Coupled microstrip line transverse electromagnetic resonator model for high-field magnetic resonance imaging.

@article{Bogdanov2002Coupled, abstract = {The performance modeling of RF resonators at high magnetic fields of 4.7 T and more requires a physical approach that goes beyond conventional lumped circuit concepts. The treatment of voltages and currents as variables in time and space leads to a coupled transmission line model, whereby the electric and magnetic fields are assumed static in planes orthogonal to the length of the resonator, but wave-like along its longitudinal axis. In this work a multiconductor transmission line (MTL) model is developed and successfully applied to analyze a 12-element unloaded and loaded microstrip line transverse electromagnetic (TEM) resonator coil for animal studies. The loading involves a homogeneous cylindrical dielectric insert of variable radius and length. This model formulation is capable of estimating the resonance spectrum, field distributions, and certain types of losses in the coil, while requiring only modest computational resources. The boundary element method is adopted to compute all relevant transmission line parameters needed to set up the transmission line matrices. Both the theoretical basis and its engineering implementation are discussed and the resulting model predictions are placed in context with measurements. A comparison between a conventional lumped circuit model and this distributed formulation is conducted, showing significant departures in the resonance response at higher frequencies. This MTL model is applied to simulate two small-bore animal systems: one of 7.5-cm inner diameter, tuned to 200 MHz (4.7 T for proton imaging), and one of 13.36-cm inner diameter, tuned to both 200 and 300 MHz (7 T).}, address = {Department of Electrical and Computer Engineering, Worcester Polytechnic Institute, Worcester, Massachusetts 01609, USA.}, author = {Bogdanov, G. and Ludwig, R. }, citeulike-article-id = {341062}, issn = {0740-3194}, journal = {Magn Reson Med}, keywords = {coil, microstrip, mri}, month = {March}, number = {3}, pages = {579--593}, posted-at = {2005-10-04 20:14:47}, priority = {2}, title = {Coupled microstrip line transverse electromagnetic resonator model for high-field magnetic resonance imaging.}, url = {http://view.ncbi.nlm.nih.gov/pubmed/11870846}, volume = {47}, year = {2002} }

TY - JOUR ID - Bogdanov2002Coupled L3 - citeulike-article-id:341062 TI - Coupled microstrip line transverse electromagnetic resonator model for high-field magnetic resonance imaging. JF - Magn Reson Med VL - 47 IS - 3 SP - 579 EP - 593 AD - Department of Electrical and Computer Engineering, Worcester Polytechnic Institute, Worcester, Massachusetts 01609, USA. SN - 0740-3194 N2 - The performance modeling of RF resonators at high magnetic fields of 4.7 T and more requires a physical approach that goes beyond conventional lumped circuit concepts. The treatment of voltages and currents as variables in time and space leads to a coupled transmission line model, whereby the electric and magnetic fields are assumed static in planes orthogonal to the length of the resonator, but wave-like along its longitudinal axis. In this work a multiconductor transmission line (MTL) model is developed and successfully applied to analyze a 12-element unloaded and loaded microstrip line transverse electromagnetic (TEM) resonator coil for animal studies. The loading involves a homogeneous cylindrical dielectric insert of variable radius and length. This model formulation is capable of estimating the resonance spectrum, field distributions, and certain types of losses in the coil, while requiring only modest computational resources. The boundary element method is adopted to compute all relevant transmission line parameters needed to set up the transmission line matrices. Both the theoretical basis and its engineering implementation are discussed and the resulting model predictions are placed in context with measurements. A comparison between a conventional lumped circuit model and this distributed formulation is conducted, showing significant departures in the resonance response at higher frequencies. This MTL model is applied to simulate two small-bore animal systems: one of 7.5-cm inner diameter, tuned to 200 MHz (4.7 T for proton imaging), and one of 13.36-cm inner diameter, tuned to both 200 and 300 MHz (7 T). KW - coil KW - microstrip KW - mri AU - Bogdanov, G AU - Ludwig, R PY - 2002/March// UR - http://view.ncbi.nlm.nih.gov/pubmed/11870846 ER -