APPLICATION OF THE AUGMENTED REALITY IN PRODUCTION PRACTICE
Dariusz PLINTA
dplinta@ath.bielsko.plUniversity of Bielsko-Biala, Production Engineering Department, Willowa 2, 43-309 Bielsko-Biała (Poland)
Martin KRAJČOVIČ
University of Žilina, Industrial Engineering Department, Univerzitná 1, 010 26 Žilina, Slovak Republic, (Slovakia)
Abstract
Current requirements which are connected with designing new, or reali-zing the existing production systems, cause continuous and rapid changes in products and processes. This means that classical approaches of pro-duction systems design have to be extended by advanced technologies and methods, such as digital factory, virtual and augmented reality, computer simulation, reverse engineering, etc. The article describes new computer technologies, which were applied in production practice, with a particular focus on the augmented reality technology.
Keywords:
augmented reality, digital factoryReferences
Azuma, R.T. (1997). A Survey of Augmented Reality. Teleoperators and Virtual En-vironments, 6, 355–385.
DOI: https://doi.org/10.1162/pres.1997.6.4.355
Google Scholar
Bajana, J. (2013). Innovative presentation of information using augmented reality. In L. Dulina (Ed.), Advanced Industrial Engineering (pp. 155-170). Bielsko-Biala: FCNT.
Google Scholar
Brzeziński, M. (2007). Wprowadzenie do nauki o przedsiębiorstwie. Warszawa: Difin. Dulina, Ľ., & Smutná, M. (2010). Methods and software support in industrial ergonomics. Zilina: Slovenská ergonomická spoločnosť (SES).
Google Scholar
Furmann, R., & Krajčovič, M. (2009). Interactive 3D Design of Production Systems. In Digital Factory 2009 – Workshop Handbook. Zilina: SLCP.
Google Scholar
Gabajová, G. (2013). Picking process using augmented reality. In L. Dulina (Ed.), Advanced Industrial Engineering (pp. 41–66). Bielsko-Biala: FCNT.
Google Scholar
Gabajová, G., Krajčovič, M., & Plinta, D. (2013). Navigation with augmented reality. In InvEnt 2013 – modern technologies - way to higher productivity. Zilina: University of Zilina, EDIS.
Google Scholar
Gregor, M., Medvecký, Š., Mičieta, B., Matuszek, J., & Hrčeková, A. (2007). Digital Factory. Zilina: KRUPA print.
Google Scholar
Gregor, M., Plinta, D., Furman, R., & Štefánik, A. (2011). Digital factory – 3d laser scanning, modelling and simulation of production processes. In J. Matuszek, M. Gregor,n & B. Mičieta (Eds.), Metody i techniki zarządzania w inżynierii produkcji (pp.39-50). Bielsko-Biała: Wydawnictwo Akademii Techniczno-Humanistycznej.
Google Scholar
Haas, W. (2004). AK-Digitale Fabrik. Bericht Roadmap. Ingolstadt: Audi.
Google Scholar
Januszka, M. (2012). Projektowanie ergonomiczne z zastosowaniem technik poszerzonej rzeczywistości. In. XI Forum Inżynierskiego ProCAx, 2–4.10.2012.
Google Scholar
Krajčovič, M. (2011). Projektovanie výrobných dispozícií s podporou rozšírenej reality. In Produktivita a inovácie (pp. 27–29). Zilina: University of Zilina.
Google Scholar
Mirandová, G., & Gabaj, I. (2011). Use of augmented reality in storing and picking components from warehouse. In J. Matuszek, M. Gregor, & B. Mičieta (Eds.), Metody i techniki zarządzania w inżynierii produkcji. Bielsko-Biała: Wydawnictwo Akademii Techniczno-Humanistycznej.
Google Scholar
Plinta, D., & Krajčovič, M. (2015). Production systems designing with the use of digital factory and augmented reality technologies. In R. Szewczyk, C. Zieliński, & M. Kaliczyńska (Eds.), Progress in automation, robotics and measuring techniques: control and automation (pp. 187–196). Cham, Heidelberg: Springer.
DOI: https://doi.org/10.1007/978-3-319-15796-2_19
Google Scholar
Štefánik, A., & Furmann, R. (2011). Computer simulation – aided designing of production and logistics systems. In: AI magazine - journal about the automotive industry, mechanical engineering and economics (pp. 46–47).
Google Scholar
Westkaemper, E., Bischoff, J., Von Biel, R., & Duerr, M. (2001). Factory Digitalizing – An adapted approach to a digital factory planning in existing factories and buildings, Werkstattstechnik, 91.
Google Scholar
Authors
Dariusz PLINTAdplinta@ath.bielsko.pl
University of Bielsko-Biala, Production Engineering Department, Willowa 2, 43-309 Bielsko-Biała Poland
Authors
Martin KRAJČOVIČUniversity of Žilina, Industrial Engineering Department, Univerzitná 1, 010 26 Žilina, Slovak Republic, Slovakia
Statistics
Abstract views: 68PDF downloads: 7
License
This work is licensed under a Creative Commons Attribution 4.0 International License.
All articles published in Applied Computer Science are open-access and distributed under the terms of the Creative Commons Attribution 4.0 International License.
Most read articles by the same author(s)
- Dariusz Plinta, Katarzyna Radwan, IMPROVING MATERIAL FLOW IN A MODIFIED PRODUCTION SYSTEM , Applied Computer Science: Vol. 19 No. 1 (2023)
- Damian KOLNY, Dorota WIĘCEK, Paweł ZIOBRO, Martin KRAJČOVIČ, APPLICATION OF A COMPUTER TOOL MONITORING SYSTEM IN CNC MACHINING CENTRES , Applied Computer Science: Vol. 13 No. 4 (2017)
- Martin KRAJČOVIČ, Patrik GRZNÁR, UTILISATION OF EVOLUTION ALGORITHM IN PRODUCTION LAYOUT DESIGN , Applied Computer Science: Vol. 13 No. 3 (2017)
- Dariusz Plinta, Karolina Kłaptocz, VIRTUAL REALITY IN PRODUCTION LAYOUT DESIGNING , Applied Computer Science: Vol. 17 No. 1 (2021)
Similar Articles
- Lukas BAUER, Leon STÜTZ, Markus KLEY, BLACK BOX EFFICIENCY MODELLING OF AN ELECTRIC DRIVE UNIT UTILIZING METHODS OF MACHINE LEARNING , Applied Computer Science: Vol. 17 No. 4 (2021)
- Muhammad Hasyimsyah BATUBARA, Awal Kurnia Putra NASUTION , NURMALINA, Fachrur RIZHA, CHATGPT IN COMMUNICATION: A SYSTEMATIC LITERATURE REVIEW , Applied Computer Science: Vol. 20 No. 3 (2024)
- Anitha Rani PALAKAYALA, Kuppusamy P, A QUALITATIVE AND QUANTITATIVE APPROACH USING MACHINE LEARNING AND NON-MOTOR SYMPTOMS FOR PARKINSON’S DISEASE CLASSIFICATION. A HIERARCHICAL STUDY , Applied Computer Science: Vol. 20 No. 3 (2024)
You may also start an advanced similarity search for this article.
