Title :
Evolutionary identification of nonlinear parametric models with a set-theoretic fitness criterion
Author :
Jinyao Yan ; Deller, J.R. ; Fleet, B.D. ; Goodman, E.D. ; Meng Yao
Author_Institution :
Dept. Elec. & Comput. Eng., Michigan State Univ., East Lansing, MI, USA
Abstract :
System models that are linear in parametric structure, but arbitrarily nonlinear in signal operations, are identified using an approach with two novel components. The fundamental parameter estimation task (the “linear” part) uses a set-theoretic analysis of the data to deduce feasible sets of solutions in light of certain model assumptions. In turn, measurable set solution properties are used to assess the viability of nonlinear regressor functions that compete for “survival” as components of the model best fit to represent the system. The solution is formulated as a somewhat unconventional exercise in evolutionary computation.
Keywords :
evolutionary computation; parameter estimation; regression analysis; set theory; signal processing; evolutionary identification; linear part; nonlinear parametric models; nonlinear regressor functions; parameter estimation task; set-theoretic fitness criterion; signal operations; Biological cells; Biological system modeling; Computational modeling; Estimation; Evolutionary computation; Mathematical model; Signal processing; evolutionary computation; nonlinear models; parameter estimation; set-membership identification;
Conference_Titel :
Signal and Information Processing (ChinaSIP), 2013 IEEE China Summit & International Conference on
Conference_Location :
Beijing
DOI :
10.1109/ChinaSIP.2013.6625294
