Model input and output dimension reduction using Karhunen Loève expansions with application to biotransport
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2019-03-15
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Alen Alexanderian, William Reese, Ralph C. Smith, Meilin Yu, Model input and output dimension reduction using Karhunen Loève expansions with application to biotransport, Physics , Computational Physics, 2019, https://arxiv.org/abs/1903.06314
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Abstract
We consider biotransport in tumors with uncertain heterogeneous
material properties. Specifically, we focus on the elliptic
partial differential equation (PDE) modeling the pressure
field inside the tumor. The permeability field is modeled
as a log-Gaussian random field with a prespecified covariance
function. We numerically explore dimension reduction
of the input parameter and model output. Truncated
Karhunen–Lo`eve (KL) expansions are used to decompose
the log-permeability field, as well as the resulting random
pressure field. We find that although very high-dimensional
representations are needed to accurately represent the permeability
field, especially in presence of small correlation
lengths, the pressure field is not very sensitive to high-order
KL terms of the input parameter. Moreover, we find that the
pressure field itself can be represented accurately using a KL
expansion with a small number of terms. These observations
are used to guide a reduced-order modeling approach to accelerate
computational studies of biotransport in tumors.