Holographic Experiences: A New Era of Immersive Educational Technologies

The word hologram comes from the Greek words holos, “whole,” and gramma, “message”. The derivative holography comes from the words holos -“whole” and graphē -“writing” or “drawing”.

The augmented reality training sessions for nurses (Gemini Research, 2017),  the MIT museum, Chinese museum, BBC frozen planet and the immersive experience of the Eurostar train (Eurostar, 2017)  make  people wonder what the future holds in store for educators, which new immersive technologies will be available and how they can be used to augment human experiences. Holography is considered a central theme of augmented reality. But how does it work and what does it really mean? Social media guest blogger Chryssa Themelis takes us behind the scenes, and offers her vision of the future.

A holographic image is composed of light-wave interference patterns. The interference patterns are created by splitting the beam from a laser, sending half to the subject (the object beam) and half directly to the photographic plate (the reference beam). The light reflected off the subject recombines with the light that went directly to the plate, creating a unique pattern of light-wave interference. After the recorded image is processed, the appearance of a 3D subject can be recreated by illuminating the photographic image with another laser beam (Kroon,2012). Hologram often depict an object or subject as a 3D image, using sophisticated laser projectors. Many other methods have been invented to develop holographic images or even video projections.

The Hungarian-British physicist Dennis Gabor was awarded the Nobel Prize in Physics in 1971 for his invention and development of “the holographic method”. The technique as originally invented is still used in electron microscopy. It facilitates biomedical research to investigate the detailed structure of tissues, cells, organelles and macromolecular complexes. Development of the laser popularized holograms starting in the ’60s. and grow rapidly since then. A hologram of a hand reaching out of a store window at the Cartier Fifth Avenue flagship captivates passersby in 1972. Princess Leia is presented holographically in Star Wars in 1977, National Geographic becomes the first mass circulation publication to put a hologram on its cover in 1984 and Designer Alexander McQueen caps his fall fashion show with a hologram of model Kate Moss in 2006 (Bloomberg, 2012). The list becomes endless especially after the invention of HoloLens in 2015.

Holography could play a major role in all levels education. Educational research shows that it could be linked to the theory of embodied cognition (Lakoff & Johnson,1999), facilitating the interaction and understanding because AR could give the human brain a sense of immersion (Invitro, Spada, and De Paolis as cited in De Paolis & Mongelli 2015). Holographic technology could be implemented for:

  1. Collaboration and interactivity. Students could work with other students, teachers or experts worldwide in what feels like face-to-face interaction. Holography may take videoconferencing to a physical level providing great opportunities for language learners and intercultural communication.
  2. Science. Holograms could allow students to experience mathematics visually, conduct experiments and learn about environmental phenomena in real life.
  3. History and social science. Students could tour historical sites and museums and talk to historical figures using mobile augmented reality application such as Aurasma.
  4. Educational gaming. Gaming would allow students to interact with the environments they create.
  5. 3D designing. Students in classrooms or makerspaces could complete a design project in three dimensions.
  6. Skills development. Holograms could train students how to do job-related tasks in vocational fields such as in medical science.

In the 21rst century, holography as new experiential approach, aims to unlock users form the 2D-limited world.  Alex Kipman, a Microsoft inventor, talks about “the dawn of the age of holograms” in a 2016 TED presentation and claims that we spend many hours per day looking at screens, but interactions and connectivity are limited. He points out: “We are like cave people in computer terms, we have barely discovered charcoal and started drawing the first stick figures in our cave “(TED, 2016).

About the Author

Dr. Chryssa Themelis is a researcher at Lancaster University, professor/doctoral advisor at Bolton University and an expert of technology enhanced learning (TEL). She works as a researcher/trainer for EU projects such as Erasmus + and coordinates the annual VocTEL conference aiming to promote TEL in Europe. In 2007, Hellenic American Union awarded her school of foreign language with a Certificate of Recognition. She holds a BA in Economics from Deere College, a MSc in Networked Learning and a PhD in the field of “E-research and Technology Enhanced Learning” from Lancaster University (department of educational research). Having studied at Harvard school of education, action research, she focuses on educational technologies, visual literacies and research methods. She belongs to the Networked Learning conference reviewers’ committee UK, the British Journal of Educational Technology reviewers’ panel, the open praxis journal, educational research and IRRODL journal editorial teams. As research assessor, she evaluates European Union proposals for H2020 FET Innovation Launchpad Calls. Her research material is published at books, peer-reviewed journals and presented at several conferences in the UK, Denmark, Spain, the USA, Italy and Greece.

 

References:

Bloomberg L.P. (2012). Holographic History. Retrieved December 2017 from Bloomberg database. https://www.bloomberg.com/news/photo-essays/2012-04-19/holographic-history

De Paolis, L., Mongelli, Antonio, & SpringerLink. (2015). Augmented and Virtual Reality [electronic resource] : Second International Conference, AVR 2015, Lecce, Italy, August 31 – September 3, 2015, Proceedings (1st ed. 2015. ed., Lecture Notes in Computer Science, 9254).

Holography; laser. (2012). In R. W. Kroon, 3d a-to-z: An encyclopedic dictionary. Jefferson, NC: McFarland. Retrieved from http://ezproxy.lancs.ac.uk/login?url=http://search.credoreference.com/content/entry/mcfthreed/holography_laser/0?institutionId=3497

Kipman, A. (2016, February). Alex Kipman: the dawn of the age of holograms [Video-file].  Retrieved from https://www.ted.com/talks/alex_kipman_the_dawn_of_the_age_of_holograms

Lakoff, G., & Johnson, M. (1999). Philosophy in the flesh: The embodied mind and its challenge to western thought. New York: Basic Books.

Feedback

  Comments: 2

  1. Sonia Ivette Rivera


    As a grad student from University of North Florida I am writing to you based on this article which impacted me to read.
    After understanding somewhat of this article I am now curious to know as having a background in medicine, whether this information could help researcher come up with a reading tool for patients with Macular degeneration or Retinitis Pigmentosa using Holgrams as you have described in this article.

Your feedback