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PIER PIER B PIER C PIER M PIER Letters
2020-01-09
Port Decoupling Vs Array Elements Decoupling for Tx/Rx System at 7-Tesla Magnetic Resonance Imaging
By
Ashraf Abuelhaija,

    Dr. Ashraf Abuelhaija

    Applied Science Private University

    Jordan

    Homepage

Sanaa Salama,

    Dr. Sanaa Salama

    Arab American University

    Palestine

    Homepage

Tarik Baldawi

    Dr. Tarik Baldawi

    Applied Science Private University

    Jordan

    Homepage

Progress In Electromagnetics Research C, Vol. 98, 213-224, 2020
doi:10.2528/PIERC19091205
Abstract
Symmetrically excited meandered microstrip line RF coil elements are widely utilized in multichannel approaches which have been proposed to be integrated in ultra-high field MRI system (i.e., 7T and higher). These elements have demonstrated strong magnetic field in the deep areas in the object under imaging. Designing a radio frequency (RF) coil array that employs these elements without decoupling networks might cause non-optimized driving performance of coil array which in turn result in non-clear image. In this paper, two different methods of decoupling have been studied: port decoupling and array elements decoupling. For port decoupling, the coil elements have been designed at Larmor frequency (297.3 MHz) whereas for array elements decoupling, the coil elements have been designed at higher frequencies but matched at Larmor frequency. Port decoupling does not always mean element decoupling. Conventional decoupling methods, such as single capacitor or inductor, face challenges to realize the coil element decoupling for meandered microstrip arrays. An optimized reactive (T-shaped) network is needed in order to achieve element decoupling which in turn prevents distortion of the EM field. All simulation results have been obtained using the CST time domain solver (CST AG, Darmstadt, Germany).
Citation
Ashraf Abuelhaija, Sanaa Salama, and Tarik Baldawi, "Port Decoupling Vs Array Elements Decoupling for Tx/Rx System at 7-Tesla Magnetic Resonance Imaging," Progress In Electromagnetics Research C, Vol. 98, 213-224, 2020.
doi:10.2528/PIERC19091205
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