or augmented reality, was more of a gadget or entertainment approach, rather than purely educational. Mobile technologies, on the other hand, were very useful for history but served no real purpose in fluid dynamics material,” says Davarakis.

Students were between 11 and 18 years old and the level targeted was secondary and vocational education in seven countries. The project included nine partners in eight countries. The learning experiments were conducted in the local language to ensure student take-up and the evaluation content for all subjects was translated into English.

“Reaction from both students and teachers to the project is very positive, we can’t yet judge in detail how effective the systems are at improving learning and teaching. Analytical effectiveness was not part of the original brief, so some of the partners will continue work to assess effectiveness in the future,” says Davarakis.

Currently the project is undergoing final testing and evaluation. “The evaluation is the most difficult part of the project, because we have so many parameters. We had to cope with different pupils, teachers, schools and countries, all with different educational cultures,” says Davarakis.

Evaluation was further complicated because there were three different pillars to the project: the pedagogical theory, the technology and the evaluation. These pillars were spread through the four topics so the project has a huge set of results.

The biggest risk with the project is that it could develop as an ’island’, isolated from other developments in enhanced learning using technology, says Davarakis, so the consortium is actively trying to link their results with other work underway in the EU, among national governments and in private enterprise.

The partners also hope to commercialise the results of the project and wish to continue research. “We have developed a technology implementation plan. The consortium is very diverse and includes schools, universities, research institutes, and large and small industrial partners.”

“Each views the future from a different perspective. The research institutes want to exploit the data we collected. The technology companies, are trying to capitalise on the technology issues we’ve resolved for specific learning modules,” says Davarakis.

And that could mean that educational theory becomes translated into commercial reality.

Media Contact

Tara Morris alfa

More Information:

http://istresults.cordis.lu/

All latest news from the category: Science Education

Back to home

Comments (0)

Write a comment

Newest articles

Lighting up the future

New multidisciplinary research from the University of St Andrews could lead to more efficient televisions, computer screens and lighting. Researchers at the Organic Semiconductor Centre in the School of Physics and…

Researchers crack sugarcane’s complex genetic code

Sweet success: Scientists created a highly accurate reference genome for one of the most important modern crops and found a rare example of how genes confer disease resistance in plants….

Evolution of the most powerful ocean current on Earth

The Antarctic Circumpolar Current plays an important part in global overturning circulation, the exchange of heat and CO2 between the ocean and atmosphere, and the stability of Antarctica’s ice sheets….

Partners & Sponsors