An easy to use GUI for simulating big data using Tennessee Eastman process. Andersen, E. B., Udugama, I. A., Gernaey, K. V., Khan, A. R., Bayer, C., & Kulahci, M. Quality and Reliability Engineering International, 38(1):264–282, 2022. _eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/qre.2975
An easy to use GUI for simulating big data using Tennessee Eastman process [link]Paper  doi  abstract   bibtex   
Data-driven process monitoring and control techniques and their application to industrial chemical processes are gaining popularity due to the current focus on Industry 4.0, digitalization and the Internet of Things. However, for the development of such techniques, there are significant barriers that must be overcome in obtaining sufficiently large and reliable datasets. As a result, the use of real plant and process data in developing and testing data-driven process monitoring and control tools can be difficult without investing significant efforts in acquiring, treating, and interpreting the data. Therefore, researchers need a tool that effortlessly generates large amounts of realistic and reliable process data without the requirement for additional data treatment or interpretation. In this work, we propose a data generation platform based on the Tennessee Eastman Process simulation benchmark. A graphical user interface (GUI) developed in MATLAB Simulink is presented that enables users to generate massive amounts of data for testing applicability of big data concepts in the realm of process control for continuous time-dependent processes. An R-Shiny app that interacts with the data generation tool is also presented for illustration purposes. The app can visualize the results generated by the Tennessee Eastman Process and can carry out a standard fault detection and diagnosis studies based on PCA. The data generator GUI is available free of charge for research purposes at https://github.com/dtuprodana/TEP.
@article{andersen_easy_2022,
	title = {An easy to use {GUI} for simulating big data using {Tennessee} {Eastman} process},
	volume = {38},
	issn = {1099-1638},
	url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/qre.2975},
	doi = {10.1002/qre.2975},
	abstract = {Data-driven process monitoring and control techniques and their application to industrial chemical processes are gaining popularity due to the current focus on Industry 4.0, digitalization and the Internet of Things. However, for the development of such techniques, there are significant barriers that must be overcome in obtaining sufficiently large and reliable datasets. As a result, the use of real plant and process data in developing and testing data-driven process monitoring and control tools can be difficult without investing significant efforts in acquiring, treating, and interpreting the data. Therefore, researchers need a tool that effortlessly generates large amounts of realistic and reliable process data without the requirement for additional data treatment or interpretation. In this work, we propose a data generation platform based on the Tennessee Eastman Process simulation benchmark. A graphical user interface (GUI) developed in MATLAB Simulink is presented that enables users to generate massive amounts of data for testing applicability of big data concepts in the realm of process control for continuous time-dependent processes. An R-Shiny app that interacts with the data generation tool is also presented for illustration purposes. The app can visualize the results generated by the Tennessee Eastman Process and can carry out a standard fault detection and diagnosis studies based on PCA. The data generator GUI is available free of charge for research purposes at https://github.com/dtuprodana/TEP.},
	language = {en},
	number = {1},
	urldate = {2022-05-02},
	journal = {Quality and Reliability Engineering International},
	author = {Andersen, Emil B. and Udugama, Isuru A. and Gernaey, Krist V. and Khan, Abdul R. and Bayer, Christoph and Kulahci, Murat},
	year = {2022},
	note = {\_eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/qre.2975},
	keywords = {chemical process, digitalization, industry 4.0, process monitoring and control, process simulator, process surveillance},
	pages = {264--282},
}

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