Sensitivity Functions and Their Uses in Inverse Problems

Banks, Harvey Thomas; Dediu, Sava; Ernstberger, Stacey L.

doi:10.21236/ada471254

Cited by 34 publications

(51 citation statements)

References 23 publications

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“…For the last few values of t f , the error does appear to exhibit an increasing trend, possibly due a lack of sufficient resolution in time. This result is consistent with the literature [11, 52, 75] in that the size and resolution of the observation interval can have a substantial effect on identifiability of parameters. For instance, Thomaseth and Cobelli [75] developed generalized sensitivity functions that can be used for the qualitative analysis of the impact of the observation intervals on identifiability of parameters in dynamical systems.…”

Section: Application To Flocculation Equationssupporting

confidence: 92%

“…These sensitivity functions help to identify the most relevant data and time subdomains for identification of certain parameters. Later, Banks et al [12, 13] offered a quantitative means to choose the duration t f required for an optimal experiment design. Moreover, Keck and Bortz [52], provided an extension of this sensitivity functions to the size-structured population models.…”

Section: Application To Flocculation Equationsmentioning

confidence: 99%

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An inverse problem for a class of conditional probability measure-dependent evolution equations

2016

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We investigate the inverse problem of identifying a conditional probability measure in measure-dependent evolution equations arising in size-structured population modeling. We formulate the inverse problem as a least squares problem for the probability measure estimation. Using the Prohorov metric framework, we prove existence and consistency of the least squares estimates and outline a discretization scheme for approximating a conditional probability measure. For this scheme, we prove general method stability. The work is motivated by Partial Differential Equation (PDE) models of flocculation for which the shape of the post-fragmentation conditional probability measure greatly impacts the solution dynamics. To illustrate our methodology, we apply the theory to a particular PDE model that arises in the study of population dynamics for flocculating bacterial aggregates in suspension, and provide numerical evidence for the utility of the approach.

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Section: Application To Flocculation Equationssupporting

confidence: 92%

Section: Application To Flocculation Equationsmentioning

confidence: 99%

An inverse problem for a class of conditional probability measure-dependent evolution equations

2016

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“…In this frame the Fisher information matrix becomes

F_{i j} (T, θ) = \int_{0}^{T} \frac{1}{v^{2} false(t false)} \frac{\partial h false(t, θ false)}{\partial θ_{i}} \frac{\partial h false(t, θ false)}{\partial θ_{j}} d P (t)

and its inverse is, asymptotically and approximately, the covariant matrix of the estimator

\overset{θ}{true}

of θ. The generalized sensitivity at t ∈ [0, T ] is the diagonal of

F {(P, θ_{0})}^{- 1} F (P_{[0, t]}, θ_{0})

(see Banks et al, 2008). …”

Section: Methodsmentioning

confidence: 99%

“…They can help to determine the time instants where the output of a dynamical system has more information about the value of its parameters in order to carry on an estimation process. Both functions were considered by some authors who compared their results for different dynamical systems (see Banks and Bihari, 2001; Kappel and Batzel, 2006; Banks et al, 2008). In this work we apply the TSF and the GSF to analyze the sensitivity of the 3D Poisson-type equation with interfaces of the forward problem of electroencephalography.…”

mentioning

confidence: 99%

Sensitivity Analysis for the EEG Forward Problem

Troparevsky¹,

Rubio²,

Saintier³

2010

Front. Comput. Neurosci.

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Sensitivity analysis can provide useful information when one is interested in identifying the parameter θ of a system since it measures the variations of the output u when θ changes. In the literature two different sensitivity functions are frequently used: the traditional sensitivity functions (TSF) and the generalized sensitivity functions (GSF). They can help to determine the time instants where the output of a dynamical system has more information about the value of its parameters in order to carry on an estimation process. Both functions were considered by some authors who compared their results for different dynamical systems (see Banks and Bihari, 2001; Kappel and Batzel, 2006; Banks et al., 2008). In this work we apply the TSF and the GSF to analyze the sensitivity of the 3D Poisson-type equation with interfaces of the forward problem of electroencephalography. In a simple model where we consider the head as a volume consisting of nested homogeneous sets, we establish the differential equations that correspond to TSF with respect to the value of the conductivity of the different tissues and deduce the corresponding integral equations. Afterward we compute the GSF for the same model. We perform some numerical experiments for both types of sensitivity functions and compare the results.

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“…In addition to computing estimates

\overset{θ}{true}

for the unknown parameters using observations { y j }, it is widely accepted that quantifying the uncertainty in these parameter estimates is equally important. A standard method [3, 4, 6, 8, 14, 16, 25] to do this involves computation of standard errors (SE) to be used in confidence intervals (CI) for the parameter estimates. Discussions of the fundamental ideas and methods that are accessible to non-statisticians can be found in [3, 8].…”

Section: Introductionmentioning

confidence: 99%

Standard error computations for uncertainty quantification in inverse problems: Asymptotic theory vs. bootstrapping

Banks

Holm

Robbins

2010

Mathematical and Computer Modelling

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We computationally investigate two approaches for uncertainty quantification in inverse problems for nonlinear parameter dependent dynamical systems. We compare the bootstrapping and asymptotic theory approaches for problems involving data with several noise forms and levels. We consider both constant variance absolute error data and relative error which produces non-constant variance data in our parameter estimation formulations. We compare and contrast parameter estimates, standard errors, confidence intervals, and computational times for both bootstrapping and asymptotic theory methods.

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Sensitivity Functions and Their Uses in Inverse Problems

Cited by 34 publications

References 23 publications

An inverse problem for a class of conditional probability measure-dependent evolution equations

An inverse problem for a class of conditional probability measure-dependent evolution equations

Sensitivity Analysis for the EEG Forward Problem

Standard error computations for uncertainty quantification in inverse problems: Asymptotic theory vs. bootstrapping

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