Teens, trends and technology.

 

congerdesign / Pixabay

 

There is no comprehensive data on the recreational reading preferences of Australian children and teenagers across print or digital formats, but a study conducted by Deakin University and Murdoch University point out that teens have a clear preference for print in comparison to reading on devices (Cull, 2011; Dickenson, 2014; Earp, 2017).    This is surprising considering over 90% of Australian children and teenagers have access to a computer or laptop, but more than 75% never used them to access digital literature (Earp, 2017).   This information seems contradictory when you consider that recent fieldwork into public libraries showed a significant shift from traditional to more digital and computer based resources to compensate for the shift in the reading paradigm  (Wyatt, McQuire & Butt, 2015, p. 6-8).   This is because libraries are anticipating the long term presence of digital literature, and are motivated to curate their collection to hold a range of physical and digital resources, as well as a repository of technology for their clientele’s personal, social or educational use (Cull, 2011; Wyatt, McQuire & Butt, 2015, p. 8).   

O’Connell, Bales & Mitchell (2015) point out that the advent of e-books and e-readers have been the biggest game changers for school libraries in the past few decades.  E-books, especially e-textbooks have become increasingly popular in schools across the country as they are able to integrate multimodal features such as interactive maps, videos and images and enhance teaching and learning practices (O’Connell, Bales & Mitchell, 2015).  E-books also meet ACARA’s mandate to include a variety of print, digital and hybrid resources as part of the ICT and Literacy components of the General Capabilities (ACARA, 2018). 

Whilst e-books address curriculum requirements and educational needs of the modern student, O’Connell, Bales & Mitchell (2015) do acquiesce that including digital literature may be cost prohibitive to many schools and students.  Many students, especially those in lower socio-economic areas lack the financial ability to purchase a personal device to access e-books, and many schools cannot afford to purchase additional e-readers or other personal devices for all their students.  The other pertinent issue is internet access.  E-library subscriptions such as Wheelers require internet access at all times to read the book which is problematic when on public transport or out of wifi, whereas Borrowbox titles can be downloaded and then used offline, which is far more beneficial.  But both e-book repositories permit only one borrower at a time to access a title.  For class texts , this can be extremely expensive for schools to purchase multiple subscriptions for the same title.  The other pecuniary issue is that many e-books are often just ‘leased’, and as they are not owned by the school, can suddenly become unavailable and or the lending parameters change without warning.  

Whilst the cost of e-books may be prohibitive, the on-going costs of maintaining digital literature subscriptions for online encyclopaedias and databases are often cheaper than  obtaining individual journal subscriptions (Cull, 2011).  Academic libraries in particular, often purchase databases with access to a variety of journal articles for a lower cost than individual subscriptions.  Smaller libraries may coalesce to purchase a subscription together.  For example, ACT local libraries offer Gale databases as part of their collection.  

When it comes to genres, recent publishing trends show an increase in young adult literature across Australia and the world (Manuel & Carter, 2015).  These trends indicate two possible reasons, the first being that young adults are reading increasingly, and the second, is that as teenagers age into adults, they are retaining their young adult reading preferences.  Manual & Carter (2015, p.122) point out that fiction is still the most popular choice for teens, followed by multimedia, non-fiction and magazines.  Genre wise,  fantasy and mystery are popular with both sexes, and romance disdained by everyone (Manuel & Carter, 2015, p.123).  Graphic novels are making a comeback but this time in a digital space, girls seem to like detective stories, action and adventure, whereas boys like science fiction, informational texts and biographies AND EVERYONE HATES POETRY (Manuel & Carter, 2015, p.123-124; Moorefield-Lang & Gavigan, 2011))!  

What is interesting about reading preferences with teenagers is that text selection and pedagogical practices in the classroom actually has an impact on students.  When inappropriate classroom texts are selected, and or the pedagogy associated with them is poor, students develop an antithesis for that particular title/genre or reading in general (Manuel & Carter, 2015, p.125).  A perfect example would be Golding’s Lord of the Flies. I studied this text many moons ago and I only have ghastly memories of the text. 

I am an avid reader and I STILL GET THE HEEBIE JEEBIES when I think about that book.  

Whereas appropriate texts and good pedagogy can bolster a love of reading.  I studied Charlotte Bronte’s Jane Eyre ain high school and I still love her to the point where I have seven copies of Jane Eyre!!!

   

 

 

*All imageswere obtained from the public domain.

YES I HAVE 7 COPIES OF JANE EYRE!!!

 

 

Digital devices have been often touted as the panacea for improving reading rates, literacy and learning for three main reasons.  Introducing digital literature into classroom practice allows teachers to bridge the digital disconnect between a teenager’s personal life in the digital world and the school’s analogue world.  By making these valuable connections, teachers are able to lure students to tasks they may normally disdain, such as reading class texts or researching online.  Combined with the fact that most teenagers are permanently glued to their personal devices means that they are very receptive to the idea of using (their phones and) digital literature for personal and educational purposes.

 

REFERENCES:

Cull, B. W. (2011). Reading revolutions: online digital text and implications for reading in academe. First Monday, 16(6). Retrieved from http://firstmonday.org/ojs/index.php/fm/article/view/3340/2985

Dickenson, D. (2014). Children and reading: Literature review. Australia Council 2014. Retrieved from https://www.australiacouncil.gov.au/workspace/uploads/files/research/children-and-reading-literatur-5432557e418db.pdf.

Earp, J. (2017). Infographic – Teen reading habits. Teacher Magazine. Australian Council for Educational Research.  Retrieved from https://www.teachermagazine.com.au/articles/infographic-teen-reading-habits

Houston, C. (2011). Digital Books for Digital Natives. Children & Libraries: The Journal of the Association for Library Service to Children, 9(3), 39–42. EBSCO 

Manuel, J., & Carter, D. (2015). Current and historical perspectives on Australian teenager’reading practices and preferences. Australian Journal of Language and Literacy, 38(2), p.115-128. Retrieved from https://www.alea.edu.au/documents/item/1175

Moorefield-Lang, H., & Gavigan, K. (2012). These aren’t your father’s: the new world of digital graphic novels. Knowledge Quest, 40(3), 30-35. Retrieved from http://web.b.ebscohost.com.ezproxy.csu.edu.au/ehost/detail/detail?vid=0&sid=b349502e-3dd2-48d3-9d9a-6beed7db31cc%40pdc-v-sessmgr05&bdata=JnNpdGU9ZWhvc3QtbGl2ZQ%3d%3d#AN=82563984&db=lih

O’Connell, J., Bales, J., & Mitchell, P. (2015). Literature in digital environments: Changes and emerging trends in Australian school libraries. In L. Das, S. Brand-Gruwel, K. Kok, & J. Walhout (Eds.), IASL 2015 Conference Proceedings: The School Library Rocks: Living it, Learning it, Loving it (pp. 356-369). International Association of School Librarianship. http://www.meles.nl/_clientfiles/SMD/IASL2015_Proceedings_Vol2_2ndEd_ResearchPapers.pdf

Teen Reading In a Digital Era. (2017). Report at a glance – Teen Reading in a digital era. Murdoch University & Deakin University.  Retrieved from https://teenreadingdotnet.files.wordpress.com/2017/04/teen-reading-folio-report_email.pdf

Wyatt, D., McQuire, S., & Butt, D. (2015). Public libraries in a digital culture.  University of Melbourne & State Library of QLD. University of Melbourne Press. Melbourne Victoria. Retrieved from https://arts.unimelb.edu.au/__data/assets/pdf_file/0005/1867865/PublicLibrariesinaDigitalCulture.pdf

Task 1 – INF533 – Reading, literacy and digital literature in the classroom.

xxolaxx / Pixabay – Reading in a digital landscape.

 

The advent of technology, and plethora of personal devices has revolutionised the reading paradigm to the point where, texts are no longer restricted to print, but are now available through multiple formats and platforms.  Digital literature utilises a continuum of technology to convey meaning, and the level of computation varies from a scanned book, to the interactive hypertext narratives with multimodal features  with a host of genres and hybrid genres such as e-stories, linear e-narratives, interactive stories, hypertext narratives and electronic games narratives. in the middle (Walsh, 2013; Maneti, Lipscombe & Kervin, 2018; Rettberg, 2012).  These new formats as Lamb (2011), and Sadokiesiski (2013) point out, require additional literacies to engage, process, evaluate and communicate. 

This is because reading has evolved from text decoding, to constructing meaning from symbols (Lamb, 2011) . 

ACARA’s (2018)  response has been to define literacy as the ability to interact with, engage and communicate across modalities for personal, social, economic and recreational purposes. 

This definition clearly indicates that teaching practice needs to include a variety of texts, in print, digital and hybrid formats (Leu, Forzani, Timbrell, & Maykel, 2015).  But whilst there are strong arguments and mandates to include digital texts, there are are complications.  

Many students struggle with digital text comprehension, as the simultaneous synthesising of visual, audio and text information causes information overload (Jeon, 2012; Mangen, Walgermo & Bronnick., 2013).   Students with poor fundamental literacy are at further disadvantage, as they are easily distracted away from the content by the multimodal elements, as well as being unable to locate information due poor visual ergonomics (Lamb, 2011; Leu, McVerry, OByrne, Kili, Zawilinski, Everett-Cacopardo,Kennedy, Forzani, 2011;  Jeon, 2012; Hashim & VongKulluksn, 2018; Mangen et al., 2013, p.66). 

geralt / Pixabay – Feeling overwhelmed???

 

I have noticed that here is a strong disinclination for teachers to include the creation of hypertext narratives and games in their practice (Mantei, Lipscombe & Kervin, 2018).  This hesitancy could be attributed to the premise that it requires both the student and the teacher to be competent in the additional literacies  (Leu et al., 2015).  Whilst many students could be considered digital natives and may possess the necessary skill set to create such hypertext, many teachers would be considered digital immigrants and therefore lack the confidence to implement such technologies in their classroom.  Unfortunately by excluding creation of digital texts, students are disadvantaged by the lack of potential extension and consolidation of learning. 

Armstong (2020) Bloom’s Taxonomy. CC – BY – NC

Remember Bloom – By failing to include a creative element – students are being denied opportunities for higher order thinking.  

In an effort to address some of these concerns, our library team has a balanced collection of print and digital literature, as well as have recently implemented an information literacy scope and sequence  (Leu et al., 2015).  Our students have access to a robust physical collection, e-books and audiobooks through a BorrowBox subscription, as well as online databases such as InfoBase, Gale, Britannica, EBSCO, Trove, and World Book.  

Anecdotally from my position as a teacher librarian, I can see the students vastly prefer print for recreational reading, but have a strong preference for digital resources for informational purposes.  I regularly see many teachers include digital texts into their teaching practice through reading and viewing of e-books, online databases and web based texts.  Through our information literacy program, we are endeavouring to teach digital literacy skills, such as, how to locate, evaluate and synthesise information, as well as problem solving in both online and offline scenarios (Leu et al., 2015, p. 140).  

Digital literature has transformed society, the definition of literacy and the landscape of pedagogical practice.  Time will only tell if our scope and sequence improve digital literacies and competencies in both the faculty and the students… stay tuned for further updates

 

 

References 

Armstrong, P. (2020). Bloom’s Taxonomy. Center for Teaching, Vanderbilt University. Retrieved from https://cft.vanderbilt.edu/guides-sub-pages/blooms-taxonomy/. Image licenced under CC – BY – NC 

Australian Curriculum, Assessment and Reporting Authority. (2018). Literacy. In Australian Curriculum – General Capabilities. Retrieved from https://www.australiancurriculum.edu.au/f-10-curriculum/general-capabilities/literacy/

Hashim, A & VongKulluskn, V. (2018). E reader apps and reading engagement: A descriptive case study. Computers and Education, 125, pp.358-375. Retrieved from https://www.journals.elsevier.com/computers-and-education/

Jabr, F. (2013). The reading brain in the digital age: The science of paper versus screens. Scientific American. Retrieved from https://www.scientificamerican.com/article/reading-paper-screens/

Jeon, H. (2012). A comparison of the influence of electronic books and paper books on reading comprehension, eye fatigue, and perception. The Electronic Library, 30(3), 390-408. doi: 10.1108/02640471211241663 

Lamb, A. (2011). Reading redefined for a transmedia universe. Learning and leading with technology, 39(3), 12-17. Retrieved from http://ezproxy.csu.edu.au/login?url=http://search.ebscohost.com/ login.aspx?direct=true&db=ehh&AN=67371172&site=ehost-live

Leu, D., McVerry, J. G., O’Byrne, W. I., Kiili, C., Zawilinski, L., Everett-Cacopardo, H., Kennedy, C., & Forzani, E. (2011). The new literacies of online reading comprehension: Expanding the literacy and learning curriculum. Journal of Adolescent & Adult Literacy, 55(1)5-14. Doi: 10.1598/JAAL.55.1.1

Leu, D.J, Forzani, E.,Timbrell, N., & Maykel., C. (2015) . Seeing the forest, not the trees: Essential technologies for literacy in primary grade and upper elementarty grade classroom. Reading Teacher 69: (2), p.139-145. Retrieved from https://eric.ed.gov/?id=EJ1073399

Mangen, A., Walgermo, B. R. & Bronnick, K.A. (2013). Reading linear texts on paper versus computer screen: Effects on reading comprehension. International Journal of Educational Research, 58, 61-68.doi:10.1016/j.ijer.2012.12.002 

Mantei, J., Kipscombe, K., & Kervin, L. (2018). Literature in a digital environment (Ch. 13). In L. McDonald (Ed.), A literature companion for teachers. Marrickville, NSW: Primary English Teaching Association Australia (PETAA).

Rettberg, J.W. (2012). Electronic literature seen from a distance: the beginnings of a field. Retrieved from http://www.dichtung-digital.org/2012/41/walker-rettberg.htm

Sadokierski, Z. (2013, November 12). What is a book in the digital age? [Web log post]. Retrieved from http://theconversation.com/what-is-a-book-in-the-digital-age-19071

Sargeant, B. (2015). What is an ebook? what is a book app? And why should we care? An analysis of contemporary picture books. Children’s Literature in education, 46, p.454-466. doi: 10.1007/s10583-015-9243

Walsh, M. (2013). Literature in a digital environment (Ch. 13). In L. McDonald (Ed.), A literature companion for teachers. Marrickville, NSW: Primary English Teaching Association Australia (PETAA).

Augmented Reality – Part 7 – Contraindications, Limitations and Future Implications

CONTRAINDICATIONS AND LIMITATIONS OF AUGMENTED REALITY USE IN THE CLASSROOM 

There are a few issues with implementing innovative teaching practices such as AR into classrooms.  These reasons include misconceptions with using ICT in the classroom, teacher reluctance and insufficient access to technology and the internet.

  1. MISCONCEPTIONS ABOUT ICT IN THE CLASSROOM – There is a significant disinclination from some educators about the inclusion of digital technology into classroom practice.  This reluctance can stem from a belief that technology causes students to become passive in their learning and that encouraging the use of personal devices increases class distractions (Wu et al., 2013).  Saidin, Abd Hali & Yahaya (2015, p.1) disagree vehemently and argue that AR actually causes the learner to become more interactive with the learning content as it requires the student to think critically and be able to make meaning from their interactions.  Wu et al. (2017) suggests that the use of mobile phones promotes social interactivity and student collaboration when using through networked devices.  
  2. TEACHER RELUCTANCE – Many teachers are not comfortable with emerging technologies due to their own lack of knowledge with the medium (Pope, 2018a).  Wolz (2019, p.6) points out that teachers, like students, develop self efficacy from their own ability, observing others and verbal affirmation.  Self efficacy of teachers and educators is essential, as there is a strong correlation between teacher competence and inclusion of digital technologies in the classroom  (Wolz, 2019).  Saidin, Abd Hali & Yahaya (2015, p.1) argue that all teachers should be required to continuously keep abreast of new products as part of professional learning and development.   Unfortunately, requiring all teachers to be familiar and confident with emerging technologies is simply unfeasible.  Many teachers are already overworked and overwhelmed with their current workloads.  Therefore, it is more viable that each school has dedicated ICT teachers, or teacher librarians, that are tasked with embedding emerging technologies into classroom practice.  This method allows both classroom teachers and students to improve their digital literacy skills and develop ICT acuity concurrently.  For schools with a library, it makes sense to ensure the TL has self efficacy with AR/VR technology as most AR installations are sourced in their teaching and learning spaces.    
  3. DIGITAL DIVIDE – This is a significant hurdle to the implementation of digital technologies such as AR in Australian classrooms.  The high cost of technology has inhibited its diffusion across classrooms, but the recent rapid advancements and price has reduced this barrier significantly (Wolz, 2019, p.2).  It is not common for all students and schools to possess mobile devices and or have available data to have transactions with AR.  This issue is more common in rural areas and within lower socio-economic families and schools (DIIS, 2016).   The extent of the digital divide has been highlighted and under scrutiny by the recent COVID 19 school closures, where the lack of internet and device access caused many students to be unable to access home learning.  

 

IMPLICATIONS FOR THE FUTURE

Oddone (2019) and Zak (2014) suggest that VR and AR will become mainstream technology soon and it behooves educators to equip students with the necessary skills to maintain their digital literacy.  Previously access to these technologies was extremely expensive and many schools were unable to gain access due to lack of funds. However,  rapid changes in technology have led to a significant price reduction, but even with the decreased costs, AR installations are still out of reach for many schools.  For schools and educational institutions that can afford these emerging technologies, there are educators that lack confidence in their ability to use AR, and there are others that find the available AR content is not suited to the needs of their students (Wu et al., 2013, p.46).  Whilst centralising emerging technologies into the library addresses the lack of self efficacy of teachers, it does not solve the issue of unsuitable AR content.   

Hannah et al., (2019) proposes that schools create their own 3D content objects that suit their students and align to the curriculum as needed.  As part of this approach, images are curated and integrated into the library management system that shares knowledge and collaboration.  This method allows all the images that are created in the school by both staff and students to be stored for future use whilst acknowledging the authorship and intellectual property ownership of the images.  This proposition is an extension of Zak (2014) idea of using AR in information seeking as mentioned previously.   Whilst collection management is part of a librarian’s repertoire, the curation of 3D images requires new vocabulary and ontology, and requires further exploration of the relevant literature.  Therefore, it makes logical sense that AR installations and its other forms of hardware and software are centralised in the library and the teacher librarian tasked with cataloging the 3D images, embedding AR and other emerging technologies across the curriculum.  

Augmented Reality in the Classroom – Part 6 – Role of the TL

Bit of a hiatus since the last post… I decided to go on holidays.

 

ROLE OF TEACHER LIBRARIAN

The library and the teacher librarian hold a central position in the school learning and teaching dynamic and thus are ideally positioned to engage in collaborative planning and teaching across the curriculum.  Like libraries, the role of the teacher librarian has evolved in response to the metamorphosis of repository spaces to information gateways.  ASLA (2016) clearly defines the foci of a modern teacher librarian to; learning and teaching, resourcing the curriculum, management of the library and its resources, providing leadership, collaborating with their peers and engaging with the school community.  

Even though libraries and the role of the teacher librarian has evolved, their main purview in a school has not changed.  Information seeking is the core of each school library, and the main point of the teacher in teacher librarian is  information literacy and the explicit teaching of ICT (ALIA & ASLA, 2004).  This teaching role extends to both staff and students, as teacher librarians are required to model good practice, and explicitly teach information seeking behaviour and information literacy to everyone in the school community (ALIA & ASLA, 2004; ALIA, 2014).  

All teachers in Australia are required to integrate technology into their teaching and learning, but many classroom educators are unaware of the benefits of emerging technologies such as AR and VR (AITSL, 2017).  Consequently, the task of educating staff about emerging technologies falls onto the teacher librarian.  This is because teacher librarians are required by ALIA & ASLA (2014), ALIA (2014) and ASLA (2014) to be familiar with emerging technologies, provide access to and integrate them into library practice, programs as well as support the school community in using them effectively.  

There are many traditional ways of introducing these technologies, such as staff emails or meetings, but there are innovative ways of introducing emerging technologies to the school community.  Townsdin & Whitmer (2017) suggested AR embedded library marketing as an effective way of promoting the library and its services whilst improving information literacy, whereas Wolz (2019) points out that using AR in information seeking covertly introduces colleagues to the technology whilst they overtly search the catalogue.  Pope (2018a) proposes that AR can be introduced through team building exercises, and Zak (2014) suggests the use of AR embedded resources as an effective method of introducing AR into classroom practice.   

Whilst all those listed are valid methods of introducing the school community to new technologies, the most effective manner is by using AR embedded classroom resources.  By using emerging technologies in teaching resources, students and staff are gaining access to high quality information that meets curriculum needs and student development.  The secondary and almost furtive asset is that students gain access to these new technologies and are given opportunities to experiment in a low stakes environment.  This tactic also gives classroom teachers an opportunity to experiment and play with the technology themselves, so that they can effectively use them in their classrooms (Zak, 2014).   From a library management position, teacher librarians are required to regularly evaluate their strategies and services to ensure that it meets the needs of their community, and this extends to AR programming and resourcing  (Zak, 2014).  This evaluation must also broaden to include any mobile applications, 3D image repository or hardware that the library choses to maintain as part of their collection and digital technologies program (Zak, 2014). 

Augmented Reality in a school library – Part 5.

So far I have covered ways in which emerging technologies such as AR can be incorporated into the classroom.  This next section is about this technology can be used in school libraries as part of resource management, pedagogical practices and collaborative learning.

ROLE OF THE LIBRARY

School libraries and teacher librarians play a pivotal role in technology access.  School libraries have long been known for providing equitable access for information (ALIA, 2014).  The digital revolution has changed the primary purpose of libraries from information repositories to being gateways to knowledge.  This is because a library collection is no longer limited to print texts but now extends to including ebooks, digital resources,online databases and emerging technologies.  Consequently, by extending this access to emerging technologies like AR and VR, school libraries are building the value of their resources and concurrently, reducing the impact of the digital divide on their students (DIIS, 2016).  There are several ways in which a library can introduce emerging technologies such as AR to their patrons.  These include:

 

  1. AR EMBEDDED TEXTS – These resources are also the most cost efficient method of introducing AR technology to students,  as it enables them to experience the technology but without the associated costs of setting up hardware and software (Brigham, 2017; Foote, 2018).  Magana, Serrano & Rebello (2018, p. 526) cite clearly there is an increased student understanding when multimodal resources such as AR embedded information texts are used when compared to traditional texts. The reason why AR technology has increased efficacy in informational resources is that haptic feedback is non verbal and students focus on that as the primary source of information and the text provides the support (Magana, Serrano & Rebello, 2018).  This method is currently in place in most schools and academic libraries and some libraries offer a smart device loan scheme as well to assist with AR resources for offsite learning.
  2. MAKERSPACES – Makerspaces convert students from users of content to creators of knowledge as they allow students to pursue individual projects in and out of class time,  as well as facilitate independent and cross disciplinary learning (Slatter & Howard, 2013).  Many libraries have designated makerspace areas to facilitate creativity and critical learning and free play.  Pope (2018a) points out that free play should be encouraged as it allows users of all ages to learn through experimentation, even if the original point was educational or recreational in purpose.  These areas also allow teachers to experiment with new technology for their own personal benefit or to embed into their teaching practice (Slatter & Howard, 2013).
  3. AR INSTALLATIONS – An extension of makerspaces are AR installations.  These areas, known as sandbox programming, are permanently devoted to experimentation, exploration and demonstrations of AR/VR technology  (Townsdin & Whitmer, 2017).  Some examples of AR installations are TinkerLamp and zSpace. TinkerLamp was the forerunner of AR technology and required a screen, a projector, experimentation board and an interferometer (Furio et al., 2017, p.3).  Whereas the more modern zSpace consists of a computer, stylus and specialised glasses (Foote, 2018).                                                                                                                 Foote (2018) correctly points out that it is not cost effective to implement AR technology into every classroom, and that AR elements are best served through shared spaces such as the library.  But even then, these installations are not common in schools as Merge cubes, as they are very expensive and the latter is cheaper and more flexible for group use (Pope, 2018a).  
  4. LIBRARY OUTREACH AND MARKETING – Library tours, displays and other promotional programs have an immense capability for AR.  AR embedded posters and displays are an innovative method to engage students, and can convey useful information about seasonal events, special collection, library skills and services (Townsdin & Whitmer, 2017).  It is also possible to gamify library maps with embedded GPS tagging as a method of incentivising students to explore the various library spaces and facilities (Balci, 2017; Townsdin & Whitmer, 2017).  Besides being innovative, the use of mobile applications facilitates the collection of user data.  Library staff are able to analyse this data and use it to appraise student engagement, as well as illustrate the library’s effectiveness in adapting to advancements in technology (Townsdin & Whitmer, 2017). 
  5. INFORMATION SEEKING BEHAVIOUR –  There is scope for libraries to implement AR as part of their learning management system, the delivery of information and the provision of data (Zak, 2014).  The modern student has a preference for technology based practices and this extends to information seeking (Wolz, 2019). Zak (2014) suggests that by using emerging technologies as part of information seeking, libraries are speaking the same language as their clientele.

 

REFERENCES:

Australian Library and Information Association. (2014). Future of the Library and Information Science Profession. ALIA Futures. Retrieved from https://www.alia.org.au/sites/default/files/documents/advocacy/ALIA-Future-of-the-Profession-ALL.pdf

Balci, L. (2017). Using augmented reality to engage students in the library. Information Today Europe [Blog]. Retrieved from https://www.infotoday.eu/Articles/Editorial/Featured-Articles/Using-Augmented-Reality-to-engage-students-in-the-library-121763.aspx

Brigham, T. (2017). Reality check: Basics of augmented, virtual, and mixed reality. Medical Reference Services Quarterly (36) 2. Pp 171-178. DOI: 10.1080/02763869.2017.1293987

Department of Industry, Innovation and Science (2016). Australia’s digital economy update. Retrieved from https://apo.org.au/sites/default/files/resource-files/2016/05/apo-nid66202-1210631.pdf

Foote, C. (2018).  Is it real or is it VR? Exploring AR and VR tools. Computers in Libraries. Retrieved from http://web.b.ebscohost.com.ezproxy.csu.edu.au/ehost/pdfviewer/pdfviewer?vid=0&sid=6093ea4d-06fa-42b1-8400-75e5bd1dd875%40pdc-v-sessmgr03

Furio, D., Fleck, S., Bousquet, B., Guillet, JP., Canioni, L., & Hachet, M. (2017). HOBIT: Hybrid optical bench for innovative teaching. CHI’17 – Proceedings of the 2017 CHI Conference on Human Factors in Computing Systems. Retrieved from https://hal.inria.fr/hal-01455510/file/HOBIT_CHI2017_authors.pdf

Magana, A., Serrano, M., & Rebello, N. (2018). A sequenced multimodal learning approach to support students’ development of conceptual learning. Journal of Computer Assisted Learning, 35 (4). DOI https://doi-org.ezproxy.csu.edu.au/10.1111/jcal.12356

Pope, H. (2018a). Virtual and augmented reality in libraries. Library Technology Reports – American Library Association, (54)6.

Slatter, D., & Howard, D. (2013). A place ot make, hack and learn: makerspaces in Australian public libraries. Journal of the Australian Library and Information Association, 62(4), pp.272-284. Retrieved from https://eprints.qut.edu.au/73071/1/73071.pdf

Townsdin, S., & Whitmer, W. (2017). Technology. Public Services Quarterly. 13. Pp190-199. DOI: 10.1080/15228959.2017.1338541

Wolz, K. (2019). Building faculty competence and self efficacy for using ZSpace virtual reality (VR) software in the classroom. All Regis University Theses. Retrieved from https://epublications.regis.edu/cgi/viewcontent.cgi?article=1930&context=theses

Zak, E. (2014). Do you believe in magic? Exploring the conceptualisation of augmented reality and its implication for the user in the field of library and information science.  Information Technology and Libraries.

Augmented Reality in the Classroom – Part 4

Continuing with the series….

More ways in which AR can be applied in a school dynamic. 

6. NUMERACY

Numeracy skills can be enhanced using AR.  Wu et al. (2013) suggest that students can learn geometry, trigonometry, spatial relationships and collaborative problem based learning by using AR to supplement their learning.  Technologies such as the combination of TinkerLamp and Kaleidoscope are popular in Europe and can be used to explore symmetries and congruence.  Whereas the mobile application – AR Measure kit is useful in measuring distances, trajectories, angles, height and estimating volume  (Cuendet, Bonnard, Do-Lenh & Dillenbourg, 2013).  

7. SUPPORT LITERARY ARTS

Hannah et al. (2019) cited several methods in which AR can support the literary arts curriculum.  Students are able to create or visit real or fictional sites using the digital interfaces such as Merge cubeso that connections between the content and the real world can be made.  For example, Shakespeare comes alive with a tour of Verona, Japanese medieval history can be taught by analysing the structure of Kokura Castle, and students can investigate the structure of a steam engine, all with a single mobile app, a smartphone or tablet and a Merge cube.  

8. VISUAL ARTS

A very interesting use of AR is the ability to access and engage in an authentic exploration of real objects in an artificial space (Wu et al. 2013).  Many art galleries and museums around the world already have embedded AR to allow users access to additional information about the display, for example, some places use QR codes to inform the user of additional information about the artist or exhibit (Coates, 2020).  From a classroom perspective, students can support their own creative pieces by embedding their rationale using Thinglink, Padlet or Metaverse, and use QR codes on their paintings, sculptures, photographs or collages to link it to their rationale (Zak, 2014) .  

9. LOCATION BASED LEARNING

Wu et al., (2013) suggests that location based learning, such as field trips and excursions, can be augmented by the use of AR.  As previously mentioned, many museums, galleries and other institutions have already adopted the use of AR in their spaces (Coates, 2020; Townsdin & Whitmer, 2017).   Some of them use the technology to provide additional information to the user about the collection, whereas other places use AR in their maps or tours  (Townsdin & Whitmer, 2017).  By including relevant information within the augmented space, it encourages more authentic learning, which in turn improves student engagement and learning outcomes (Wu et al., 2013). 

Emerging technologies have also been adopted by some council reserves and state national parks as a means to inform users about local flora and fauna.  Visitors are able to use their devices and their inbuilt GPS systems to access pertinent information about the site they are accessing (Townsdin & Whitmer, 2017).  Some sites also offer remote access and this can be very useful for excursion preparation or for revision purposes.  Remote access would also be of great assistance when students are unable to attend excursions or field trips due to illness or pandemics. 

10. ASSISTING STUDENTS WITH DIVERSE LEARNING NEEDS

Technology has often been cited as an effective intervention method for students with autism spectrum disorder (ASD) and educators seek methods in which to meet cognitive, behavioural and developmental needs (Sahin, Keshav, Salisbury & Vahabzadeh, 2018).  Digital methods are often favoured  for ASD students, as they tend to have a preference for electronic media due to their predilection as visual learners (Mahayuddin & Mamat, 2019, p.2176-2177).  Additionally AR offers them an environment that supports the tangible manipulation of abstract ideals, as well as a visual image of the learning content, and standardised and predictable outcomes as routine and predictability is very important to students with ASD (Mahayuddin & Mamat, 2019, p.2176-2177; Sahin et al., 2018, p.1).   

AR and VR are also able to assist ASD students in developing their socio-emotional skills.  This technology allows students to experience the world and its environmental hazards as well as engage and interact with their peers in a socially controlled environment (Sahin et al., 2018, p.2; Riva, Banos, Botella, Mantovani & Gaggioli; 2016).   Whilst tablets and smartphones can be used, Sahin et al. (2018) suggests the use of SmartGlasses as they can be preloaded with social and behavioural coaching software.  Another benefit is that AR experiences can be tailored and adapted to suit student’s diverse needs, which is important as many experience high levels of anxiety when there is disruption to their learning plan.  

 

Augmented Reality in the Classroom – Part 3

Continuing on the series….

Here are few ways in which AR can be applied in a school dynamic.

  1. STUDENT ENGAGEMENT 

Technology has often been cited as a tool to increase student engagement.  Bonascio (2017) and  Magana, Serrano & Rebello (2019) theorise that AR is able to prolong attention and focus, as when multimodal resources and haptic devices are used, higher levels of enjoyment are experienced.  This gratification is significantly reduced in students that do not comprehend the mechanics of the technology and indicated that whilst utilising AR can improve digital literacy, explicit teaching is required to ensure that all students are able to interact successfully with the technology (Magana, Serrano & Rebello, 2019). 

               2. INQUIRY LEARNING

Oddone (2019) and Foote (2018) both suggest that greater educational benefits arise from students creating their own interactive images and overlays rather than using supplied ones.  Apps such as Metaverse or Augment can be used by students to construct their own interactive content and would be an ideal cross curricular inquiry task across any discipline, but have curriculum value within the Science, History and Geography inquiry skills section. Examples of inquiry tasks include:

 

 

 

 

 

 

 

3. ABSTRACT CONCEPTS & STEM SUBJECTS

Magana, Serrano & Rebello (2018, p.526) believe that there is a positive effect to using multimodal resources and active learning for science and its related fields. This is because students often need assistance with visualising complex and abstract concepts (Saidin, Abd Hali & Yahaya, 2015; Riva, Banos, Botella, Mantovani & Gaggioli, 2016).  Abstract concepts can be problematic for many students because of the difficulty students can have in visualising theoretical postulations (Furio, Fleck, Bousquet, Guillet, Canioni & Hachet, 2017, p.2-3 ).  This struggle can negatively influence a student’s perception of the content material and lead to adverse learning outcomes (Furio et al., 2017, p.2-3 ).   AR technology allows students to visualise the concept, albeit in animation, and increase comprehension which leads to improved outcomes  (Saidin, Abd Hali & Yahaya, 2015, Wu et al., 2013).  This is because haptic devices allow students to manipulate and utilise their sensory faculties when they are constructing knowledge. Large and small phenomena, as well as anatomical figures, can be visualised using AR technology (Wu et al. 2013). 

 

High school curriculum linked examples include:

 

 

 

 

 

 

 

4. READING – RECREATIONAL & INFORMATIONAL

AR books is the largest growing trend in children’s publishing and that many publishers are supplementing traditional texts with AR embedded resources (Levski, 2018; Zak, 2014). This is because AR books are seen as more innovative and able to improve flagging reading rates in children and adolescents (Levski ,2018, Zak, 2014).  Many young readers find the interactivity extremely engaging and the use of technology appeals to digital natives (Magana, Serrano & Rebello, 2019).

5. LITERACY

Mayahayuddin & Mamat, (2019) point out that the multimodal nature of AR improves literacy because the audio visual cues assist students in decoding.   Additionally,  AR enables students that have low focus or attention to enhance their learning as it grants access  to language in both formal and informal contexts, which is very useful for students with ADD, ADHD and those with social anxiety (Rafiq & Hashim, 2018, p.31; Mayayuddin & Mamat, 2019.  These benefits are further improved when AR is combined with gaming principles which provides additional interest and intrinsic motivation  (Mayahayuddin & Mamat, 2019; Levski 2018). 

 

REFERENCES

Foote, C. (2018).  Is it real or is it VR? Exploring AR and VR tools. Computers in Libraries. Retrieved from http://web.b.ebscohost.com.ezproxy.csu.edu.au/ehost/pdfviewer/pdfviewer?vid=0&sid=6093ea4d-06fa-42b1-8400-75e5bd1dd875%40pdc-v-sessmgr03

Furio, D., Fleck, S., Bousquet, B., Guillet, JP., Canioni, L., & Hachet, M. (2017). HOBIT: Hybrid optical bench for innovative teaching. CHI’17 – Proceedings of the 2017 CHI Conference on Human Factors in Computing Systems. Retrieved from https://hal.inria.fr/hal-01455510/file/HOBIT_CHI2017_authors.pdf

Levski, Y. (2018). 10 Augmented Reality Books That Will Blow Your Kid’s Mind. AppReal- VR [Blog]. Retrieved from https://appreal-vr.com/blog/10-best-augmented-reality-books/

Mahayuddin, Z., & Mamat, Z. (2019). Implementing augmented reality (AR) on phonics based literacy among children with autism. International Journal on Advanced Science Engineering Information Technology 9 (6). Retrieved from https://core.ac.uk/download/pdf/296918932.pdf

Oddone, K. (2019). Even better than the real thing? Virtual and augmented reality in the school library. SCIS Connections. (110). Retrieved from https://www.scisdata.com/media/1921/scis-connections-110.pdf

Saidin, N. Abd Halim, N., & Yahaya, N. (2015). A review of research on augmented reality in education: Advantages and applications. International Education Studies, 8(13). Retrieved from http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.730.8456&rep=rep1&type=pd

Rafiq, K., & Hashim, H. (2018) Augmented reality game (ARG), 21st century skills and ESL classroom. Journal o fEducational and Learning Studies. 1 (1) pp29-34. Retrieved from https://journal.redwhitepress.com/index.php/jels/article/view/23/pdf

Riva, G., Banos, R., Botella, C., Mantovani, F., & Gaggioli, A. (2016). Transforming experience: The potential of augmented reality and virtual reality for enhancing personal and clinical change. Frontiers in Psychiatry 7. Retrieved from https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5043228/pdf/fpsyt-07-00164.pdf

Wu, H., Lee, S., Chang, H., & Liang, J. (2013). Current status, opportunities and challenges of augmented reality in education. Computers & Education, 62. Pp41-49. Retrieved from https://doi.org/10.1016/j.compedu.2012.10.024

Zak, E. (2014). Do you believe in magic? Exploring the conceptualisation of augmented reality and its implication for the user in the field of library and information science.  Information Technology and Libraries

 

Augmented Reality in the classroom – Part 2

AR APPLICATIONS IN CLASSROOMS – Part 2 

The interactive and innovative nature of technology has often been cited as a positive influence on educational outcomes, and this benefit extends to the inclusion of AR in schooling (Oddone, 2019).   AR can be used to improve student engagement, address curriculum outcomes and increase digital literacy skills (Oddone, 2019; Saidin, Abd Hali & Yahaya, 2015).   It can be used in inquiry learning, recreational and informational reading, improving literacy and numeracy standards, developing STEM and ICT skills, supporting literary arts, visual arts and developing social emotional learning (Saidin, Abd Hali & Yahaya, 2015).  Like VR, AR expands learning beyond the textbook and classroom walls, as well as builds those critical digital literacy skills for life beyond the classroom (Wolz, 2019, p.3; Wu et al., 2014). 

The most sizable and unique benefit AR has on educational practices is that it uses 3D images to illustrate complex concepts to students (Zak, 2014).  By creating these images, AR enables the student to feel a sense of immediacy and immersion which fosters a realistic experience (Wu et al., 2013, p.44).  This realistic experience increases the frequency and depth of connections made between the student, the content and the real world (Hannah, Huber & Matei, 2019, p.278; Wu et al., 2013).  AR requires the user to activate the augmented data, therefore it can be described as student centred, contextual to the user and is a constructivist approach to education, and consequently aligns itself along the current prevalent pedagogical theories (Wolz, 2019, p.2; Zak, 2014).   Hence, when combined with holistic and authentic learning practices, AR has an immense capability to inspire affective learning. 

REFERENCES

Hannah, M., Huber, S., & Matei, S. (2019). Collecting virtual and augmented reality in the twenty first century library. Collection Management, 44 (2-4), pp.277-295. DOI: 10.1080/01462679.2019.1587673

Oddone, K. (2019). Even better than the real thing? Virtual and augmented reality in the school library. SCIS Connections. (110). Retrieved from https://www.scisdata.com/media/1921/scis-connections-110.pdf

Saidin, N. Abd Halim, N., & Yahaya, N. (2015). A review of research on augmented reality in education: Advantages and applications. International Education Studies, 8(13). Retrieved from http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.730.8456&rep=rep1&type=pdf

Wolz, K. (2019). Building faculty competence and self efficacy for using ZSpace virtual reality (VR) software in the classroom. All Regis University Theses. Retrieved from https://epublications.regis.edu/cgi/viewcontent.cgi?article=1930&context=theses

Wu, H., Lee, S., Chang, H., & Liang, J. (2013). Current status, opportunities and challenges of augmented realiy in education. Computers & Education, 62. Pp41-49. Retrieved from https://doi.org/10.1016/j.compedu.2012.10.024

Zak, E. (2014). Do you believe in magic? Exploring the conceptualisation of augmented reality and its implication for the user in the field of library and information science.  Information Technology and Libraries.

Augmented Reality in the classroom- Part 1

zedinteractive / Pixabay

The technology revolution, pervasive use of the internet and plethora of personal devices have changed the way society engages in employment, recreation, education and personal endeavours.

Educators need to keep abreast of emerging technologies so that they can ensure students possess the necessary digital skills and strategies to thrive in the 21st century  (Wolz, 2019).  Emanating software such as augmented and virtual reality are being trialed by many teachers seeking methods in which to improve engagement, bolster ICT acuity and meet the needs of the modern student.  This article seeks to define AR, identify its role in pedagogical practice, role in meeting curriculum outcomes, and inferences of future applications.  

WHAT IS AR 

Augmented reality (AR) is when a computer generated layer of information is placed over a person’s experience of the world (Townsdin & Whitmer, 2017; Oddone, 2019).  Wu, Lee, Chang & Liang (2013) define AR as technology that uses accurate 3D visual representations to combine real with virtual worlds.  Generally viewed using mobile device applications or wearable computers, AR displays the augmented media in the form of images, sounds, videos, graphics or GPS data (Townsdin & Whitmer, 2017; Wu et al. 2013). At this point, AR is already in use within military machinery, theatre, flight navigation, entertainment industry and various mobile applications, i.e. Pokemon Go (Pope, 2018a; Townsdin & Whitmer, 2017).  There are two forms of AR.  The first  form is when an interaction is stimulated between an image and a smart device, and the second is when the GPS triggers the digital information over the user’s location (Oddone, 2019, p.3).  Whereas virtual reality (VR) is when a user is completely immersed into an artificial world with the aid of technology (Oddone, 2019).  This technology has the ability to flood the senses and trick the mind into believing that the user is actually experiencing the event.  

AR resources are activated by an application that ‘reads’ a QR code, image or illustration so that the interactive content is released.   Levski (2018) points out that this added material could be as simple as a hidden photo or video, but could also be animated sequences or even an embedded game.  The addition of these interactive elements is based upon the gamification principle, which relies on positive feedback to keep students motivated.  By supporting interaction between the real and virtual world, AR allows the user to actively manipulate a tangible interface and thus increase the learner engagement and boost information retention (Saidin, Abd Hali & Yahaya, 2015; Wolz, 2019).  This interaction means that AR is self paced, promotes independent learning and allows students to progress at their own cognitive capabilities.  There is great potential for AR in educational practices, it can be embedded into print or digital resources, used across disciplines, and its multimodal nature gives diverse learners multiple entry points into the content (Levski, 2018).  

References:

Levski, Y. (2018). 10 Augmented Reality Books That Will Blow Your Kid’s Mind. AppReal- VR [Blog]. Retrieved from https://appreal-vr.com/blog/10-best-augmented-reality-books/

Oddone, K. (2019). Even better than the real thing? Virtual and augmented reality in the school library. SCIS Connections. (110). Retrieved from https://www.scisdata.com/media/1921/scis-connections-110.pdf

Pope, H. (2018a). Virtual and augmented reality in libraries. Library Technology Reports – American Library Association, (54)6.

Saidin, N. Abd Halim, N., & Yahaya, N. (2015). A review of research on augmented reality in education: Advantages and applications. International Education Studies, 8(13). Retrieved from http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.730.8456&rep=rep1&type=pdf

Townsdin, S., & Whitmer, W. (2017). Technology. Public Services Quarterly. 13. Pp190-199. DOI: 10.1080/15228959.2017.1338541

Wolz, K. (2019). Building faculty competence and self efficacy for using ZSpace virtual reality (VR) software in the classroom. All Regis University Theses. Retrieved from https://epublications.regis.edu/cgi/viewcontent.cgi?article=1930&context=theses

Wu, H., Lee, S., Chang, H., & Liang, J. (2013). Current status, opportunities and challenges of augmented realiy in education. Computers & Education, 62. Pp41-49. Retrieved from https://doi.org/10.1016/j.compedu.2012.10.024

Location Learning – Virtual reality in the classroom.

When COVID-19 ruins your plans!

The group of Year 8 students had just finished a unit of work on the history of the Catholic Church from the fall of Rome to the Reformation as part of their Religious Education subject (Curriculum link – ACDSEH052/ ACDSEH054).  At the culmination of the semester, they were supposed to go on an excursion to explore the various different Christian churches and analyse how their structure, design, and use of symbols support faith based practices (Curriculum link – ACAVAM119/ACHASSK198). 

However, the COVID-10 pandemic and resulting restrictions prevented that adventure.  Therefore, in an effort to address the gap in their learning, the teacher librarian and classroom teacher collaborated to create a lesson that would virtually explore various churches by introducing emerging technologies in the form of virtual reality to the classroom with Google Cardboard and Google Streetview.  In the process students would learn essential note taking skills using a graphic organiser and paragraph writing skills.   Evidence of learning would be the written TEXAS or TEEL paragraph illustrating their analysis of the building structure and design and how it supports faith practices and community. 

Rosenblatt’s reader response theory was the underlying pedagogical principle for this activity (Woodruff & Griffin, 2017, p.110).  Commonly used in literature circles, Rosenblatt’s constructivist theory acknowledges each student’s contribution as valid, which enables them to become active agents in their own learning, and the activity appropriate for a diverse classroom (Woodruff & Griffin, 2017, p.109-110).  However, instead of investigating texts in a literature circle, the students investigated and analysed religious sites in a similar immersive experience.  This virtual exploration required them to combine the new visual information to their own prior experience in order to create new knowledge (Woodruff & Griffin, 2017, p.111).  The collaborative atmosphere allows students to have an equal exchange of ideas, increases their problem solving skills as well as developing interpersonal skills and promotes collegian discussion  (ACARA, 2014a; Tobin, 2012, p. 41).  

The students were given a choice of six different churches to visit and had to select three for comparison purposes.  As location was no longer an issue, the TL identified a variety of churches from different Christian denominations across the world that were suitable.  It is important that careful research be undertaken to ensure that the sites are accessible freely via Google Streetview and the associated images provide relevant information.  

The students were requested to note down the similarities and differences between the different types of churches using a triple venn diagram.  This part of the task involved student collaboration and ideally students would have selected a different church site each and then shared their information through discourse.  However this did not happen as the students all looked at sites sequentially rather concurrently, which was a poor use of time from a teacher perspective, but did increase the length and breadth of discourse.  

Teaching note taking and the use of graphic organisers simultaneously was a pedagogical strategy.  Note taking is an essential skill that needs to be explicitly taught across the curriculum as the style of note taking and vocabulary choice will vary depending on the discipline.  Good note takers have generally higher academic outcomes because they are able to succinctly summarise ideas, concepts and information using their own vernacular, and then use their notes to create content to communicate their understanding and analysis (Stacy & Cain, 2015).  Graphic organisers have been proven to improve learning outcomes because it increases connections between ideas, and organises information in a visual and spatial manner (McKnight, n.d.; Mann, 2014).  By utilising the two strategies together, the students are given an opportunity to explore different methods of learning which they can use throughout their learning both in and outside classroom walls.  

Good notes lead to a strong author’s voice and content in paragraphs.  The culmination of the task required students to create a paragraph identifying and describing the structure of the church and its alignment to faith based practices, as well as evaluating how the design of the church’s spiritual and aesthetic design holds value to their congregation and society.   The question was created using Bloom’s taxonomy of cognitive domains so that all the diverse learning needs of the class would be catered for appropriately (Kelly, 2019b). 

Questions are an intrinsic and ancient practice of teaching (Tofade, Elsner & Haines, 2013).  Carefully designed questions are all features of good pedagogical practice and are able to, stimulate thinking, promote discourse, further connections between prior and new knowledge as well as encourage subject exploration. (Tofade et al., 2013).  Teachers that stage questions in order of Bloom’s taxonomy are addressing all the cognitive domains, as well as building students to achieve that higher order thinking (Tofade et al., 2013).  

The virtual exploration of churches around the world was designed to compensate students for their inability to connect their learning to the real world to the pandemic.  The task overtly sought to get students to experiment with emerging technologies, work in collaborative groups and communicate their learning in written form.  In addition students covertly learned to note take using graphic organisers, engage in collegial discourse and use Bloom’s taxonomy to work toward higher order thinking.  These skills are in addition to the content learning outcomes and even if the students did not learn any new content, they had a good crack at learning some valuable skills!  

Curriculum links:

Overall content outcomes:

  • ACDSEH052Dominance of the Catholic Church and the role of significant individuals such as Charlemagne
  •  ACDSEH054Relationships with subject peoples, including the policy of religious tolerance 
  • ACAVAM119Analyse how artists use visual conventions in artworks
  • ACTDIP026 – Analyse and visualise data using a range of software to create  information, and use structured data to model objects or events 
  • ACHASSK198 – Identify the different ways that cultural and religious groups express their beliefs, identity and experiences
  • ACELA1763 – writing structured paragraphs for use in a range of academic settings such as paragraph responses, reports and presentations. 
  • ACELY1810 – Experimenting with text structures and language features to refine and clarify ideas and improve text effectiveness. 

                   (ACARA, 2014h; ACARA, 2014i; ACARA, 2014j)

Using VR

  • GC – ICT -Locate, generate and access data and information  
  • GC – CCT –  Identify and clarify information and ideas
  • GC – Literacy – Understanding how visual elements create meaning (ACARA, 2014c; ACARA, 2014b; ACARA, 2014h)

Graphic organisers

  • GC – CCT – 
    • Organise and process information
    • Imagine possibilities and connect ideas                (ACARA, 2014b)

Collaborative Learning groups

  • GC – PSC
    • Appreciate diverse perspectives
    • Understand relationships
    • Communicate effectively
    • Work collaboratively
    • Negotiate and resolve conflict

                                   (ACARA, 2014d)

TEXAS Paragraph

GC – IC – 

  • Investigate culture and cultural identity
  • Explore and compare cultural knowledge, beliefs and practices

GC – Literacy 

  • Compose spoken, written, visual and multimodal learning area texts
  • Use language to interact with others
  • Use knowledge of text structures
  • Express opinion and point of view
  • Understand learning area vocabulary

(ACARA, 2014f; ACARA, 2014c)

REFERENCES

ACARA. (2014a). Personal and social capability. General Capabilities Curriculum.  Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/f-10-curriculum/general-capabilities/personal-and-social-capability/

ACARA. (2014b). Creative and critical thinking continuum.  F-10 Curriculum – General Capabilities Curriculum. Educational Services Australia.  Retrieved from  https://www.australiancurriculum.edu.au/media/1072/general-capabilities-creative-and-critical-thinking-learning-continuum.pdf

ACARA. (2014c). Literacy continuum. F-10 Curriculum – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/media/3596/general-capabilities-literacy-learning-continuum.pdf

ACARA. (2014d). Personal and social capabilities continuum. F-10 Curriculum – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/media/1078/general-capabilities-personal-and-social-capability-learning-continuum.pdf

ACARA. (2014e). Ethical understanding continuum. F-10 Curriculum – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/media/1073/general-capabilities-ethical-understanding-learning-continuum.pdf

ACARA. (2014f). Intercultural understanding continuum. F-10 Curriculum – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/media/1075/general-capabilities-intercultural-understanding-learning-continuum.pdf

ACARA. (2014h). Information and communication technology capability learning continuum. F-10 – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/media/1074/general-capabilities-information-and-communication-ict-capability-learning-continuum.pdf

ACARA. (2014h). English. F-10 – General Capabilities Curriculum. Educational Services Australia. Retrieved from https://www.australiancurriculum.edu.au/f-10-curriculum/english/?strand=Language&strand=Literature&strand=Literacy&capability=ignore&priority=ignore&year=11582&elaborations=true&el=15718&searchTerm=TEEL+paragraph#dimension-content

ACARA. (2014i). History Curriculum. F-10 Curriculum – Humanities and Social Sciences Curriculum. Educational Services Australia. . Retrieved from https://www.australiancurriculum.edu.au/f-10-curriculum/humanities-and-social-sciences/history/

ACARA. (2014j). Visual Arts Curriculum. F-10 Curriculum – Humanities and Social Sciences Curriculum. Educational Services Australia. . Retrieved from https://www.australiancurriculum.edu.au/f-10-curriculum/the-arts/visual-arts/

Kelly, M. (2019a). Organising compare-contrast paragraphs. ThoughtCo [Blog]. Retrieved from https://www.thoughtco.com/organizing-compare-contrast-paragraphs-6877

Kelly, M. (2019b). Bloom’s taxonomy in the classroom. ThoughtCo [Blog]. Retrieved from https://www.thoughtco.com/blooms-taxonomy-in-the-classroom-8450

Mann, M (2014). The effectiveness of graphic organisers on the comprehension of social studies content by students with disabilities. Marshall University Theses, Dissertations and Capstones. Retrieved from https://mds.marshall.edu/cgi/viewcontent.cgi?referer=&httpsredir=1&article=1895&context=etd

McKnight, M. (n.d.). Use graphic organisers for effective learning. TeachHUB.com. Retrieved from https://www.teachhub.com/teaching-graphic-organizers

Stacy, E., & Cain, J. (2015). Note taking and handouts in the digital age. American Journal of Pharmaceutical Education (79) 7. Retrieved from https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4812780/

Tobin, M. (2012). Digital storytelling: Reinventing literature circles. Fischer College of Education. 12. NSU. Retrieved from https://nsuworks.nova.edu/cgi/viewcontent.cgi?article=1000&context=fse_facarticles

Tofade, T., Elsner, J., Haines, S. (2013). Best practice strategies for effective use of questions as a teacher tool. American Journal of Pharmaceutical Education 77 (7). Retrieved from https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3776909/.

Woodruff, A., & Griffin, R. (2017). Reader response in secondary settings: Increasing comprehension through meaningful interactions with literary texts. Texas Journal of Literacy Education (5) 2 pp.108-116. Retrieved from https://files.eric.ed.gov/fulltext/EJ1162670.pdf