Accuracy of a single equivalent moving dipole model in a realistic anatomic geometry torso model

Author

Fukuoka, Y. ; Armoundas, A. ; Oostendorp, TF ; Cohen, RJ

Author_Institution

Div. of Health Sci. & Technol., MIT, Cambridge, MA, USA

fYear

2000

fDate

2000

Firstpage

439

Lastpage

442

Abstract

We investigated the accuracy of an algorithm to identify, the spatial single equivalent moving dipole parameters in a realistic anatomic geometry torso model from potentials at the body surface. Specifically we investigated the effect of measurement noise, and dipole position and orientation in the accuracy of the algorithm. The boundary element method was used to calculate the forward potential distribution at 64 electrode positions on the body surface due to a point dipole. The mean and standard deviation of the distance of the true (obtained in the forward potential calculation) minus the estimated dipole location (obtained from the inverse algorithm) was estimated for each of the above three cases. Our results indicate that the dipole position has the most significant influence on the accuracy of our inverse algorithm

Keywords

boundary-elements methods; electrocardiography; inverse problems; medical signal processing; physiological models; 64 electrode positions; ECG; accuracy; body surface potentials; boundary element method; dipole location; dipole orientation; dipole position; forward potential distribution; inverse algorithm; measurement noise; point dipole; realistic anatomic geometry torso model; single equivalent moving dipole model; spatial single equivalent moving dipole parameters; Boundary element methods; Conductors; Electrodes; Geometry; Heart; Lungs; Noise measurement; Position measurement; Solid modeling; Torso;

fLanguage

English

Publisher

ieee

Conference_Titel

Computers in Cardiology 2000

Conference_Location

Cambridge, MA

ISSN

0276-6547

Print_ISBN

0-7803-6557-7

Type

conf

DOI

10.1109/CIC.2000.898551

Filename

898551