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A high-pass detunable quadrature birdcage coil at high-fieldKampani, Vishal Virendra 10 October 2008 (has links)
The circuit described in this study is intended for Magnetic Resonance Imaging
(MRI) application. The function of this circuit is to transmit RF energy to the sample
and then receive the RF energy. The circuit that does this is called a birdcage coil. This
coil is capable of producing a very homogenous B1 field over a large volume; it is this
aspect of birdcage coils that make them very favorable for animal/human studies as it is
necessary that all nuclei in the volume of the coil are excited by uniform RF energy. At
high-field (4.7T) when the power is fed to the coil at a single port the coil unable to
produce a homogenous B1 field. However when power is fed at multiple ports the
performance of the coil improves. In this paper a study is carried out comparing the
performance of the coil when power is fed at a single port and two ports. The advantage
of feeding at two ports is that there is sqrt(2) improvement in SNR and the RF power
efficiency is doubled. In this work strategies are presented for matching, tuning and
isolating the two ports. Also, an attempt is made to fabricate a mechanically rigid coil
and interfacing the coil with some additional features that will make the coil easy to use.
The homogeneity and SNR of a birdcage coil in linear and quadrature mode loaded with
saline, oil and CuSO4 phantom was measured on the bench and the scanner. The coil performance was compared to two other birdcage coils in the lab. It was found that the
unshielded trombone coil that was 3 times smaller in volume than the coil presented has
140% higher SNR than the coil presented but the homogenous region of the coil
presented is 48% higher than the smaller coil. Lastly on the bench; the SNR of the
quadrature coil was 30% higher than the coil in the linear mode.
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Design and Optimization of a Miniature Radiation Pattern Reconfigurable Antenna for 2.4 GHz Band and a Dual Tuned Birdcage Coil for Magnetic Resonance ImagingAdhikari, Manoj 09 July 2012 (has links) (PDF)
This thesis describes development of a miniature reconfigurable antenna and optimization of a dual tuned birdcage coil. The design goals for the miniature reconfigurable antennas are resonance center frequency of 2.44 GHz, bandwidth of 2.4 GHz - 2.48 GHz, size of 0.8 cm x 1.2 cm, radiation efficiency of 70%, pattern correlation coefficient of 0.3 and input impedance of 50 Ω. The main goals to be achieved from the birdcage coil are the better homogeneity and higher signal to noise ratio than the existing coil. The design and optimization of both antenna and birdcage coil were done using simulation software and MATLAB. Wireless communications have progressed rapidly in last decade and communication devices are becoming smaller and smaller. With miniaturization of devices, dimensions of antennas need to be reduced accordingly. In recent years engineers have not only focused on miniaturization but also on the reconfigurability of the antenna. The functionality and performance of an antenna can be greatly improved by a reconfigurable antenna. However, designing such an antenna can be a tricky task. This thesis addresses issues that are faced during design of such miniature reconfigurable antenna. It also describes design and optimization of such an antenna. The modeled and measured results for the miniature reconfigurable antennas were very close except the built antenna requires frequency tuning and better switching technique. Magnetic resonance imaging (MRI) is an imaging modality that provides high quality images. Radio frequency (RF) coils play an important role in MRI. RF coils act like an antenna that transmits RF energy and receives energy as well. The most commonly-used RF coil for volume imaging is the birdcage coil. This thesis describes an optimization of a birdcage coil that is dual tuned for sodium and hydrogen frequencies. The modeled coil has better performance compared to the existing coil.
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The Electromagnetic Simulation of Birdcage Coils for MRI based on Finite Element MethodTadesse, Yonatan Abebe January 2016 (has links)
No description available.
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Développement d'antennes RF pour l'imagerie du rat en résonance magnétiqueLessard, Rémi 08 1900 (has links)
Le présent mémoire porte sur la conception et le développement de deux antennes
RF utilisées en imagerie par résonance magnétique. Ces antennes ont pour but de guider
le futur développement d’une plateforme d’imagerie multi-animal qui servira les chercheurs
du nouveau CRCHUM. Plus spécifiquement, ces antennes ont été conçues pour
l’imagerie du proton à 1.5T. La première utilise une birdcage de type lowpass pour la
partie émettrice et utilise 8 éléments de surface pour la partie réceptrice. La seconde antenne
est une birdcage de type lowpass polarisée circulairement qui est utilisée à la fois
pour l’émission et pour la réception. Cette dernière a présenté de bonnes performances,
générant des images avec un SNR élevé et avec une bonne homogénéité, la rendant une
bonne candidate pour la future plateforme. La première a présenté quelques problèmes
au niveau de la désyntonisation de la birdcage et du couplage entre les éléments. Dans le
cas où ces problèmes venaient à être surmontés, cette antenne aurait l’avantage de pouvoir
utiliser des techniques d’imagerie parallèle et possiblement d’avoir un SNR plus
élevé. / This master thesis focuses on the design and development of two RF coils used in
magnetic resonance imaging. These coils are designed to guide the future development
of a multi-animal imaging platform that will serve researchers of the new CRCHUM.
More specifically, these coils were designed for proton imaging at 1.5T. The first uses a
lowpass birdcage as transmitter and uses 8 surface elements for the receiving part. The
second coil is a circularly polarized lowpass birdcage which is used both for transmission
and for reception. The latter presented good performances, generating images with
high SNR and good homogeneity, making it a good candidate for the future platform.
The first one presented a few problems at the detuning of the birdcage and the coupling
between the elements. In the case where these problems would be overcome, this coil
would have the advantage of being able to use parallel imaging techniques and possibly
to have a higher SNR.
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Développement d'antennes RF pour l'imagerie du rat en résonance magnétiqueLessard, Rémi 08 1900 (has links)
Le présent mémoire porte sur la conception et le développement de deux antennes
RF utilisées en imagerie par résonance magnétique. Ces antennes ont pour but de guider
le futur développement d’une plateforme d’imagerie multi-animal qui servira les chercheurs
du nouveau CRCHUM. Plus spécifiquement, ces antennes ont été conçues pour
l’imagerie du proton à 1.5T. La première utilise une birdcage de type lowpass pour la
partie émettrice et utilise 8 éléments de surface pour la partie réceptrice. La seconde antenne
est une birdcage de type lowpass polarisée circulairement qui est utilisée à la fois
pour l’émission et pour la réception. Cette dernière a présenté de bonnes performances,
générant des images avec un SNR élevé et avec une bonne homogénéité, la rendant une
bonne candidate pour la future plateforme. La première a présenté quelques problèmes
au niveau de la désyntonisation de la birdcage et du couplage entre les éléments. Dans le
cas où ces problèmes venaient à être surmontés, cette antenne aurait l’avantage de pouvoir
utiliser des techniques d’imagerie parallèle et possiblement d’avoir un SNR plus
élevé. / This master thesis focuses on the design and development of two RF coils used in
magnetic resonance imaging. These coils are designed to guide the future development
of a multi-animal imaging platform that will serve researchers of the new CRCHUM.
More specifically, these coils were designed for proton imaging at 1.5T. The first uses a
lowpass birdcage as transmitter and uses 8 surface elements for the receiving part. The
second coil is a circularly polarized lowpass birdcage which is used both for transmission
and for reception. The latter presented good performances, generating images with
high SNR and good homogeneity, making it a good candidate for the future platform.
The first one presented a few problems at the detuning of the birdcage and the coupling
between the elements. In the case where these problems would be overcome, this coil
would have the advantage of being able to use parallel imaging techniques and possibly
to have a higher SNR.
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Návrh a realizace klecové cívky pro MRI / Design and Realization of the Bird Cage Coil for MRISedlář, Petr January 2016 (has links)
The work deals with the design and experimental production of the model type Birdcage coil used for magnetic resonance imaging system (MRI). The work deals with the design and behaviour of the model type Birdcage coil volume designed for imaging system for magnetic resonance imaging (MRI). Volume coils are generally very useful for use in MRI, because in transversal design allow easy access into the cavity when the flow vector of magnetization. The aim of the work was to construct a numerical model of transversal coil type Birdcage of the predefined dimensions. The created the coil tuned the desired resonant frequency having regard to maximize performance in the measured sample migrated. The modeling coil experimentally produced and measurements also confirm the accuracy of the numerical model.
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