Welcome to the InfoSci Platform

Reference Hub

This research has been cited in:

Article
A Design and Implementation of a New Control Based on Petri Nets for Three Phase PWM-RectifierInternational Journal of Service Science, Management, Engineering, and Technology10.4018/IJSSMET.326801
Article
Novel Hybrid Genetic Arithmetic Optimization for Feature Selection and Classification of Pulmonary Disease ImagesInternational Journal of Sociotechnology and Knowledge Development10.4018/IJSKD.330150

Subspace Data-Driven Control for Linear Parameter Varying Systems

Jianhong Wang, Yunfeng Zhang, Ricardo A. Ramirez-Mendoza, Ahmad Taher Azar, Ibraheem Kasim Ibraheem, Nashwa Ahmad Kamal, Farah Ayad Abdulmajeed

Source Title: International Journal of Service Science, Management, Engineering, and Technology (IJSSMET)14(1)

ISSN: 1947-959X|EISSN: 1947-9603|EISBN13: 9781668479407|DOI: 10.4018/IJSSMET.321198

Cite Article Cite Article

MLA

Wang, Jianhong, et al. "Subspace Data-Driven Control for Linear Parameter Varying Systems." IJSSMET vol.14, no.1 2023: pp.1-25. http://doi.org/10.4018/IJSSMET.321198

APA

Wang, J., Zhang, Y., Ramirez-Mendoza, R. A., Azar, A. T., Ibraheem, I. K., Kamal, N. A., & Abdulmajeed, F. A. (2023). Subspace Data-Driven Control for Linear Parameter Varying Systems. International Journal of Service Science, Management, Engineering, and Technology (IJSSMET), 14(1), 1-25. http://doi.org/10.4018/IJSSMET.321198

Chicago

Wang, Jianhong, et al. "Subspace Data-Driven Control for Linear Parameter Varying Systems," International Journal of Service Science, Management, Engineering, and Technology (IJSSMET) 14, no.1: 1-25. http://doi.org/10.4018/IJSSMET.321198

Export Reference

Favorite Full-Issue Download

View Full Text HTML

View Full Text PDF

Abstract

In this research, a unique subspace data driven control for linear parameter changing system with scheduling parameters is presented. This control paves the way for investigating the nonlinear system based on the results regarding the linear system that are already known. Only the data matrix is utilized to represent the output prediction value in the future various time instants, while the input-output observation data matrix is used to identify Markov parameters in the form of state space forms. The cost function in data-driven control is then adjusted using the output prediction value. The optimal control input value of this quadratic cost function is solved using a parallel distribution technique, and the algorithm's iterative convergence is thoroughly examined. Finally, the DC motor, whose mass distribution factor is considered to be one linear parameter varying system, is controlled using the suggested subspace data driven control approach.