Eddy currents in a transverse MRI gradient coil

The current distribution in a set of parallel rings and patches, called islands, positioned at the surface of a cylinder, is investigated. The current is driven by an externally applied source current. The islands are rectangular pieces of copper (patches) placed in parallel between the rings. The eddy currents in the islands induce currents in the rings that vary in the tangential direction. From the quasi-static Maxwell equations, an integral equation for the current distribution in the strips is derived. The Galerkin method, using global basis functions, is applied to solve this integral equation. It shows fast convergence. The global basis functions are Legendre polynomials in the axial direction and 2π -periodic trigonometric functions in the tangential direction. The Legendre polynomials efficiently cope with the singularity of the kernel function of the integral equation. Explicit numerical results are shown for three configurations. Apart from the current distributions, the resistance and self-inductance of the three systems of rings and islands are computed. The resulting tool can be used to qualitatively understand eddy currents in z-gradient coils, and as such enable the incorporation of eddy currents in the optimization of gradient-coil design.

show abstract

“…The source current is incorporated in the model via Ohm's law (including source currents; see [15,Eq. 6…”

Section: Model Formulationmentioning

confidence: 99%

“…They consist of strips that are placed spirally on the surface of a cylinder. For curved circular strips of width much smaller than the radius of the cylinder, one may locally replace the curved circular strip by a tangent-plane circular strip, as described in [15].…”

Section: Introductionmentioning

confidence: 99%

Eddy currents in MRI gradient coils configured as rings and patches

2011

Self Cite

View full text Add to dashboard Cite

show abstract

“…The time-varying gradient field produced by the switched gradient coils induces undesirable time-varying eddy currents in the nearby conductive materials such as cryostat, RF shield and the gradient coils themselves. These eddy currents result in many deleterious effects, such as ohmic heating, mechanical vibration and acoustic noise in conductive parts in MRI scanners [11,12].…”

Section: Research Problem and Motivationmentioning

confidence: 99%

“…Due to the skin and proximity effects, the current density tends to be non-uniform across the width of the conductor [12] and it is known that these effects increase with the frequency [12], especially in the modern MRI scanner, the gradient coils are usually etched or machined using wide copper sheet for power dissipation purpose [82]. Not taking into account the skin and proximity effects may lead to inaccurate modelling of the magnetic field profile expected from the gradient coil design.…”

Section: Introductionmentioning

confidence: 99%

“…To study edge-effects, a mathematical model that explains coupling between tracks was developed by Kroot [12,89,132]. However, in his work, only the current distribution in strips and islands were studied, but the effects caused by a non-uniform current density distribution along the track width on the coil parameters and field harmonics were not considered.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Gradient coil design and intra-coil eddy currents in MRI systems

Tang¹

View full text Add to dashboard Cite

The work in this thesis is primarily concerned with the enhancement of gradient coil performance in magnetic resonance imaging (MRI). In MRI, gradient coils are used to produce gradient fields to spatially encode magnetic resonance signals. However, rapid switching on and off of the gradient coils induces fields and eddy currents in the human tissues and surrounding conducting structures. This thesis will provide novel solutions for the design of gradient coils and the reduction of eddy currents.Gradient switching induces electric fields in human tissue that can cause safety problems, in particular peripheral nerve stimulation (PNS), which limits the gradient performance such as the slew rate and maximum gradient strength. One approach to solve this problem is to use local insertable gradient coils to achieve high gradient performance over localised regions of interest (ROI) yet not trigger PNS. Head only coils or head and neck coils are by far the most commonly used local coils. However, due to the constraints of the human head and shoulder, the head gradient coils are usually designed in an asymmetric configuration, with the region-of-uniformity (ROU) close to the patient end of the coil. This asymmetric configuration leads to technical difficulties in maintaining a high gradient performance for the head coil inserts given the very limited space available. Therefore, in this thesis, a practical configuration of an insertable asymmetric gradient head coil that offers improved performance was proposed. In the proposed design, at the patient end, the primary and secondary coils were connected using an additional radial surface, thus allowing the coil conductors distributed on the flange to ensure an improvement in the coil performance. At the service end, the primary and shielding coils were not connected, to permit access to shim trays, cooling system piping, cabling, and so on. It was found that with a similar field quality in the ROI, the proposed coil pattern improved construction characteristics (open service end, well-distributed wire pattern) and offers a better coil performance (lower inductance, higher efficiency etc.) than conventional head coil configurations.Another obstacle to the advancement of MRI is the eddy currents induced in the surrounding conducting structures including the gradient coils themselves. The eddy currents induced in the surrounding conductors depend on the geometry of the conductor and the excitation waveform. These alternating fields caused by the switching gradient coils change the spatial profile of the current density within the coil tracks and surrounding coils with the applied frequencies of the input waveform and by their proximity to other conductors. Therefore, in this thesis, inductive coupling between coil tracks and gradient coils themselves was first investigated and then solutions for mitigation of the eddy current effects were provided. IIFirst, the inductive coupling between coil tracks was studied, considering skin and proximity effects. In this investiga...

show abstract

Dual optimization method of radiofrequency and quasistatic field simulations for reduction of eddy currents generated on 7T radiofrequency coil shielding

Zhao

Zhao²,

Raval

et al. 2014

Magnetic Resonance in Med

View full text Add to dashboard Cite

Purpose To optimize the design of radiofrequency (RF) shielding of transmit coils at 7T and reduce eddy currents generated on the RF shielding when imaging with rapid gradient waveforms. Methods One set of a four-element, 2×2 Tic-Tac-Toe (TTT) head coil structure is selected and constructed to study eddy currents on the RF coil shielding. The generated eddy currents are quantitatively studied in the time and frequency domains. The RF characteristics are studied using the finite-difference time-domain (FDTD) method. Five different kinds of RF shielding were tested on a 7T MRI scanner with phantoms and in-vivo human subjects. Results The eddy current simulation method is verified by the measurement results. Eddy currents induced by solid/intact and simple-structured slotted RF shielding can significantly distort the gradient fields. EPI images, B1+ maps and S matrix measurements verified that the proposed slot pattern can suppress the eddy currents while maintaining the RF characteristics of the transmit coil. Conclusion The presented dual-optimization method could be used to design the RF shielding and reduce the gradient field-induced eddy currents while maintaining the RF characteristics of the transmit coil.

show abstract

Eddy currents in a transverse MRI gradient coil

Cited by 6 publications

References 16 publications

Eddy currents in MRI gradient coils configured as rings and patches

Eddy currents in MRI gradient coils configured as rings and patches

Gradient coil design and intra-coil eddy currents in MRI systems

Dual optimization method of radiofrequency and quasistatic field simulations for reduction of eddy currents generated on 7T radiofrequency coil shielding

Contact Info

Product

Resources

About