Journal of Computer Technology & Applications

In recent years, the significance of effectiveness and productivity has grown. Furthermore, the industry has been able to improve production system performance thanks to advances in processing power and advanced analytics. A better understanding of intermediate product stages is therefore required to take the relevant measures. To highlight the importance of this field of study, a study on data-driven probabilistic ML algorithms and their real-time applications to smart energy systems and networks was done. The use of ML in fundamental energy technologies and ML use cases for utilities involved in energy distribution were the two main topics of this study. The purpose of this research is to create a framework for data-driven understanding of the various state propagation inside manufacturing systems in order to increase the transparency of cause-effect linkages linked to product quality. Machine learning algorithms classify items into groups based on their intermediate properties. A research study as within electronic manufacturing sector illustrates how this strategy might be put into practise. Product state propagation along the production process chain may be examined in detail utilising visual analytics tools.

K Cook, R Earnshaw, J Stasko. Guest editors' introduction: Discovering the unexpected. IEEE computer graphics and applications. 2007 Sep 17; 27 (5): 15–19.

H Gebauer, A Gustafsson, L Witell. Competitive advantage through service differentiation by manufacturing companies. Journal of business research. 2011 Dec 1; 64 (12): 1270–1280.

JC Huang. Reducing solder paste inspection in surface-mount assembly through Mahalanobis– Taguchi analysis. IEEE Transactions on Electronics Packaging Manufacturing. 2010 Aug 30; 33(4): 265–274.

HS Kang, JY Lee, S Choi, H Kim, JH Park, JY Son, BH Kim, SD Noh. Smart manufacturing: Past research, present findings, and future directions. International journal of precision engineering and manufacturing-green technology. 2016 Jan; 3 (1): 111–128.

DA Keim, F Mansmann, J Schneidewind, J Thomas, H Ziegler. Visual analytics: Scope and challenges. InVisual data mining 2008 (pp. 76–90). Springer, Berlin, Heidelberg.

J Kohlhammer, D Keim, M Pohl, G Santucci, G Andrienko. Solving problems with visual analytics. Procedia Computer Science. 2011 Jan 1; 7: 117–120.

A Mazeika,. (Eds.), Visual data mining. Theory, techniques and tools for visual analytics, vol. 4404. Springer, Berlin, pp. 76–90.

Thomas, J.J. (Ed.), 2005. Illuminating the path: The research and development agenda for visual analytics. IEEE Computer Soc, Los Alamitos, Calif., 186 pp.

S Thiede. Environmental sustainability of cyber physical production systems. Procedia CIRP. 2018 Jan 1; 69: 644–649.

T Wuest, D Klein, KD Thoben. State of steel products in industrial production processes. Procedia Engineering. 2011 Jan 1; 10: 2220–2225.