Gurbir Perhar scite author profile

[1] Large simulation models of eutrophication processes are commonly used to aid scientific understanding and to guide management decisions. Confidence in models for these purposes depends on uncertainty in model equations (structural uncertainty) and on effects of input uncertainties (model parameters, initial conditions, and forcing functions) on model outputs. Our objective herein is to illustrate two strategies, a generalized likelihood uncertainty estimation (GLUE) approach combined with a simple Monte Carlo sampling scheme and a Bayesian methodological framework along with Markov Chain Monte Carlo (MCMC) simulations, for elucidating the propagation of uncertainty in the high-dimensional parameter spaces of mechanistic eutrophication models. We examine the ability of the two approaches to offer insights into the degree of information about model inputs that the data contain, to quantify the correlation structure among parameter estimates, and to obtain predictions along with uncertainty bounds for modeled output variables. Our analysis is based on a four-state-variable (phosphate-detritus-phytoplankton-zooplankton) model and the mesotrophic Lake Washington (Washington State, United States) as a case study. Scientific knowledge, expert judgment, and observational data were used to formulate prior probability distributions and characterize the uncertainty pertaining to 14 model parameters. Despite the conceptual differences for addressing model equifinality, that is, wide ranges of parameter values subject to complex multivariate relationships that result in plausible observed behaviors and produce equivalently accurate predictions, we found that the two strategies provided fairly consistent estimates of the posterior parameter correlation structure and output uncertainty. Nonetheless, our analysis also shows that MCMC can more efficiently quantify the joint probability distribution of model parameters and make inference about this distribution. The latter finding can be explained by the basic idea underlying the MCMC methodology, that is, the configuration of a Markov process whose stationary distribution approximates the joint posterior distribution of all the stochastic model nodes; as a result, Monte Carlo samples are not drawn from the prior parameter space, and problems of wide or highly correlated prior distributions can be overcome. Finally, our study stresses the lack of perfect simulators of natural system dynamics and introduces two statistical formulations that can explicitly account for the discrepancy between mathematical models and environmental systems.

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Modelling the role of highly unsaturated fatty acids in planktonic food web processes: a mechanistic approach

Perhar

Arhonditsis

Brett

2012

Environ. Rev.

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Highly unsaturated fatty acids (HUFAs) are a subgroup of fatty acids characterized by chains of 20 or more carbon atoms with multiple double bonds, which potentially limit the growth of zooplankton. Zooplankton require high HUFA concentrations during periods of rapid growth, but co-limitation with nutrients is also likely to occur. Recent modelling results suggest food webs with high quality (nutritional and biochemical) primary producers can attain inverted biomass distributions with efficient energy transfer between trophic levels. In this study, our objective is to highlight the recent advances in studying the role of HUFAs in aquatic food webs. We take a first-principles approach to investigate the chemical nature of HUFAs, and the role they play in zooplankton ecology. To this end, we introduce a novel zooplankton growth sub model that tracks the interplay between nitrogen, phosphorus, and HUFAs in plankton population models. Our aim is to produce a sub model that incorporates the knowledge gained from decades of biochemical research into management-oriented predictive tools.

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Modelling the role of highly unsaturated fatty acids in planktonic food web processes: Sensitivity analysis and examination of contemporary hypotheses

Perhar¹,

Arhonditsis²,

Brett³

2013

Ecological Informatics

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Gurbir Perhar

Our current understanding of lake ecosystem response to climate change: What have we really learned from the north temperate deep lakes?

Bayesian calibration of mechanistic aquatic biogeochemical models and benefits for environmental management

Addressing equifinality and uncertainty in eutrophication models

Modelling the role of highly unsaturated fatty acids in planktonic food web processes: a mechanistic approach

Modelling the role of highly unsaturated fatty acids in planktonic food web processes: Sensitivity analysis and examination of contemporary hypotheses

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