Differential Games Controllers That Confine a System to a Safe Region in the State Space, With Applications to Surge Tank Control
Surge tanks are units employed in chemical processing to regulate the flow of fluids between reactors. A notable feature of surge tank control is the need to constrain the magnitude of the Maximum Rate of Change (MROC) of the surge tank outflow, since excessive fluctuations in the rate of change of...
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| Veröffentlicht in: | IEEE transactions on automatic control 2012-11, Vol.57 (11), p.2778-2788 |
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| creator | Falugi, P. Kountouriotis, Panagiotis-Aristidis Vinter, R. B. |
| description | Surge tanks are units employed in chemical processing to regulate the flow of fluids between reactors. A notable feature of surge tank control is the need to constrain the magnitude of the Maximum Rate of Change (MROC) of the surge tank outflow, since excessive fluctuations in the rate of change of outflow can adversely affect down-stream processing (through disturbance of sediments, initiation of turbulence, etc.). Proportional + Integral controllers, traditionally employed in surge tank control, do not take direct account of the MROC. It is therefore of interest to explore alternative approaches. We show that the surge tank controller design problem naturally fits a differential games framework, proposed by Dupuis and McEneaney, for controlling a system to confine the state to a safe region of the state space. We show furthermore that the differential game arising in this way can be solved by decomposing it into a collection of (one player) optimal control problems. We discuss the implications of this decomposition technique, for the solution of other controller design problems possessing some features of the surge tank controller design problem. |
| doi_str_mv | 10.1109/TAC.2012.2194335 |
| format | Article |
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| source | IEEE Electronic Library (IEL) |
| subjects | Adaptative systems Aerospace electronics Applied sciences Budgets Computer science control theory systems Control system synthesis Control systems Control theory. Systems Controllers Design engineering Differential games Equations Exact sciences and technology Fluid dynamics Fluid flow Game theory Games Operational research and scientific management Operational research. Management science Optimal control Process control robust control stochastic optimal control Studies Surge tanks Surges Trajectory Turbulent flow |
| title | Differential Games Controllers That Confine a System to a Safe Region in the State Space, With Applications to Surge Tank Control |
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