Simultaneous versus sequential estimation of biogeochemical and physical parameters in coupled marine ecosystem models Journal Article uri icon

Overview

abstract

  • Abstract. As computational resources have increased in availability and capability, so has the complexity of the models used to represent biogeochemical (BGC) processes in ocean simulations. To effectively calibrate the increasingly large number of uncertain parameters in these models, efficient parameter estimation methods are needed to ensure that the models can accurately represent the BGC processes under investigation. In this study, we address this challenge using a multistage automatic parameter estimation methodology that sequentially applies global sampling and local optimization to calibrate both the BGC model parameters and the parameters associated with a one-dimensional physical ocean model. We quantitatively compare the accuracy of sequential and simultaneous parameter estimations of moderately complex BGC and physical models at locations corresponding to the Bermuda Atlantic time series and the Hawaii Ocean time series. The results show that the best overall agreement with the observed mean seasonal cycles is obtained when BGC, advection, boundary condition, and turbulent diffusion parameters are estimated simultaneously, rather than sequentially. Simultaneous estimation of all these parameters results in closer agreement with mean seasonal cycles for oxygen and particulate organic nitrogen. Moreover, the agreement is improved in general when the advection, boundary condition, and turbulent diffusion parameters are included in the estimation, as opposed to calibrating the BGC model alone. This study also serves as a demonstration of a meta-algorithm for parameter estimation in high-dimensional models using a truncated global search with local optimizations.

publication date

  • June 29, 2026

Date in CU Experts

  • July 9, 2026 8:16 AM

Full Author List

  • Kern S; McGuinn ME; Smith KM; Pinardi N; Niemeyer KE; Lovenduski NS; Hamlington PE

author count

  • 7

Other Profiles

Electronic International Standard Serial Number (EISSN)

  • 1991-9603

Additional Document Info

start page

  • 5601

end page

  • 5622

volume

  • 19

issue

  • 12