According to one embodiment, an arrayed structure includes a cylindrical-shaped conductor layer and a cylindrical-shaped layer stack. The cylindrical-shaped layer stack is arranged on an inner periphery of the conductor layer and a plurality of frequency selective surfaces are arranged in layers and stacked. Each of the frequency selective surfaces has a plurality of elements which are periodically arranged. Each element of the plurality of elements is formed in such a manner that at least a portion of an edge of a first element that faces an adjacent element in the same layer is closer to a center of the first element than another portion of edge.

According to one or more example embodiments, a computer-implemented method for at least partially suppressing a field emitted by a magnetic resonance device during an examination, the emitted field being at least one of an electric field or a magnetic field, the method comprises measuring a signature of the emitted field with a sensor facility; providing a trained function which is configured, based on a signature to generate a field information item relating to the emitted field upon which the respective signature is based; creating a field information item for the emitted field by inputting the signature into the trained function; and suppressing the emitted field by generating a counterfield with a transmitting facility based on the created field information item, the counterfield being at least one of an electric counterfield or a magnetic counterfield, wherein the counterfield is generated such that the counterfield least partially suppresses the emitted field.

Systema and methods to improve the suppression of interference fields outside a magnetic resonance tomography unit. A radiofrequency alternating electromagnetic field of the magnetic resonance tomography unit is generated and measured. A step series is repeated multiple times. The step series includes generating an electromagnetic interference-reduction field for reducing the magnetic field strength at at least one defined location on the basis of a product of a weighting factor and a defined interference-reduction field strength; measuring a magnetic field strength of the generated interference-reduction field; determining an adjustment factor for the weighting factor in such a way as to minimize a sum of the measured field strength of the alternating electromagnetic field and the product of the adjustment factor and the measured interference-reduction field strength; and updating the weighting factor by multiplying by the adjustment factor.

Systema and methods to improve the suppression of interference fields outside a magnetic resonance tomography unit. A radiofrequency alternating electromagnetic field of the magnetic resonance tomography unit is generated and measured. A step series is repeated multiple times. The step series includes generating an electromagnetic interference-reduction field for reducing the magnetic field strength at at least one defined location on the basis of a product of a weighting factor and a defined interference-reduction field strength; measuring a magnetic field strength of the generated interference-reduction field; determining an adjustment factor for the weighting factor in such a way as to minimize a sum of the measured field strength of the alternating electromagnetic field and the product of the adjustment factor and the measured interference-reduction field strength; and updating the weighting factor by multiplying by the adjustment factor.

According to some aspects, a magnetic resonance imaging system capable of imaging a patient is provided. The magnetic resonance imaging system comprising at least one BO magnet to produce a magnetic field to contribute to a BO magnetic field for the magnetic resonance imaging system and a member configured to engage with a releasable securing mechanism of a radio frequency coil apparatus, the member attached to the magnetic resonance imaging system at a location so that, when the member is engaged with the releasable securing mechanism of the radio frequency coil apparatus, the radio frequency coil apparatus is secured to the magnetic resonance imaging system substantially within an imaging region of the magnetic resonance imaging system.

A magnetic resonance apparatus including: a scanner; a patient receiving region which is at least partially surrounded by the scanner; and a lighting apparatus designed to light the patient receiving region. The lighting apparatus includes at least one lighting element; and two neutralizing elements designed to at least partially neutralize a voltage that is induced by a high-frequency field of the scanner.

A radiofrequency transducer assembly includes an antenna structure of the birdcage type. This antenna structure has longitudinally extending segments, which are arranged in a cylindrical configuration around a center axis, and at least one transversally oriented circular electrical coupling between the longitudinally extending segments. An electrically conductive shield surrounds the antenna structure of the birdcage type. The radiofrequency transducer assembly comprises a pair of electrically conductive bridges between a longitudinally extending segment of the antenna structure and the electrically conductive shield, which thereby jointly form an inductive loop.

An upper coil assembly for use with a lower RF coil assembly mounted to provide an RF probe arranged to be engaged with a head of a patient in MRI includes a plurality of coil loops arranged in a row defining a phase shift coil array with each coil loop including an independent output conductor for communicating signals to a respective preamplifier for independent amplification and each coil loop including a plurality of capacitors at spaced positions therearound. To decouple the loops each coil loop partly overlaps a next coil loop with a first decoupling capacitor shared on a common portion of each coil loop and each next coil loop. The first and third coil loops are also decoupled by using third decoupling capacitor in a connecting conductor between the first and third coil loops.

The disclosure relates to a radio-based physiological acquisition system for an RF-shielded room comprising a peripheral acquisition unit with a peripheral transmitter, a peripheral control unit, and a door sensor unit. The door sensor unit is configured to determine an opening status of a door in an RF shield around the RF-shielded room. The peripheral acquisition unit is configured to switch off the peripheral transmitter depending on the opening status of the door, e.g. when the door is open.

According to some aspects, a method of suppressing noise in an environment of a magnetic resonance imaging system is provided. The method comprising estimating a transfer function based on multiple calibration measurements obtained from the environment by at least one primary coil and at least one auxiliary sensor, respectively, estimating noise present in a magnetic resonance signal received by the at least one primary coil based at least in part on the transfer function, and suppressing noise in the magnetic resonance signal using the noise estimate.