Title :
Dependence of the inverse solution accuracy in magnetocardiography on the boundary-element discretization
Author :
Haueisen, Jens ; Schreiber, Jörg ; Brauer, Hartmut ; Knösche, Thomas R.
Author_Institution :
Biomagnetic Center, Friedrich-Schiller-Univ., Jena, Germany
fDate :
3/1/2002 12:00:00 AM
Abstract :
Modeling in magnetocardiography is increasingly based on the boundary-element method. We quantify the influence of the boundary-element discretization on the cardiomagnetic forward and inverse problem for different dipole depths and regions of the heart. Simulations using single current dipoles and a high resolution boundary-element model (edge length <10 mm) are used to assess models of various complexity (with and without blood masses) and discretization. It is found that the maximum localization error of about 5 mm occurs if the test dipole is very close to one of the boundaries (lungs). Edge lengths of 20, 15, and 8 mm for the torso, lungs, and ventricles, respectively, are sufficient to reach a localization accuracy of 2 mm
Keywords :
boundary-elements methods; computational complexity; error analysis; inverse problems; magnetocardiography; medical computing; 10 mm; 15 mm; 20 mm; 8 mm; biomagnetics; blood masses; boundary-element discretization; boundary-element method; cardiography; cardiomagnetic forward problem; cardiomagnetic inverse problem; dipole depths; edge length; edge lengths; heart regions; high resolution boundary-element model; inverse problems; inverse solution accuracy; localization accuracy; lungs; magnetocardiography; magnetocardiography modeling; maximum localization error; model complexity; model discretization; simulations; single current dipoles; test dipole; torso; ventricles; Blood; Cardiology; Computational modeling; Conductivity; Heart; Humans; Inverse problems; Lungs; Magnetic fields; Torso;
Journal_Title :
Magnetics, IEEE Transactions on
