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• [1] Kaplanoğlu, E. (2006) Predictive control applications of multi input multi output constrained systems, PhD Thesis, Institute of Pure and Applied Sciences, Marmara University, İstanbul, Turkey.
• [2] Tham, M.T., (1999) Multivariable Control (An Introduction To Decoupling Control), Department of Chemical Process Engineering University of Newcastle, United Kingdom.
• [3] Huang H.P., Jeng J.C., Chiang C.H, Pan W. (2003) A direct method for multi-loop PI/PID controller design, Journal of Process Control 13, 769-786.
• [4] Zhai L., Chai T., Shi Y., (2005) Nonlinear Multivariable Decoupling PID Control Using Neural Networks, International Conference on Neural Networks and Brain, Pekin, 1843-1848.
• [5] Zhai L., Chai T.,(2006) Intelligent Decoupling PID Control of a Class of Complex Industrial Processes, Intelligent Control and Automation, 6(1), 4827-4832.
• [6] Liu T., Zhang W., Gao F., (2007) Analytical decoupling control strategy using a unity feedback control structure for MIMO processes with time delays, Journal of Process Control, 17(2), 173-186.
• [7] Shen Y., Cai W.J., Li S., (2010) Normalized decoupling control for high-dimensional MIMO processes for application in room temperature control HVAC systems, Control Engineering Practice, 18(6), 652-664.
• [8] Vranćic D., (2011) Design of MIMO Controllers with inverted decoupling, 8th Asian Control Conference (ASCC), Taiwan, 1153-1158.
• [9] Garrido J., Vàzquez F., Morilla F., (2011) An extended approach of inverted decoupling, Journal of Process Control, 21(1), 55-68.
• [10] Morilla F., Vàzquez F., Garrido J., (2008) Centralized PID control by decoupling for TITO processes, IEEE International Conference on Emerging Technologies and Factory Automation, Hamburg, 1318-1325.
• [11] Jevtović B. T., Mataušek M. R., (2010) PID controller design of TITO system based on ideal decoupler, Journal of Process Control, 20(7), 869-876.
• [12] Fu Y., Chai T., (2009) Intelligent decoupling control of nonlinear multivariable system and its application to a wind Tunnel System, IEEE Transactions on Control System Technology, 17(6), 1376-1384.
• [13] Tang Y., Wang R., (2009) Decoupling control for nonlinear coupling systems based on CMAC & PID, IEEE International Conference on Cognitive Informatics, Hong Kong, 302-305.
• [14] Wang Y., Pang X., Piao Z., Fang J., Fu J., Chai T., (2015) Intelligent decoupling PID control for the forced-circulation evaporation system, Chinese Journal of Chemical Engineering, 23(12), 2075-2086.
• [15] Garrido J., Lara M., Ruz M. L., Alfaya J. A., (2018) Morilla F. Decentralized PID control with inverted decoupling and superheating reference generation for efficient operation: Application to the Benchmark PID 2018, 3rd IFAC Conference on Advances in Proportional-Integral-Derivative Control PID 2018, 51(4), 710-715.
• [16] Skogestad S., Postlethwaite I., (2005) Multivariable Feedback Control Analysis and Design, 2nd Edition, Wiley, 592.
• [17] Tham, M.T., (1999), Multivariable Control (An Introduction To Decoupling Control), Department of Chemical Process Engineering University of Newcastle, United Kingdom, 19.
• [18] Luyben, W.L., (1970) Distillation decoupling, AIChE Journal, 16(2), 198-203.
• [19] Process automation MPS® PA Compact Workstation Manual, FESTO.
• [20] Vranćic D., (2011) Design of MIMO Controllers with inverted decoupling, 8th Asian Control Conference (ASCC), Taiwan, 1153-1158.
• [21] Ziegler, J. G., Nichols, N. B., (1942) Optimum Settings for Automatic Controllers, Transactions of the A.S.M.E, 759-768.
• [22] Üstüner M.A., Taşkın S., (2015) Decoupling Of Multi-Input Multi-Output Systems: A Process Control System Application, CBU Journal of Science, 11(2), 225-231.