2007
DOI: 10.1016/j.apnum.2006.07.016
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A comparison of approximation methods for the estimation of probability distributions on parameters

Abstract: In this paper, we compare two computationally efficient approximation methods for the estimation of growth rate distributions in size-structured population models. After summarizing the underlying theoretical framework, we present several numerical examples as validation of the theory. Furthermore, we compare the results from a spline based approximation method and a delta function based approximation method for the inverse problem involving the estimation of the distributions of growth rates in size-structure… Show more

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Cited by 25 publications
(29 citation statements)
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“…[4,8,9,10,15]). However, it was demonstrated in [5] that if the sought-after probability measure is absolutely continuous, then the spline-based approximation methods converge much faster than do the Dirac measure approximation methods (in terms of the value of M). In addition, it was observed in [5] that the spline-based approximation methods also provide convergence for the associated probability density functions while the Dirac measure approximation methods do not do this.…”
Section: Approximation Schemes For Probability Measure Estimationmentioning
confidence: 99%
“…[4,8,9,10,15]). However, it was demonstrated in [5] that if the sought-after probability measure is absolutely continuous, then the spline-based approximation methods converge much faster than do the Dirac measure approximation methods (in terms of the value of M). In addition, it was observed in [5] that the spline-based approximation methods also provide convergence for the associated probability density functions while the Dirac measure approximation methods do not do this.…”
Section: Approximation Schemes For Probability Measure Estimationmentioning
confidence: 99%
“…Cyton models and branching process models have been formulated to account for various levels of correlation [34,45,73], and these models may be incorporated into the compartmental model framework as described above. Alternatively, it may be possible (given any reasonable, identifiable parameterizations of cell division and death) to place probability distributions on these parameters (e.g., on the functions α i (t) and β i (t)) [6,9,12] in the manner described in Section 3.3.…”
Section: Generalizations Of the Mathematical Modelmentioning
confidence: 99%
“…According to mathematical theory (see [14] for proofs), the solutions of (8) converge to the solution of (7) as the number N of uniformly spaced elements in [−7, 0] goes to infinity. When we perform an inverse problem using the delay differential equation model, we need to know how large to take our N so that we obtain accurate estimates of our parameters.…”
Section: Convergence Of Solutionsmentioning
confidence: 99%
“…An alternative approach, "optimize in a function space setting and then discretize for computation," would require as a first step the computation of sensitivity (or gradients) of the original delay system (1) solutions with respect to its function space parameters (especially the probability kernel m). To compute these one might develop a set of sensitivity equations which could then be a basis for an (as yet undeveloped ) infinite dimensional nonlinear asymptotic statistical framework (see [8,9] for some initial efforts in this direction) for the computation of functional "confidence bands" for the estimated functions. This of course would involve infinite dimensional function space versions of the sensitivity and covariance matrices that are fundamental in the finite dimensional asymptotic theory for sampling distributions.…”
Section: An Alternative Sensitivity Analysismentioning
confidence: 99%