AUGMENTED REALITY IN INDUSTRY 4.0: ENABLING TECHNOLOGIES AND THE POTENTIAL FOR SMEs

1. AUGMENTED REALITY IN INDUSTRY 4.0:
ENABLING TECHNOLOGIES AND THE
POTENTIAL FOR SMEs
GULAY EKREN
Sinop University
BIRGIT OBERER
Sakarya University
ALPTEKIN ERKOLLAR
Sakarya University

2. Co-workers
Alptekin ERKOLLAR, Phd
Sakarya University, TURKEY
Faculty of Management, Department of Management Information Systems
erkollar@sakarya.edu.tr
Birgit OBERER, Phd
Sakarya University, TURKEY
Faculty of Management, Department of Management Information Systems
oberer@sakarya.edu.tr
Gülay EKREN, Phd Student
Sinop University, TURKEY
Departmant of Computer Technologies, Vocational School of Ayancık
gekren@sinop.edu.tr

3. Introduction
• Industry 4.0 (I4.0)
• I4.0 required
• advanced technologies (e.g. artificial intelligence,
robotics, 3D printing) and business models
• a high level of maturity
• small and medium-sized businesses (SMEs)
• face difficulties in adopting Industry 4.0 ideas
• hesitant to invest in new technologies (QR codes,
RFID tags, AR markers etc.)

4. Introduction
• Augmented Reality (AR)
• plays a significant role in industrial environments
• support and facilitating opportunities for SMEs
• new technologies should be developed for SMEs in
coming years

5. Aims
• Industry 4.0 (I4.0)
• I4.0 required
• advanced technologies (e.g. artificial intelligence,
robotics, 3D printing) and business models
• a high level of maturity
• small and medium-sized businesses (SMEs)
• face difficulties in adopting Industry 4.0 ideas
• hesitant to invest in new technologies (QR codes,
RFID tags, AR markers etc.)
• This study aims
• to introduce industrial AR technologies that
SMEs can use to improve their Industrial 4.0
capabilities
• potentials that facilitate the process of SMEs'
adaptation to Industry 4.0.
• a set of case studies is presented to examine
opportunities of AR technologies for SMEs.

6. SMEsandI4.0
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• Digital transition
• in Europe the initiatives named as "Industrie 4.0"
in Germany, "Catapult" in the United Kingdom,
"Factory of the Future" in France and Italy
• in China, a range of activities named as "Made in
China 2025" initiative
• in the USA, a whole range of federally funded
programs have been initiated to promote
advanced manufacturing

7. SMEsandI4.0
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• SMEs are socially and economically important
• represent 99% of all enterprises as well as
around 65 million employments in the Europe
(http://ec.europa.eu).
Criteria for micro, small or medium-sized enterprises (EC, 2015)

8. Adoptionof
SMEstoI4.0
(Kleindienst & Ramsauer, 2016)2016)

9. Technologies
RelatedtoAR
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• AR markers (e.g. QR code),
• displays and hologram technologies (e.g. head-
mounted devices, glasses),
• mobile devices,
• cloud computing,
• tracking technologies (e.g. GPS, RFID, Infra-red
LEDs),
• interaction technologies (e.g. touch screen,
speech recognition).

10. Technologies
RelatedtoAR
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• AR markers

11. Technologies
RelatedtoAR
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• Displays and Hologram technologies
Elevator maintenance with Microsoft HoloLens
(https://www.youtube.com/watch?v=8OWhGiyR4Ns)

12. Technologies
RelatedtoAR
• Criteria for inclusion; Research should be:
• Conducted in the context of distance higher education
• Examined the effect of openness on distance
education.
• used quantitative, qualitative, mixed or other research
methods.
• providing necessary information for openness in its
abstract.
• Mobile devices and Cloud computing
AR experience using a mobile device
(Speicher et al., 2015)

13. CaseStudies
• Index AR Solutions (http://www.indexarsolutions.com/)
An AR application of Index AR Solutions
(https://www.youtube.com/watch?v=oBzIKZqEGwI)

14. CaseStudies
• AR Solutions of Immersion (http://www.immersion.fr)
An AR tool of Sunna Design
(https://www.youtube.com/watch?v=NIyyb5Jj7tk )

15. CaseStudies
• AR Solutions of VTScada (https://www.trihedral.com/ )
SCADA systems control with HoloLens
(https://www.youtube.com/watch?v=XK_hW_c99Xs)

16. CaseStudies
• The SCS Concept and DMG solutions
(http://scsconcept.com, http://www.dmgsolutions.net/)
A visual production guide for manufacturing
(https://www.youtube.com/watch?v=0m67O1Em7dY)

17. CaseStudies
• Solutions of EquipCodes (http://www.equipcodes.com/)
An AR equipment training & maintenance app
(https://www.youtube.com/watch?v=nHfY56lHZjU)

18. InClosing
• SMEs for Industry 4.0
• There is a high potential,
• a lack of adoption the emerging technologies
• AR technology
• Early enterprise adopters will gain a significant
competitive advantage
• A range of case studies presented here can help
SMEs to add value to their business processes
through AR technology in the vision of Industry 4.0.

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