Title :
Computation of hyperthermia-SAR distributions in 3-D
Author :
Hoole, S. Ratnajeevan H ; Sathiaseelan, Vythilingham ; Tseng, Ampere
Author_Institution :
Dept. of Eng., Harvey Mudd Coll., Claremont, CA, USA
fDate :
3/1/1990 12:00:00 AM
Abstract :
A formulation for the solution of the general Maxwell´s equations to predict the electromagnetic power deposition (as the specific absorption rate, SAR) in a three-dimensional model of a human body irradiated by an annular array applicator used for hyperthermia is investigated. Methods for generating the grid as well as displaying the three-dimensional solutions are presented. A least-squares finite-element approach to the problem is developed. Difficulties which arise as a result of the finite-element trial functions are identified that make it difficult to impose the divergence and curl equations together. The boundary-element formulation, which relies on the free-space analytical solution, is shown to overcome this difficulty and is demonstrated in two dimensions. These methods form the basis of a treatment planning system under development which will have the capability of generating the finite-element grid model of the body from computerized tomography scans solving for the fields, and displaying the absorbed power distributions
Keywords :
biothermics; electromagnetism; finite element analysis; least squares approximations; radiation therapy; Maxwell´s equations; absorbed power distributions; annular array applicator; boundary-element formulation; computerized tomography scans; electromagnetic power deposition; human body; hyperthermia; least-squares finite-element approach; specific absorption rate; three-dimensional model; treatment planning system; tumour treatment; Biological system modeling; Distributed computing; Electromagnetic modeling; Finite element methods; Humans; Hyperthermia; Maxwell equations; Mesh generation; Predictive models; Specific absorption rate;
Journal_Title :
Magnetics, IEEE Transactions on
