TY - JOUR
T1 - Mathematical model for robust control of an irrigation main canal pool
AU - Rivas-Perez, R.
AU - Feliu-Batlle, V.
AU - Castillo-Garcia, F. J.
AU - Linares-Saez, A.
PY - 2014/1
Y1 - 2014/1
N2 - This paper describes the formulation and development of a mathematical model for high-performance robust controller design techniques, based on a complete identification for control procedure, of an irrigation main canal pool (true plant), which is characterized by the exhibition of large variations in its dynamic parameters when the discharge regime changes in the operating range [Qmin, Qmax]. Real-time field data has been used. Four basic steps of the proposed procedure have been defined in which all the stages, from the design of the experiments to the model validation, are considered. This procedure not only delivers a nominal model of the true plant, but also a reliable estimate of its model uncertainty region bounded by the true plant models under minimum and maximum operating discharge regimes (limit operating models). The model uncertainty set, defined by the nominal model and its uncertainty region, is characterized by its being as tight as possible to the true irrigation main canal pool. The obtained results are very promising since this kind of models facilitates the design of robust controllers, which allow improving the operability of irrigation main canal pools and also substantially reduce water losses.
AB - This paper describes the formulation and development of a mathematical model for high-performance robust controller design techniques, based on a complete identification for control procedure, of an irrigation main canal pool (true plant), which is characterized by the exhibition of large variations in its dynamic parameters when the discharge regime changes in the operating range [Qmin, Qmax]. Real-time field data has been used. Four basic steps of the proposed procedure have been defined in which all the stages, from the design of the experiments to the model validation, are considered. This procedure not only delivers a nominal model of the true plant, but also a reliable estimate of its model uncertainty region bounded by the true plant models under minimum and maximum operating discharge regimes (limit operating models). The model uncertainty set, defined by the nominal model and its uncertainty region, is characterized by its being as tight as possible to the true irrigation main canal pool. The obtained results are very promising since this kind of models facilitates the design of robust controllers, which allow improving the operability of irrigation main canal pools and also substantially reduce water losses.
KW - Irrigation canal
KW - Model uncertainty set
KW - Robust controller
KW - Systems identification
KW - Time-varying parameters
KW - Water efficient use
UR - http://www.scopus.com/inward/record.url?scp=84887008994&partnerID=8YFLogxK
U2 - 10.1016/j.envsoft.2013.10.002
DO - 10.1016/j.envsoft.2013.10.002
M3 - Article
AN - SCOPUS:84887008994
SN - 1364-8152
VL - 51
SP - 207
EP - 220
JO - Environmental Modelling and Software
JF - Environmental Modelling and Software
ER -