HMI Development Automation with GUI Elements for Object-Oriented Programming Languages Implementation
HMI Development Automation with GUI Elements for Object-Oriented Programming Languages Implementation |
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| © 2022 by IJETT Journal | ||
| Volume-70 Issue-1 |
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| Year of Publication : 2022 | ||
| Authors : Syed Khalid Mustafa, Vladyslav Yevsieiev, Igor Nevliudov, Vyacheslav Lyashenko, Adel R. Alharbi, Wahid Rajeh |
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| DOI : 10.14445/22315381/IJETT-V70I1P215 | ||
How to Cite?
Syed Khalid Mustafa, Vladyslav Yevsieiev, Igor Nevliudov, Vyacheslav Lyashenko, Adel R. Alharbi, Wahid Rajeh, "HMI Development Automation with GUI Elements for Object-Oriented Programming Languages Implementation," International Journal of Engineering Trends and Technology, vol. 70, no. 3, pp. 132-139, 2022. Crossref, https://doi.org/10.14445/22315381/IJETT-V70I1P215
Abstract
In this article, the authors propose a new method for developing a user interface for industrial information visualizations within Industry 4.0. A feature of the developed method is the use of structured Microsoft Excel files to simplify the presentation of the parameters of the interface being developed. In the course of the experiments, the authors showed the easy way of creating new elements of the industrial interface for the users who are not experts in the field of software development.
Keywords
Industry 4.0, Cyber-Physical Production Systems, Additive Cyber Design, HMI, GUI.
Reference
[1] Ugur M. Dilberoglu, BaharGharehpapagh, UlasYaman, MelikDolen. The Role of Additive Manufacturing in the Era of Industry 4.0, Procedia Manufacturing, 11 (2017) 545-554.
[2] Rami Matarneh, SvitlanaMaksymova, ZhannaDeineko, Vyacheslav Lyashenko. Building Robot Voice Control Training Methodology Using Artificial Neural Net, International Journal of Civil Engineering and Technology, 8(10) (2017) 523-532.
[3] Lucas Santos Dalenogare, Guilherme Brittes Benitez, Néstor Fabián Ayala, Alejandro Germán Frank. The expected contribution of Industry 4.0 technologies for industrial performances, International Journal of Production Economics, 204 (2018) 383-394.
[4] Oleksandr Kuzomin, Mohammad Ayaz Ahmad, HryhoriiKots, Vyacheslav Lyashenko, MariiaTkachenko. Preventing of technogenic risks in the functioning of an industrial enterprise, International Journal of Civil Engineering and Technology, 7(3) (2016) 262-270.
[5] Yang Lu. Industry 4.0: A survey on technologies, applications and open research issues, Journal of Industrial Information Integration, 6 (2017) 1-10.
[6] N. Jazdi. Cyber physical systems in the context of Industry 4.0, in 2014 IEEE International Conference on Automation, Quality and Testing, Robotics, Cluj-Napoca, Romania, (2014) 22-24.
[7] László Monostori. Cyber-physical production systems: Roots, expectations and R&D challenges, Procedia CIRP, 17 (2014) 9-13.
[8] P.J. Mosterman, J. Zander. Industry 4.0 as a Cyber-Physical System study, Softw Syst Model, 15 (2016) 17-29.
[9] Jin Ho Kim. A Review of Cyber-Physical System Research Relevant to the Emerging IT Trends: Industry 4.0, IoT, Big Data, and Cloud Computing, Journal of Industrial Integration and Management, 02 (03) (2017).
[10] Jay Lee, Behrad Bagheri, Hung-An Kao. A Cyber-Physical Systems architecture for Industry 4.0-based manufacturing systems, Manufacturing Letters, 3 (2015) 18-23.
[11] Behrad Bagheri, Shanhu Yang, Hung-An Kao, Jay Lee. Cyberphysical Systems Architecture for Self-Aware Machines in Industry 4.0 Environment, IFAC-PapersOnLine, 48(3) (2015) 1622-1627.
[12] SergiiIarovyi, Wael M. Mohammed, Andrei Lobov, Borja Ramis Ferrer, Jose L. Martinez Lastra. Cyber–Physical Systems for Open- Knowledge- Driven Manufacturing Execution Systems, Proceedings of the IEEE, 104(5) (2016) 1142 - 1154.
[13] SvitlanaSotnik, Rami Matarneh, Vyacheslav Lyashenko. System model tooling for injection molding. International Journal of Mechanical Engineering and Technology, 8(9) (2017) 378-390.
[14] M. Ayaz, T. Sinelnikova, S. K. Mustafa, V. Lyashenko. Features of the Construction and Control of the Navigation System of a Mobile Robot, International Journal of Emerging Trends in Engineering Research, 8(4) (2020) 1445-1449.
[15] Jay Lee, Behrad Bagheri, Chao Jin. Introduction to cyber manufacturing, Manufacturing Letters, 8 (2016) 11-15.
[16] Armando W., Bangemann Thomas, Karnouskos Stamatis, DelsingJerker, Stluka Petr, Harrison Robert, Jammes Francois, Martinez Lastra, Jose L. Industrial Cloud-Based Cyber-Physical Systems, Springer International Publishing Switzerland, Springer, Cham. (2014) 245.
[17] Igor Nevliudov, Vladyslav Yevsieiev, Jalal Hasan Baker, M. Ayaz Ahmad, Vyacheslav Lyashenko. Development of a cyber design modeling declarative Language for cyber physical production systems, J. Math. Comput. Sci., 11(1) (2021) 520-542.
[18] SangSu Choi, Gyhun Kang, Chanmo Jun, , Ju Yeon, Lee, Seukjoo Han. Cyber-physical systems: a case study of development for manufacturing industry, International Journal of Computer Applications in Technology, 55(4) (2017) 298-307.
[19] Omid Givehchi, Klaus Landsdorf, Pieter Simoens, Armando Walter Colombo. Interoperability for Industrial Cyber-Physical Systems: An Approach for Legacy Systems, IEEE Transactions on Industrial Informatics, 13(6) (2017) 3370-3378.
[20] Chunyang Yu, Xuanlin Jiang, Shiqiang Yu, Cheng Yang. Blockchain-based shared manufacturing in support of cyber physical systems: concept, framework, and operation, Robotics and Computer-Integrated Manufacturing, 64 (2020).
[21] Armando W. Colombo, StamatisKarnouskos, OkyayKaynak, Yang Shi, Shen Yin. Industrial Cyberphysical Systems: A Backbone of the Fourth Industrial Revolution, IEEE Industrial Electronics Magazine, 11(1) (2017) 6-16.
[22] Paola Fantini, Marta Pinzone, Marco Taisch. Placing the operator at the centre of Industry 4.0 design: Modelling and assessing human activities within cyber-physical systems, Computers & Industrial Engineering, 139 (2020).
[23] Albert T. Jones, David Romero, Thorsten Wuest. Modeling agents as joint cognitive systems in smart manufacturing systems, Manufacturing Letters, 17 (2018) 6-8.
[24] Marie-Pierre Pacaux-Lemoine, Quentin Berdal, Simon Enjalbert, Damien Trentesaux. Towards human-based industrial cyberphysical systems, in 2018 IEEE Industrial Cyber-Physical Systems (ICPS), (2018).
[25] Edward A. Lee. Cyber Physical Systems: Design Challenges, in 2008 11th IEEE International Symposium on Object and Component-Oriented Real-Time Distributed Computing (ISORC), Orlando, FL, USA, (2008).
[26] Amy J. C. Trappey, Charles V. Trappey, UsharaniHareesh Govindarajan, John J. Sun, Allen C. Chuang. A Review of Technology Standards and Patent Portfolios for Enabling Cyber- Physical Systems in Advanced Manufacturing, IEEE Access, 4 (2016) 7356-7382.
[27] Moshev E., Meshalkin V., Romashkin M. Development of Models and Algorithms for Intellectual Support of Life Cycle of Chemical Production Equipment, Cyber-Physical Systems: Advances in Design & Modelling. Studies in Systems, Decision and Control, 259 (2019) 153-165.
[28] Urcun John Tanik. Cyberphysical Design Automation Framework for Knowledge-based Engineering, The International Journal on Multidisciplinary Approaches on Innovation, 1(1) (2013) 158-178.
[29] Igor Nevliudov, Vladyslav Yevsieiev, SvitlanaMaksymova, Inna Filippenko. Development of an architectural-logical model to automate the management of the process of creating complex cyberphysical industrial systems, Eastern-European Journal of Enterprise Technologies, 4 (3(106)) (2020) 44-52.