2005
DOI: 10.1021/ie048872n
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Solving Kinetic Inversion Problems via a Physically Bounded Gauss−Newton (PGN) Method

Abstract: An iterative physically bounded Gauss-Newton (PGN) method has been formulated to estimate unknown kinetic parameters from experimental measurements. A physically bounded approach is adopted to reduce the size of the search space and ensure search within physically meaningful ranges of kinetic rates. First-order sensitivity information of state variables, with respect to unknown rate parameters, is computed simultaneously with the integration of the governing ordinary differential equations (ODEs). Optimal kine… Show more

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Cited by 36 publications
(34 citation statements)
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“…(1) which we implemented with non-linear constrained optimization algorithms developed by our group. 69,79,80 The resulting network is an acyclic binary graph composed of cylindrical elements, where N is the number of segments belonging to the tree.…”
Section: Methodsmentioning
confidence: 99%
“…(1) which we implemented with non-linear constrained optimization algorithms developed by our group. 69,79,80 The resulting network is an acyclic binary graph composed of cylindrical elements, where N is the number of segments belonging to the tree.…”
Section: Methodsmentioning
confidence: 99%
“…It is well-known that multiple solutions may exist with equal error margins (Tang et al, 2005; Vajda and Rabitz, 1988; Zsely et al, 2004). Various combinations of parameters can fit the experimental data equally well within the experimental uncertainty, or some of the parameters may be interdependent.…”
Section: Discussionmentioning
confidence: 99%
“…In fact, the parameters of the model can be determined only if the sensitivity coefficients are non-zero and linearly independent (Beck and Arnold, 1977). More rigorously, Tang et al (2005) used the “physically bounded Gauss-Newton” (PGN) method by utilizing the sensitivity matrix as a global map to determine the unknown kinetic parameters of complex reaction networks that contain dozens of species and hundreds of reactions.…”
Section: Introductionmentioning
confidence: 99%
“…Encouragingly, the subject of model optimization has become more ''acceptable'' in recent years, as evidenced by the rising number of publications of new optimization [72,73] and error-analysis [48,49,74] methods for extracting kinetic information from experimental observations. Recent efforts of Ruscic and co-workers on ''Active Thermochemical Tables'' [75] and of Frenkel and co-workers on ''ThermoData Engine'' [76] corroborate further the benefits of global multidataset optimization.…”
Section: Gri-mechmentioning
confidence: 99%