Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method

Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method

Bibliographic Details
Main Author: Wang, Guang Chao
Language:English
Published: The Ohio State University / OhioLINK 2011
Subjects:
Biomechanics
Biomedical Research
Biophysics
Mechanical Engineering
Physics
Viscoelasticity
Human Brain
Simulation
CESE Method
Wave Propagation
Wave Absorption
Three-dimensional
Fung's Model
Iatridis&8217
Model
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=osu1313571236
id ndltd-OhioLink-oai-etd.ohiolink.edu-osu1313571236
record_format oai_dc
spelling ndltd-OhioLink-oai-etd.ohiolink.edu-osu13135712362021-08-03T06:03:33Z Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method Wang, Guang Chao Biomechanics Biomedical Research Biophysics Mechanical Engineering Physics Viscoelasticity Human Brain Simulation CESE Method Wave Propagation Wave Absorption Three-dimensional Fung's Model Iatridis&8217 Model <p>This thesis reports the results of my M.S. research work about applying the space-time Conservation Element and Solution Element (CESE) method to calculate the wave propagation in the human brain. I am concerned with theoretical and numerical simulations of wave propagation based on two models: Fung’s model and Iatridis’ model. The thesis is divided into two parts.</p><p>First, the governing equations which include the equation of motion, the viscoelastic constitutive relations, and the equations of internal variables are cast into vector-matrix form, and eigenvalues of the Jacobian matrices of the governing equations are thoroughly derived. The system of equations is shown to be hyperbolic with real eigenvalues and diagonalizable eigenvector matrices in the equations. The treatment for source terms in the CESE method is also reported. The material response is modeled by Fung’s model and modified Fung’s model which is developed by Iatridis. I used parallel connected standard linear solid (SLS) models to discretize Fung’s model and the modified Fung’s model. The resultant relaxation functions formulated in an integral form are then transformed to be differential equations by using the method of internal variables. I then performed simulation of wave absorption in the human brain tissues. While I took conventional approach to determine the parameters in the relaxation functions by using experimental quasi-static longitudinal tests, I also employed the measured wave absorption coefficients to determine the relaxation functions. As such, the constructed relaxation functions are inherently suitable for wave dynamics.</p><p>In the second part of the thesis, I applied the CESE method to solve newly developed model equations for the waves in the human brain. CESE method is a generic numerical method for high-fidelity simulation of first-order, coupled, linear or nonlinear hyperbolic Partial Differential Equations (PDEs). Originally developed for solving compressible flows with complex shock waves, theCESE method had been widely used to simulate various complex compressible flows, including detonations, hypersonic flows, and shock and acoustic wave interactions. The approach is validated by the simulation of an one-dimensional impact wave. </p><p>The results in this thesis present a general theoretical framework of using the first-order, hyperbolic PDEs to model wave motion in brain. The model equations are presented in three-dimensional space. To demonstrate the capabilities of the model equations, I reported numerical solutions of one-dimensional and validated the result, and showed the two-dimensional, and three-dimensional results to create a general pictures of wave propagation in the human brain.</p> 2011-09-26 English text The Ohio State University / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=osu1313571236 http://rave.ohiolink.edu/etdc/view?acc_num=osu1313571236 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.
collection NDLTD
language English
sources NDLTD
topic Biomechanics
Biomedical Research
Biophysics
Mechanical Engineering
Physics
Viscoelasticity
Human Brain
Simulation
CESE Method
Wave Propagation
Wave Absorption
Three-dimensional
Fung's Model
Iatridis&8217
Model
spellingShingle Biomechanics
Biomedical Research
Biophysics
Mechanical Engineering
Physics
Viscoelasticity
Human Brain
Simulation
CESE Method
Wave Propagation
Wave Absorption
Three-dimensional
Fung's Model
Iatridis&8217
Model
Wang, Guang Chao
Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
author Wang, Guang Chao
author_facet Wang, Guang Chao
author_sort Wang, Guang Chao
title Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
title_short Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
title_full Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
title_fullStr Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
title_full_unstemmed Modeling Waves in A Human Brain by Space-Time Conservation Element and Solution Element Method
title_sort modeling waves in a human brain by space-time conservation element and solution element method
publisher The Ohio State University / OhioLINK
publishDate 2011
url http://rave.ohiolink.edu/etdc/view?acc_num=osu1313571236
work_keys_str_mv AT wangguangchao modelingwavesinahumanbrainbyspacetimeconservationelementandsolutionelementmethod
_version_ 1719430194962366464

Similar Items