Patent Description:
Magnetic resonance imaging (MRI) is a medical imaging modality that can create images of the inside of a human body without using x-rays or other ionizing radiation. MRI systems include a superconducting magnet to create a strong, uniform, static magnetic field. When a human body, or part of a human body, is placed in the magnetic field, the nuclear spins associated with the hydrogen nuclei in tissue water become polarized, wherein the magnetic moments associated with these spins become preferentially aligned along the direction of the magnetic field, resulting in a small net tissue magnetization along that axis. MRI systems also include gradient coils that produce smaller amplitude, spatially-varying magnetic fields with orthogonal axes to spatially encode the magnetic resonance (MR) signal by creating a signature resonance frequency at each location in the body. Radio frequency (RF) coils are then used to create pulses of RF energy at or near the resonance frequency of the hydrogen nuclei, which add energy to the nuclear spin system. As the nuclear spins relax back to their rest energy state, they release the absorbed energy in the form of an MR signal. This signal is detected by the MRI system and is transformed into an image using reconstruction algorithms.

As mentioned, RF coils are used in MRI systems to transmit RF excitation signals ("transmit coil"), and to receive the RF signals emitted by an imaging subject ("receive coil"). Coil-interfacing cables may be used to transmit signals between the RF coils and other aspects of the processing system, for example to control the RF coils and/or to receive information from the RF coils. However, conventional RF coils tend to be bulky, rigid and are configured to be maintained at a fixed position relative to other RF coils in an array. This bulkiness and lack of flexibility often prevents the RF coil loops from coupling most efficiently with the desired anatomy and make them very uncomfortable to the imaging subject. Further, coil-to-coil interactions dictate that the coils be sized and/or positioned non-ideally from a coverage or imaging acceleration perspective.

<CIT> describes an antenna comprising a first, outer conductor, at least one inner conductor within the first outer conductor, and a second outer conductor surrounding the first outer conductor. The second outer conductor may define a plurality of holes therethrough. The at least one inner conductor may comprise a plurality of inner conductors. At least two of the plurality of inner conductors may be connected to each other in series, across a capacitor. At least two of the plurality of inner conductors may be connected to each other in parallel, across a capacitor. The at least one inner conductor may be sufficiently surrounded by the first outer conductor to shield the inner conductor from receiving a radiofrequency signal.

<CIT> describes a radio frequency (RF) surface coil and a magnetic resonance device employing the same. The described RF surface coil for the magnetic resonance device comprises: a plurality of conductor elements connected in series so as to form a loop-shaped surface coil; and a variable inductance unit provided in at least one of the plurality of conductor elements so as to adjust inductance, wherein the variable inductance unit comprises a conductor bar and a coupler for attachably/detachably coupling the conductor bar to/from at least one of the plurality of conductor elements.

<CIT> describes an HF-antenna system for carrying out and/or detecting a magnetic resonance in an object exposed to a main magnetic field which orients the object spins in a desired longitudinal direction comprising at least one first antenna element provided with several conducting sections which lead a high-frequency alternating current and extend from the common top to a base area in the form of separate claws in such a way that the testable object containing a volume of interest is enveloped in a helmet manner. Said invention is characterized in that each conducting section is embodied in the form of a HF (HL) line for electromagnetically connecting a wave propagating in a TEM mode or in an quasi-TEM mode with the spins of the testable object to be enveloped and the electrical length the terminals of the HF (HL) lines are selected in such a way that the magnetic resonance frequency waves are produced therein.

<CIT> describes a radio-frequency (RF) resonator system, in particular, for a magnetic resonance (MR) probe, comprising at least one RF resonator with a substrate, on which a conductive structure is applied, wherein the conductive structure comprises regions of capacitive and inductive elements, and is characterized in that the conductive structure is coated at least in the regions of the capacitive elements with at least one dielectric layer that covers the regions of the capacitive elements at least partially, wherein the local thickness of at least one of the dielectric layers is set in dependence on the resonance frequency of the uncoated RF resonator, on a defined resonance frequency of the resonator once it is coated, on the dielectric constant of the substrate and on the dielectric constant of the materials of the dielectric layers.

According to the invention, a radio frequency (RF) coil assembly for a magnetic resonance (MR) imaging system as set out in claim <NUM> is provided. In this way, a flexible RF coil assembly may be provided that allows for RF coils in an array to be positioned more arbitrarily, allowing placement and/or size of the coils to be based on desired anatomy coverage, without having to account for fixed coil overlaps or electronics positioning. The coils may conform to the patient anatomy, rigid or semi-rigid housing contours with relative ease. Additionally, the cost and weight of the coils may be significantly lowered due to minimized materials and production process, and environmentally-friendlier processes may be used in the manufacture and miniaturization of the RF coils of the present disclosure versus conventional coils. Further, by including at least three distributed capacitance wires, the capacitance of the RF coil assembly may be increased relative to RF coils comprised of fewer parallel wires (e.g., two parallel wires), allowing for usage of the RF coil assembly in an MR environment where lower resonance frequency is desired.

It should be understood that the brief description above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure. Irrespective of whether the term "embodiment" is used hereafter, the scope of protection is defined by the claims.

The following description relates to various embodiments of a radio frequency (RF) coil in MRI systems. In particular, systems and methods are provided for a low-cost, flexible, and lightweight RF coil that is effectively transparent in multiple respects. The RF coil is effectively transparent to patients, given the low weight of the coil and flexible packaging that is enabled by the RF coil. The RF coil is also effectively transparent to other RF coils in an array of RF coils, due to minimization of magnetic and electric coupling effects. Further, the RF coil is effectively transparent to other structures through capacitance minimization and is transparent to positrons through mass reduction, enabling use of the RF coil in hybrid positron emission tomography (PET)/MR imaging systems. The RF coil of the present disclosure may be used in MRI systems of various magnetic field strengths.

The RF coil of the present disclosure uses a significantly smaller amount of copper, printed circuit board (PCB) material and electronic components than what is used in a conventional RF coil. The RF coil disclosure herein includes parallel elongated wire conductors, encapsulated and separated by a dielectric material, forming the coil element. The parallel wires form a low reactance structure without need for discrete capacitors. The minimal conductor, sized to keep losses tolerable, eliminates much of the capacitance between coil loops, and reduces electric field coupling. By interfacing with a large sampling impedance, currents are reduced and magnetic field coupling is minimized. The electronics are minimized in size and content to keep mass and weight low and prevent excessive interaction with the desired fields. Packaging can now be extremely flexible which allows conforming to anatomy, optimizing signal to noise ratio (SNR) and imaging acceleration.

A traditional RF receive coil for MR is comprised of several conductive intervals joined between themselves by capacitors. By adjusting the capacitors' capacitances, the impedance of the RF coil may be brought to its minimal value, usually characterized by low resistance. At resonant frequency, stored magnetic and electric energy alternate periodically. Each conductive interval, due to its length and width, possesses a certain self-capacitance, where electric energy is periodically stored as static electricity. The distribution of this electricity takes place over the entire conductive interval length of the order of <NUM>-<NUM>, causing similar range electric dipole field. In a proximity of a large dielectric load, self-capacitance of the intervals change - hence detuning of the coil. In case of a lossy dielectric, dipole electric field causes Joule dissipation characterized by an increase overall resistance observed by the coil.

In contrast, the RF coil of the present disclosure represents almost an ideal magnetic dipole antenna as its common mode current is uniform in phase and amplitude along its perimeter. The capacitance of the RF coil is built between at least two wires along the perimeter of the loop. The conservative electric field is strictly confined within the small cross-section of the parallel wires and dielectric filler material. In the case of two RF coil loops overlapping, the parasitic capacitance at the cross-overs is greatly reduced in comparison to two overlapped copper traces of traditional RF coils. RF coil thin cross-sections allows better magnetic decoupling and reduces or eliminates critical overlap between two loops in comparison to two traditional trace-based coil loops.

<FIG> illustrates a magnetic resonance imaging (MRI) apparatus <NUM> that includes a superconducting magnet unit <NUM>, a gradient coil unit <NUM>, an RF coil unit <NUM>, an RF body or volume coil unit <NUM>, a transmit/receive (T/R) switch <NUM>, an RF driver unit <NUM>, a gradient coil driver unit <NUM>, a data acquisition unit <NUM>, a controller unit <NUM>, a patient table or bed <NUM>, a data processing unit <NUM>, an operating console unit <NUM>, and a display unit <NUM>. In one example, the RF coil unit <NUM> is a surface coil, which is a local coil that is typically placed proximate to the anatomy of interest of a subject <NUM>. Herein, the RF body coil unit <NUM> is a transmit coil that transmits RF signals, and the local surface RF coil unit <NUM> receives the MR signals. As such, the transmit body coil (e.g., RF body coil unit <NUM>) and the surface receive coil (e.g., RF coil unit <NUM>) are independent but electromagnetically coupled structures. The MRI apparatus <NUM> transmits electromagnetic pulse signals to the subject <NUM> placed in an imaging space <NUM> with a static magnetic field formed to perform a scan for obtaining magnetic resonance signals from the subject <NUM> to reconstruct an image of a slice of the subject <NUM> based on the magnetic resonance signals thus obtained by the scan.

The superconducting magnet unit <NUM> includes, for example, an annular superconducting magnet, which is mounted within a toroidal vacuum vessel. The magnet defines a cylindrical space surrounding the subject <NUM>, and generates a constant, strong, uniform, static magnetic field along the Z direction of the cylindrical space.

The MRI apparatus <NUM> also includes the gradient coil unit <NUM> that generates a gradient magnetic field in the imaging space <NUM> so as to provide the magnetic resonance signals received by the RF coil unit <NUM> with three-dimensional positional information. The gradient coil unit <NUM> includes three gradient coil systems, each of which generates a gradient magnetic field, which inclines into one of three spatial axes perpendicular to each other, and generates a gradient magnetic field in each of frequency encoding direction, phase encoding direction, and slice selection direction in accordance with the imaging condition. More specifically, the gradient coil unit <NUM> applies a gradient magnetic field in the slice selection direction of the subject <NUM>, to select the slice; and the RF body coil unit <NUM> transmits an RF signal to a selected slice of the subject <NUM> and excites it. The gradient coil unit <NUM> also applies a gradient magnetic field in the phase encoding direction of the subject <NUM> to phase encode the magnetic resonance signals from the slice excited by the RF signal. The gradient coil unit <NUM> then applies a gradient magnetic field in the frequency encoding direction of the subject <NUM> to frequency encode the magnetic resonance signals from the slice excited by the RF signal.

The RF coil unit <NUM> is disposed, for example, to enclose the region to be imaged of the subject <NUM>. In some examples, the RF coil unit <NUM> may be referred to as the surface coil or the receive coil. In the static magnetic field space or imaging space <NUM> where a static magnetic field is formed by the superconducting magnet unit <NUM>, the RF coil unit <NUM> transmits, based on a control signal from the controller unit <NUM>, an RF pulse that is an electromagnet wave to the subject <NUM> and thereby generates a high-frequency magnetic field. This excites a spin of protons in the slice to be imaged of the subject <NUM>. The RF coil unit <NUM> receives, as a magnetic resonance signal, the electromagnetic wave generated when the proton spin thus excited in the slice to be imaged of the subject <NUM> returns into alignment with the initial magnetization vector. In some embodiments, the RF coil unit <NUM> may transmit the RF pulse and receive the MR signal. In other embodiments, the RF coil unit <NUM> may only be used for receiving the MR signals, but not transmitting the RF pulse.

The RF body coil unit <NUM> is disposed, for example, to enclose the imaging space <NUM>, and produces RF magnetic field pulses orthogonal to the main magnetic field produced by the superconducting magnet unit <NUM> within the imaging space <NUM> to excite the nuclei. In contrast to the RF coil unit <NUM>, which may be disconnected from the MR apparatus <NUM> and replaced with another RF coil unit, the RF body coil unit <NUM> is fixedly attached and connected to the MRI apparatus <NUM>. Furthermore, whereas local coils such as those comprising the RF coil unit <NUM> can transmit to or receive signals from only a localized region of the subject <NUM>, the RF body coil unit <NUM> generally have a larger coverage area. The RF body coil unit <NUM> may be used to transmit or receive signals to the whole body of the subject <NUM>, for example. Using receive-only local coils and transmit body coils provides a uniform RF excitation and good image uniformity at the expense of high RF power deposited in the subject. For a transmit-receive local coil, the local coil provides the RF excitation to the region of interest and receives the MR signal, thereby decreasing the RF power deposited in the subject. It should be appreciated that the particular use of the RF coil unit <NUM> and/or the RF body coil unit <NUM> depends on the imaging application.

The T/R switch <NUM> can selectively electrically connect the RF body coil unit <NUM> to the data acquisition unit <NUM> when operating in receive mode, and to the RF driver unit <NUM> when operating in transmit mode. Similarly, the T/R switch <NUM> can selectively electrically connect the RF coil unit <NUM> to the data acquisition unit <NUM> when the RF coil unit <NUM> operates in receive mode, and to the RF driver unit <NUM> when operating in transmit mode. When the RF coil unit <NUM> and the RF body coil unit <NUM> are both used in a single scan, for example if the RF coil unit <NUM> is configured to receive MR signals and the RF body coil unit <NUM> is configured to transmit RF signals, then the T/R switch <NUM> may direct control signals from the RF driver unit <NUM> to the RF body coil unit <NUM> while directing received MR signals from the RF coil unit <NUM> to the data acquisition unit <NUM>. The coils of the RF body coil unit <NUM> may be configured to operate in a transmit-only mode, a receive-only mode, or a transmit-receive mode. The coils of the local RF coil unit <NUM> may be configured to operate in a transmit-receive mode or a receive-only mode.

The RF driver unit <NUM> includes a gate modulator (not shown), an RF power amplifier (not shown), and an RF oscillator (not shown) that are used to drive the RF coil unit <NUM> and form a high-frequency magnetic field in the imaging space <NUM>. The RF driver unit <NUM> modulates, based on a control signal from the controller unit <NUM> and using the gate modulator, the RF signal received from the RF oscillator into a signal of predetermined timing having a predetermined envelope. The RF signal modulated by the gate modulator is amplified by the RF power amplifier and then output to the RF coil unit <NUM>.

The gradient coil driver unit <NUM> drives the gradient coil unit <NUM> based on a control signal from the controller unit <NUM> and thereby generates a gradient magnetic field in the imaging space <NUM>. The gradient coil driver unit <NUM> includes three systems of driver circuits (not shown) corresponding to the three gradient coil systems included in the gradient coil unit <NUM>.

The data acquisition unit <NUM> includes a pre-amplifier (not shown), a phase detector (not shown), and an analog/digital converter (not shown) used to acquire the magnetic resonance signals received by the RF coil unit <NUM>. In the data acquisition unit <NUM>, the phase detector phase detects, using the output from the RF oscillator of the RF driver unit <NUM> as a reference signal, the magnetic resonance signals received from the RF coil unit <NUM> and amplified by the pre-amplifier, and outputs the phase-detected analog magnetic resonance signals to the analog/digital converter for conversion into digital signals. The digital signals thus obtained are output to the data processing unit <NUM>.

The MRI apparatus <NUM> includes a table <NUM> for placing the subject <NUM> thereon. The subject <NUM> may be moved inside and outside the imaging space <NUM> by moving the table <NUM> based on control signals from the controller unit <NUM>.

The controller unit <NUM> includes a computer and a recording medium on which a program to be executed by the computer is recorded. The program when executed by the computer causes various parts of the apparatus to carry out operations corresponding to pre-determined scanning. The recording medium may comprise, for example, a ROM, flexible disk, hard disk, optical disk, magneto-optical disk, CD-ROM, or non-volatile memory. The controller unit <NUM> is connected to the operating console unit <NUM> and processes the operation signals input to the operating console unit <NUM> and furthermore controls the table <NUM>, RF driver unit <NUM>, gradient coil driver unit <NUM>, and data acquisition unit <NUM> by outputting control signals to them. The controller unit <NUM> also controls, to obtain a desired image, the data processing unit <NUM> and the display unit <NUM> based on operation signals received from the operating console unit <NUM>.

The operating console unit <NUM> includes user input devices such as a touchscreen, keyboard and a mouse. The operating console unit <NUM> is used by an operator, for example, to input such data as an imaging protocol and to set a region where an imaging sequence is to be executed. The data about the imaging protocol and the imaging sequence execution region are output to the controller unit <NUM>.

The data processing unit <NUM> includes a computer and a recording medium on which a program to be executed by the computer to perform predetermined data processing is recorded. The data processing unit <NUM> is connected to the controller unit <NUM> and performs data processing based on control signals received from the controller unit <NUM>. The data processing unit <NUM> is also connected to the data acquisition unit <NUM> and generates spectrum data by applying various image processing operations to the magnetic resonance signals output from the data acquisition unit <NUM>.

The display unit <NUM> includes a display device and displays an image on the display screen of the display device based on control signals received from the controller unit <NUM>. The display unit <NUM> displays, for example, an image regarding an input item about which the operator inputs operation data from the operating console unit <NUM>. The display unit <NUM> also displays a two-dimensional (2D) slice image or three-dimensional (3D) image of the subject <NUM> generated by the data processing unit <NUM>.

During a scan, RF coil array interfacing cables (not shown) may be used to transmit signals between the RF coils (e.g., RF coil unit <NUM> and RF body coil unit <NUM>) and other aspects of the processing system (e.g., data acquisition unit <NUM>, controller unit <NUM>, and so on), for example to control the RF coils and/or to receive information from the RF coils. As explained previously, the RF body coil unit <NUM> is a transmit coil that transmits RF signals, and the local surface RF coil <NUM> receives the MR signals. More generally, RF coils are used to transmit RF excitation signals ("transmit coil"), and to receive the MR signals emitted by an imaging subject ("receive coil"). In an example, the transmit and receive coils are a single mechanical and electrical structure or array of structures, with transmit/receive mode switchable by auxiliary circuitry. In other examples, the transmit body coil (e.g., RF body coil unit <NUM>) and the surface receive coil (e.g., RF coil unit <NUM>) may be independent structures that are physically coupled to each other via a data acquisition unit or other processing unit. For enhanced image quality, however, it may be desirable to provide a receive coil that is mechanically and electrically isolated from the transmit coil. In such case it is desirable that the receive coil, in its receive mode, be electromagnetically coupled to and resonant with an RF "echo" that is stimulated by the transmit coil. However, during transmit mode, it may be desirable that the receive coil is electromagnetically decoupled from and therefore not resonant with the transmit coil, during actual transmission of the RF signal. Such decoupling averts a potential problem of noise produced within the auxiliary circuitry when the receive coil couples to the full power of the RF signal. Additional details regarding the uncoupling of the receive RF coil will be described below.

As mentioned previously, traditional RF coils may include acid etched copper traces (loops) on PCBs with lumped electronic components (e.g., capacitors, inductors, baluns, resistors, etc.), matching circuitry, decoupling circuitry, and preamplifiers. Such a configuration is typically very bulky, heavy and rigid, and requires relatively strict placement of the coils relative to each other in an array to prevent coupling interactions among coil elements that may degrade image quality. As such, traditional RF coils and RF coil arrays lack flexibility and hence may not conform to patient anatomy, degrading imaging quality and patient comfort.

Thus, according to embodiments disclosed herein, an RF coil array, such as RF coil unit <NUM>, may include distributed capacitance wires rather than copper traces on PCBs with lumped electronic components. As a result, the RF coil array may be lightweight and flexible, allowing placement in low-cost, lightweight, waterproof, and/or flame retardant fabrics or materials. The coupling electronics portion coupling the loop portion of the RF coil (e.g., the distributed capacitance wire) may be miniaturized and utilize a low input impedance pre-amplifier, which is optimized for high source impedance (e.g., due to impedance matching circuitry) and allows flexible overlaps among coil elements in an RF coil array. Further, the RF coil array interfacing cable between the RF coil array and system processing components may be flexible and include integrated transparency functionality in the form of distributed baluns, which allows rigid electronic components to be avoided and aids in spreading of the heat load.

Turning now to <FIG>, a schematic view of an RF coil <NUM> including a loop portion <NUM> coupled to a controller unit <NUM> via coupling electronics portion <NUM> and a coil-interfacing cable <NUM> is shown. In one example, the RF coil may be a surface receive coil, which may be single- or multi-channel. The RF coil <NUM> is one non-limiting example of RF coil unit <NUM> of <FIG> and as such may operate at one or more frequencies in the MRI apparatus <NUM>. The coil-interfacing cable <NUM> may be a coil-interfacing cable extending between the electronics portion <NUM> and an interfacing connector of an RF coil array or a RF coil array interfacing cable extending between the interfacing connector of the RF coil array and the MRI system controller unit <NUM>. The controller unit <NUM> may be associated with and/or may be a non-limiting example of the data processing unit <NUM> or controller unit <NUM> in <FIG>.

The coupling electronics portion <NUM> may be coupled to the loop portion <NUM> of the RF coil <NUM>. Herein, the coupling electronics portion <NUM> may include a decoupling circuit <NUM>, impedance inverter circuit <NUM>, and a pre-amplifier <NUM>. The decoupling circuit <NUM> may effectively decouple the RF coil during a transmit operation. Typically, the RF coil <NUM> in its receive mode may be coupled to a body of a subject being imaged by the MR apparatus in order to receive echoes of the RF signal transmitted during the transmit mode. If the RF coil <NUM> is not used for transmission, then it may be necessary to decouple the RF coil <NUM> from the RF body coil while the RF body coil is transmitting the RF signal. The decoupling of the receive coil from the transmit coil may be achieved using resonance circuits and PIN diodes, microelectromechanical systems (MEMS) switches, or another type of switching circuitry. Herein, the switching circuitry may activate detuning circuits operatively connected to the RF coil <NUM>.

The impedance inverter circuit <NUM> may form an impedance matching network between the RF coil <NUM> and the pre-amplifier <NUM>. The impedance inverter circuit <NUM> is configured to transform a coil impedance of the RF coil <NUM> into an optimal source impedance for the pre-amplifier <NUM>. The impedance inverter circuit <NUM> may include an impedance matching network and an input balun. The pre-amplifier <NUM> receives MR signals from the corresponding RF coil <NUM> and amplifies the received MR signals. In one example, the pre-amplifier may have a low input impedance that is configured to accommodate a relatively high blocking or source impedance. Additional details regarding the RF coil and associated coupling electronics portion will be explained in more detail below with respect to <FIG>. The coupling electronics portion <NUM> may be packaged in a very small PCB approximately <NUM><NUM> in size or smaller. The PCB may be protected with a conformal coating or an encapsulating resin.

The coil-interfacing cable <NUM>, such as a RF coil array interfacing cable, may be used to transmit signals between the RF coils and other aspects of the processing system, for example to control the RF coils and/or to receive information from the RF coils. The RF coil array interfacing cables may be disposed within the bore or imaging space of the MRI apparatus (such as MRI apparatus <NUM> of <FIG>) and subjected to electro-magnetic fields produced and used by the MRI apparatus. In MRI systems, coil-interfacing cables, such as coil-interfacing cable <NUM>, may support transmitter-driven common-mode currents, which may in turn create field distortions and/or unpredictable heating of components. Typically, common-mode currents are blocked by using baluns. Baluns or common-mode traps provide high common-mode impedances, which in turn reduces the effect of transmitter-driven currents.

Thus, coil-interfacing cable <NUM> may include one or more baluns. In traditional coil-interfacing cables, baluns are positioned with a relatively high density, as high dissipation/voltages may develop if the balun density is too low or if baluns are positioned at an inappropriate location. However, this dense placement may adversely affect flexibility, cost, and performance. As such, the one or more baluns in the coil-interfacing cable may be continuous baluns to ensure no high currents or standing waves, independent of positioning. The continuous baluns may be distributed, flutter, and/or butterfly baluns. Additional details regarding the coil-interfacing cable and baluns will be presented below with respect to <FIG>.

<FIG> is a schematic of an RF coil <NUM> having segmented conductors formed in accordance with an embodiment. RF coil <NUM> is a non-limiting example of RF coil <NUM> of <FIG> and as such includes loop portion <NUM> and coupling electronics portion <NUM> of RF coil <NUM>. The coupling electronics portion allows the RF coil to transmit and/or receive RF signals when driven by the data acquisition unit <NUM> (shown in <FIG>). In the illustrated embodiment, the RF coil <NUM> includes a first conductor wire <NUM> and a second conductor wire <NUM>. The first and second conductor wires <NUM>, <NUM> may be segmented such that the conductors form an open circuit (e.g., form a monopole). The segments of the conductor wires <NUM>, <NUM> may have different lengths, as is discussed below. The length of the first and second conductor wires <NUM>, <NUM> may be varied to achieve a desired distributed capacitance, and accordingly, a desired resonance frequency.

The first conductor wire <NUM> includes a first segment <NUM> and a second segment <NUM>. The first segment <NUM> includes a driven end <NUM> at an interface terminating to coupling electronics portion <NUM>, which will be described in more detail below. The first segment <NUM> also includes a floating end <NUM> that is detached from a reference ground, thereby maintaining a floating state. The second segment <NUM> includes a driven end <NUM> at the interface terminating to the coupling electronics portion and a floating end <NUM> that is detached from a reference ground.

The second conductor wire <NUM> includes a first segment <NUM> and a second segment <NUM>. The first segment <NUM> includes a driven end <NUM> at the interface. The first segment <NUM> also includes a floating end <NUM> that is detached from a reference ground, thereby maintaining a floating state. The second segment <NUM> includes a driven end <NUM> at the interface, and a floating end <NUM> that is detached from a reference ground. The driven end <NUM> may terminate at the interface such that end <NUM> is only coupled to the first conductor through the distributed capacitance. The capacitors shown around the loop between the conductors represent the capacitance between the wires.

The first conductor wire <NUM> and the second conductor wire <NUM> exhibit a distributed capacitance that grows along the length of the first and second segments <NUM>, <NUM>, <NUM>, <NUM>. The first segments <NUM>, <NUM> may have a different length than the second segments <NUM>, <NUM>. The relative difference in length between the first segments <NUM>, <NUM> and the second segments <NUM>, <NUM> may be used to produce an effective LC circuit having a resonance frequency at the desired center frequency. For example, by varying the length of the first segments <NUM>, <NUM> relative to the lengths of the second segments <NUM>, <NUM>, an integrated distributed capacitance may be varied.

In the illustrated embodiment, the first and second conductor wires <NUM>, <NUM> are shaped into a loop portion that terminates to an interface. But in other embodiments, other shapes are possible. For example, the loop portion may be a polygon, shaped to conform the contours of a surface (e.g., housing), and/or the like. The loop portion defines a conductive pathway along the first and second conductor wires. The first and second conductor wires are void of any discrete or lumped capacitive or inductive elements along an entire length of the conductive pathway. The loop portion may also include loops of varying gauge of stranded or solid conductor wire, loops of varying diameters with varying lengths of the first and second conductor wires <NUM>, <NUM>, and/or loops of varying spacing between the first and second conductor wires. For example, each of the first and second conductors may have no cuts or gaps (no segmented conductors) or one or more cuts or gaps (segmented conductors) at various locations along the conductive pathway.

Distributed capacitance (DCAP), as used herein and also referred to as integrated capacitance, represents a capacitance exhibited between conductors along the length of the conductors and is void of discrete or lumped capacitive components and discrete or lumped inductive components. In the examples herein, the capacitance may grow in an even and uniform manner along the length of the first and second conductor wires <NUM>, <NUM>.

A dielectric material <NUM> encapsulates and separates the first and second conductor wires <NUM>, <NUM>. The dielectric material <NUM> may be selectively chosen to achieve a desired distributive capacitance. The dielectric material <NUM> may be based on a desired permittivity ε to vary the effective capacitance of the loop portion. For example, the dielectric material <NUM> may be air, rubber, plastic, or any other dielectric material. In one example, the dielectric material may be polytetrafluoroethylene (pTFE). For example, the dielectric material <NUM> may be an insulating material surrounding the parallel conductive elements of the first and second conductor wires <NUM>, <NUM>. Alternatively, the first and second conductor wires <NUM>, <NUM> may be twisted upon one another to form a twisted pair cable. As another example, the dielectric material <NUM> may be a plastic material. The first and second conductor wires <NUM>, <NUM> may form a coaxial structure in which the plastic dielectric material <NUM> separates the first and second conductor wires. As another example, the first and second conductor wires may be configured as planar strips.

The coupling electronics portion <NUM> is operably and communicatively coupled to the RF driver unit <NUM>, the data acquisition unit <NUM>, controller unit <NUM>, and/or data processing unit <NUM> to allow the RF coil <NUM> to transmit and/or receive RF signals. In the illustrated embodiment, the coupling electronics portion <NUM> includes a signal interface <NUM> configured to transmit and receive the RF signals. The signal interface <NUM> may transmit and receive the RF signals via a cable. The cable may be a <NUM>-conductor triaxial cable having a center conductor, an inner shield, and an outer shield. The center conductor is connected to the RF signal and pre-amp control (RF), the inner shield is connected to ground (GND), and the outer shield is connected to the multi-control bias (diode decoupling control) (MC_BIAS). A 10V power connection may be carried on the same conductor as the RF signal.

As explained above with respect to <FIG>, the coupling electronics portion <NUM> includes a decoupling circuit, impedance inverter circuit, and pre-amplifier. As illustrated in <FIG>, the decoupling circuit includes a decoupling diode <NUM>. The decoupling diode <NUM> may be provided with voltage from MC_BIAS, for example, in order to turn decoupling diode <NUM> on. When on, decoupling diode <NUM> causes conductor <NUM> to short with conductor <NUM>, thus causing the coil to be off-resonance and hence decouple the coil during a transmit operation, for example.

It should be understood that the decoupling circuit shown in <FIG> is for illustration not for limitation. Any appropriate decoupling configuration can be used to decouple the RF coil during the transmit operation.

The impedance inverter circuit includes a plurality of inductors, including first inductor 370a, second inductor 370b, and third inductor 370c; a plurality of capacitors, including first capacitor 372a, a second capacitor 372b, a third capacitor 372c, and a fourth capacitor 372d; and a diode <NUM>. The impedance inverter circuit includes matching circuitry and an input balun. As shown, the input balun is a lattice balun that comprises first inductor 370a, second inductor 370b, first capacitor 372a, and second capacitor 372b. In one example, diode <NUM> limits the direction of current flow to block RF receive signals from proceeding into decoupling bias branch (MC_BIAS).

The pre-amplifier <NUM> may be a low input impedance pre-amplifier that is optimized for high source impedance by the impedance matching circuitry. The pre-amplifier may have a low noise reflection coefficient, γ, and a low noise resistance, Rn. In one example, the pre-amplifier may have a source reflection coefficient of γ substantially equal to <NUM> and a normalized noise resistance of Rn substantially equal to <NUM> in addition to the low noise figure. However, γ values substantially equal to or less than <NUM> and Rn values substantially equal to or less than <NUM> are also contemplated. With the pre-amplifier having the appropriate γ and Rn values, the pre-amplifier provides a blocking impedance for RF coil <NUM> while also providing a large noise circle in the context of a Smith Chart. As such, current in RF coil <NUM> is minimized, the pre-amplifier is effectively noise matched with RF coil <NUM> output impedance. Having a large noise circle, the pre-amplifier yields an effective SNR over a variety of RF coil impedances while producing a high blocking impedance to RF coil <NUM>.

In some examples, the pre-amplifier <NUM> may include an impedance transformer that includes a capacitor and an inductor. The impedance transformer may be configured to alter the impedance of the pre-amplifier to effectively cancel out a reactance of the pre-amplifier, such as capacitance caused by a parasitic capacitance effect. Parasitic capacitance effects can be caused by, for example, a PCB layout of the pre-amplifier or by a gate of the pre-amplifier. Further, such reactance can often increase as the frequency increases. Advantageously, however, configuring the impedance transformer of the pre-amplifier to cancel, or at least minimize, reactance maintains a high impedance (i.e. a blocking impedance) to RF coil <NUM> and an effective SNR without having a substantial impact on the noise figure of the pre-amplifier. The lattice balun described above may be a non-limiting example of an impedance transformer.

In examples, the pre-amplifier described herein may be a low input impedance pre-amplifier. For example, in some embodiments, a "relatively low" input impedance of the preamplifier is less than approximately <NUM> ohms at resonance frequency. The coil impedance of the RF coil <NUM> may have any value, which may be dependent on coil loading, coil size, field strength, and/or the like. Examples of the coil impedance of the RF coil <NUM> include, but are not limited to, between approximately <NUM> ohms and approximately <NUM> ohms at <NUM> T magnetic field strength, and/or the like. The impedance inverter circuitry is configured to transform the coil impedance of the RF coil <NUM> into a relatively high source impedance. For example, in some embodiments, a "relatively high" source impedance is at least approximately <NUM> ohms and may be greater than <NUM> ohms.

The impedance transformer may also provide a blocking impedance to the RF coil <NUM>. Transformation of the coil impedance of the RF coil <NUM> to a relative high source impedance may enable the impedance transformer to provide a higher blocking impedance to the RF coil <NUM>. Exemplary values for such higher blocking impedances include, for example, a blocking impedance of at least <NUM> ohms, and at least <NUM> ohms.

<FIG> is a schematic of an RF coil <NUM> and coupling electronics portion <NUM> according to another embodiment. The RF coil of <FIG> is a non-limiting example of the RF coil and coupling electronics of <FIG>, and as such includes a loop portion <NUM> and coupling electronics portion <NUM>. The coupling electronics allows the RF coil to transmit and/or receive RF signals when driven by the data acquisition unit <NUM> (shown in <FIG>). The RF coil <NUM> includes a first conductor wire <NUM> in parallel with a second conductor wire <NUM>. At least one of the first and second conductor wires <NUM>, <NUM> are elongated and continuous.

In the illustrated embodiment, the first and second conductor wires <NUM>, <NUM> are shaped into a loop portion that terminates to an interface. But in other embodiments, other shapes are possible. For example, the loop portion may be a polygon, shaped to conform the contours of a surface (e.g., housing), and/or the like. The loop portion defines a conductive pathway along the first and second conductor wires <NUM>, <NUM>. The first and second conductor wires <NUM>, <NUM> are void of any discrete or lumped capacitive or inductive components along an entire length of the conductive pathway. The first and second conductor wires <NUM>, <NUM> are uninterrupted and continuous along an entire length of the loop portion. The loop portion may also include loops of varying gauge of stranded or solid conductor wire, loops of varying diameters with varying lengths of the first and second conductor wires <NUM>, <NUM>, and/or loops of varying spacing between the first and second conductors. For example, each of the first and second conductors may have no cuts or gaps (no segmented conductors) or one or more cuts or gaps (segmented conductors) at various locations along the conductive pathway.

The first and second conductor wires <NUM>, <NUM> have a distributed capacitance along the length of the loop portion (e.g., along the length of the first and second conductor wires <NUM>, <NUM>). The first and second conductor wires <NUM>, <NUM> exhibit a substantially even and uniform capacitance along the entire length of the loop portion. Distributed capacitance (DCAP), as used herein, represents a capacitance exhibited between conductors along the length of the conductors and is void of discrete or lumped capacitive components and discrete or lumped inductive components. In the examples herein, the capacitance may grow in an even and uniform manner along the length of the first and second conductor wires <NUM>, <NUM>. At least one of the first and second conductor wires <NUM>, <NUM> are elongated and continuous. In the illustrated embodiment, both the first and second conductor wires <NUM>, <NUM> are elongated and continuous. But in other embodiments, only one of the first or second conductor wires <NUM>, <NUM> may be elongated and continuous. The first and second conductor wires <NUM>, <NUM> form continuous distributed capacitors. The capacitance grows at a substantially constant rate along the length of the conductor wires <NUM>, <NUM>. In the illustrated embodiment, the first and second conductor wires <NUM>, <NUM> form elongated continuous conductors that exhibits DCAP along the length of the first and second conductor wires <NUM>, <NUM>. The first and second conductor wires <NUM>, <NUM> are void of any discrete capacitive and inductive components along the entire length of the continuous conductors between terminating ends of the first and second conductor wires <NUM>, <NUM>. For example, the first and second conductor wires <NUM>, <NUM> do not include any discrete capacitors, nor any inductors along the length of the loop portion.

A dielectric material <NUM> separates the first and second conductor wires <NUM>, <NUM>. The dielectric material <NUM> may be selectively chosen to achieve a desired distributive capacitance. The dielectric material <NUM> may be based on a desired permittivity ε to vary the effective capacitance of the loop portion. For example, the dielectric material <NUM> may be air, rubber, plastic, or any other dielectric material. In one example, the dielectric material may be polytetrafluoroethylene (pTFE). For example, the dielectric material <NUM> may be an insulating material surrounding the parallel conductive elements of the first and second conductor wires <NUM>, <NUM>. Alternatively, the first and second conductor wires <NUM>, <NUM> may be twisted upon one another to from a twisted pair cable. As another example, the dielectric material <NUM> may be a plastic material. The first and second conductor wires <NUM>, <NUM> may form a coaxial structure in which the plastic dielectric material <NUM> separates the first and second conductor wires <NUM>, <NUM>. As another example, the first and second conductor wires <NUM>, <NUM> may be configured as planar strips.

The first conductor wire <NUM> includes a first terminating end <NUM> and a second terminating end <NUM> that terminates at the interface. The first terminating end <NUM> is coupled to the coupling electronics portion <NUM>. The first terminating end <NUM> may also be referred to herein as a "drive end. " The second terminating end <NUM> is also referred to herein as a "second drive end.

The second conductor <NUM> includes a first terminating end <NUM> and a second terminating end <NUM> that terminates at the interface. The first terminating end <NUM> is coupled to the coupling electronics portion <NUM>. The first terminating end <NUM> may also be referred to herein as a "drive end. " The second terminating end <NUM> is also referred to herein as a "second drive end.

The loop portion <NUM> of the RF coil <NUM> is coupled to coupling electronics portion <NUM>. The coupling electronics portion <NUM> may be the same coupling electronics described above with respect to <FIG> and <FIG>, and hence like reference numbers are given to like components and further description is dispensed with.

As appreciated by <FIG> and <FIG>, the two parallel conductor wires forming the loop portion of an RF coil may each be continuous, as illustrated in <FIG>, or one or both of the conductors may be non-continuous, as illustrated in <FIG>. For example, both conductor wires shown in <FIG> may include cuts, resulting in each conductor being comprised of two segments. The resulting space between conductor segments may be filled with the dielectric material that encapsulates and surrounds the conductors. The two cuts may be positioned at different locations, e.g., one cut at <NUM>° and the other cut at <NUM>° (relative to where the loop portion interfaces with the coupling electronics). By including discontinuous segments, the resonance frequency of the coil may be adjusted. For example, for an RF coil that includes two continuous parallel conductor wires encapsulated and separated by a dielectric, the resonance frequency may be a smaller, first resonance frequency. If the RF coil instead includes one discontinuous conductor wire (e.g., where one of the conductors is cut and filled with the dielectric material) and one continuous conductor wire, with all other parameters (e.g., conductor diameter, loop diameter, dielectric material) being the same, the resonance frequency of the RF coil may be a larger, second resonance frequency. In this way, parameters of the loop portion, including conductor wire gauge, loop diameter, spacing between conductors, dielectric material selection and/or thickness, and conductor segment number and lengths, may be adjusted to tune the RF coil to a desired resonance frequency.

The RF coils described herein (e.g., the RF coils described above with respect to <FIG>) generate distributed (also referred to as incorporated) capacitance between two conductor wires (e.g., between the two looped wires). The distributed capacitance results from the approximately linear varying currents in the two conductor wires: in one conductor wire, the current linearly ascends and in the other conductor wire, current linearly descends. From the continuity equation (∇·j+∂tρ=<NUM>), current linearly varying along its path leads to constant positive charge distribution. Linearly descending current leads to constant negative charge distribution. Referring to <FIG> as an example, current may descend in conductor wire <NUM> and may ascend in conductor wire <NUM>. In this way, the loop portion of the RF coils described herein may act as a folded electric dipole antenna, where common mode current is approximately constant and the current on the different wires (e.g., non-common mode current) varies along the circumference of the wires.

<FIG> shows a cross-sectional view <NUM> of loop portion <NUM> of RF coil <NUM> taken across line A-A' of <FIG>. As appreciated by <FIG>, loop portion <NUM> of RF coil <NUM> includes first conductor wire <NUM> and second conductor wire <NUM> surrounded by and encapsulated in dielectric material <NUM>. Each conductor may have a suitable cross-sectional shape, herein a circular cross-sectional shape having a radius r. However, other cross-sectional shapes for the conductors are possible, such as rectangular, triangular, hexagonal, etc. The conductors may be separated by a suitable distance d (where d is the distance between the centers of the conductors). In one example, the radius r of each conductor may be <NUM> and the distance d between conductors may be <NUM>, but other dimensions are possible and may be selected to achieve a desired capacitance. As shown, first conductor wire <NUM> flows current in a descending manner, represented by the minus symbol and also referred to herein as descending current. Second conductor wire <NUM> flows current in an ascending manner, represented by the plus symbol and also referred to herein as ascending current.

As explained above, by adjusting one or more of the distance d between the conductors, diameter of the conductors, number of cuts to the conductors, and the properties of the dielectric material, the capacitance of the loop portion may be adjusted. However, for some MRI applications, an RF coil comprising only two conductors may not provide sufficient capacitance. For example, imaging of carbon <NUM> may be performed at a low resonance frequency of <NUM> megahertz (MHz), which requires larger capacitance than what two conductor wires can provide. Another mechanism by which RF coil loop capacitance may be adjusted includes adjusting the number of conductors included in the loop portion. <FIG>, described in more detail below, illustrate example RF coil configurations that include more than two conductor wires.

<FIG> shows a loop portion <NUM> of an RF coil including four parallel conductor wires. <FIG> shows a cross-sectional view <NUM> of the loop portion <NUM> of the RF coil of <FIG>. Loop portion <NUM> includes four conductor wires including first conductor wire <NUM>, second conductor wire <NUM>, third conductor wire <NUM>, and fourth conductor wire <NUM>, all encapsulated in a common dielectric material <NUM> (illustrated in <FIG>). Similar to the RF coils described above, each conductor wire may be a conductive wire or strip, such as a copper wire, and the dielectric material may be pTFE, rubber, or other suitable dielectric material. <FIG> shows the four conductor wires somewhat schematically (e.g., flattened and/or on the same plane) for visual purposes, but it is to be understood that the actual planar arrangement of the conductors may differ from that shown in <FIG>, such as the arrangement shown in <FIG> and described in more detail below.

The RF coil illustrated in <FIG> may include some similar features as the RF coils described above with respect to <FIG>, including the loop portion <NUM> being coupled to coupling electronics at an interface. To facilitate the coupling to the coupling electronics, the first conductor <NUM> includes a first terminating end <NUM>, similar to the first terminating end <NUM> described above with respect to <FIG>. The first conductor <NUM> is electrically coupled to the third conductor <NUM> at a second terminating end <NUM> that terminates at the interface, similar to the second terminating end <NUM> of <FIG>. The first terminating end <NUM> is coupled to the coupling electronics. The first terminating end <NUM> may also be referred to herein as a "drive end. " The second terminating end <NUM> is also referred to herein as a "second drive end.

The second conductor <NUM> may be electrically coupled to the fourth conductor <NUM> at a first terminating end <NUM> that is coupled to the coupling electronics, similar to the first terminating end <NUM> of <FIG>. Fourth conductor <NUM> includes a second terminating end <NUM> that terminates at the interface, similar to the second terminating end <NUM> of <FIG>. The first terminating end <NUM> may also be referred to herein as a "drive end. " The second terminating end <NUM> is also referred to herein as a "second drive end. " In this way, the loop portion <NUM> is coupled to coupling electronics, and the coupling electronics may be the same coupling electronics described above with respect to <FIG> and <FIG>. The second conductor <NUM> and the third conductor <NUM> may each have a floating end embedded in the loop portion.

The four conductors may be arranged into a pair of vertical conductors (including first conductor <NUM> and third conductor <NUM>) and a pair of horizontal conductors (including second conductor <NUM> and fourth conductor <NUM>). The vertical conductors, as shown, may flow ascending current while the horizontal conductors may flow descending current. By including four conductor wires arranged into two parallel pairs, the capacitance of the loop portion <NUM> may be increased relative to a loop that includes only two conductors. For example, the conductor wires shown in <FIG> may have the same radius r and be comprised of the same material as the conductors illustrated in <FIG> (e.g., r of <NUM>) and may be spaced apart by the same distance d (at least adjacent conductors may be spaced apart by the distance d, while non-adjacent conductors may be spaced apart by a larger distance), such as <NUM>, of the same dielectric material as the loop portion illustrated in <FIG>. The additional conductor wires may increase the capacitance of the loop portion, for example from approximately <NUM> pF to approximately <NUM> pF.

A further mechanism by which the capacitance of a loop portion of an RF coil may be adjusted includes the type of dielectric material comprising the core of the loop portion. Referring to <FIG> as an example, loop portion <NUM> includes a core <NUM>, around which the four conductors are arranged. Core <NUM> may be a hollowed out tube in the dielectric material <NUM>, traversing along the loop portion. Core <NUM> may be maintained hollow (e.g., filled with air) in one example. In other examples, core <NUM> may be filled with material having the same as or different dielectric properties than the material comprising dielectric material <NUM>, such as pTFE, water, ceramic, and so forth. As the relative permittivity of the core material increases, the capacitance of the loop portion also increases. For example, if the core is left follow (e.g., filled with air), the loop portion may have a lower, first capacitance. If the core is filled with pTFE, the loop portion may have a higher, second capacitance. If the core is filled with water, the loop portion may have an even higher, third capacitance.

While <FIG> show an RF coil loop portion including four conductor wires, more or fewer conductors are possible, such as three conductors. An even number of interleaved wires assures uniform distribution of the charge along the loop path and good confinement of the electric field within the multicore wire. An odd number of wires in principle is possible, but may be prone to wavelength effects - nonuniform charge distribution along the loop path.

<FIG> shows a loop portion <NUM> of an RF coil including six parallel conductor wires. <FIG> shows a cross-sectional view <NUM> of the loop portion <NUM> of the RF coil of <FIG>. Loop portion <NUM> includes six conductor wires including first conductor wire <NUM>, second conductor wire <NUM>, third conductor wire <NUM>, fourth conductor wire <NUM>, fifth conductor wire <NUM>, and sixth conductor wire <NUM>, all encapsulated in a common dielectric material <NUM> (illustrated in <FIG>). Similar to the RF coils described above, each conductor may be a conductive wire or strip, such as a copper wire, and the dielectric material may be pTFE, rubber, or other suitable dielectric material. <FIG> shows the six conductors somewhat schematically (e.g., flattened and/or on the same plane) for visual purposes, but it is to be understood that the actual planar arrangement of the conductors may differ from that shown in <FIG>, such as the arrangement shown in <FIG> and described in more detail below.

The RF coil illustrated in <FIG> may include some similar features as the RF coils described above with respect to <FIG>, including the loop portion <NUM> being coupled to coupling electronics at an interface. To facilitate the coupling to the coupling electronics, the first conductor <NUM> wire is electrically coupled to the third conductor wire <NUM> and to the fifth conductor wire <NUM> at a first terminating end <NUM> that terminates at the interface, similar to the first terminating end <NUM> of <FIG>. The first terminating end <NUM> is coupled to the coupling electronics. The first conductor wire <NUM> also includes a second terminating end <NUM> that terminates at the interface, similar to the second terminating end <NUM> of <FIG>.

The second conductor wire <NUM> may be electrically coupled to the fourth conductor wire <NUM> and the sixth conductor wire <NUM> at a first terminating end <NUM> that is coupled to the coupling electronics, similar to the first terminating end <NUM> of <FIG>. Sixth conductor wire <NUM> includes a second terminating end <NUM> that terminates at the interface, similar to the second terminating end <NUM> of <FIG>. In this way, the loop portion <NUM> is coupled to coupling electronics, and the coupling electronics may be the same coupling electronics described above with respect to <FIG> and <FIG>. The second conductor wire <NUM>, the third conductor wire <NUM>, the fourth conductor wire <NUM>, and the fifth conductor wire <NUM> may each have a floating end embedded in the loop portion.

As shown in <FIG>, the loop portion <NUM> includes the six conductor wires arranged in a hexagonal manner. The loop portion may be configured (e.g., coupled to the coupling electronics in such a manner) to flow ascending and descending current in an every-other configuration. For example, first conductor wire <NUM>, third conductor wire <NUM>, and fifth conductor wire <NUM> may each flow ascending current, while second conductor wire <NUM>, fourth conductor wire <NUM>, and sixth conductor wire <NUM> may each flow descending current. Each conductor wire may have the same radius r (such as <NUM>, similar to the conductors described above with respect to <FIG> and <FIG>) and be spaced apart by the same distance d (such as <NUM> as described above). The conductor wires may each be comprised of copper wire, for example, and the dielectric material <NUM> may be pTFE, rubber, or the like. Due to the presence of six conductor wires, the loop portion <NUM> may have a higher capacitance than loop portion <NUM> of <FIG>. In one example, the capacitance of loop portion <NUM> may be approximately <NUM> pF.

Further, loop portion <NUM> may include a core <NUM>, around which the six conductor wires are arranged. Core <NUM> may be a hollowed out tube in the dielectric material <NUM>, traversing along the loop portion. Core <NUM> may be maintained hollow (e.g., filled with air) in one example. In other examples, core <NUM> may be filled with material having the same or different dielectric properties that the material comprising dielectric material <NUM>, such as pTFE, water, ceramic, and so forth. As the relative permittivity of the core material increases, the capacitance of the loop portion also increases. For example, if the core is left follow (e.g., filled with air), the loop portion may have a lower, first capacitance. If the core is filled with pTFE, the loop portion may have a higher, second capacitance. If the core is filled with water, the loop portion may have an even higher, third capacitance. Further, the core <NUM> (as well as core <NUM> of <FIG>) may have a diameter that is selected to achieve a desired capacitance. In an example, the core may have a maximum diameter that is a function of wire spacing and wire diameter. For example, the maximum diameter of the core may be twice the distance between the wires (the distance d of <FIG>) minus the twice the radius of the wires (the radius r of <FIG>). In the examples presented above where the distance is <NUM> and the radius is <NUM>, the core may have a maximum diameter of <NUM>.

In this way, by varying the number of conductive wires, wire diameter, number of cuts in the wire, dielectric material, and/or other parameters, a broad range of distributed capacitance per unit length of the loop portion of the RF coil may be achieved, which may allow the RF coil to be operated at a resonance frequency suited to a particular MRI environment (e.g., <NUM> T versus <NUM> T). As explained above, by increasing the number of conductive wires, the capacitance may be increased. The capacitance may additionally or alternatively be varied by modifying the dielectric material core within the RF coil loop portion cross-section. Further, in some examples, to modify the capacitance of the RF coil loop portion, one or more cuts may be present on one or more of the conductors. When the RF coil loop portion includes more than two conductors (e.g., four or six parallel wires as described above with respect to <FIG> and <FIG>), the cuts to the conductors may be made only on the conductors flowing ascending current and not on the conductors flowing descending current, or vice versa.

<FIG> is a graph <NUM> illustrating conductor current as a function of conductor length (in the example shown, the conductor circumference for looped conductors), for conductors with descending current (plot <NUM>) and conductors with ascending current (plot <NUM>). As appreciated by <FIG>, the current may descend linearly along a length of one conductor wire (shown by plot <NUM>) and ascend linearly (in an amount proportional to the amount of descending current) along the length of the other conductor wire (shown by plot <NUM>).

<FIG> illustrate various additional RF coil loop portion configurations. Each coil loop portion illustrated in <FIG> is a cross-section of a loop portion, similar to the cross-sectional views shown in <FIG>, <FIG>, and <FIG>. Further, each loop portion illustrated in <FIG> may be coupled to a respective coupling electronics portion in a manner similar to that described above with respect to <FIG> and <FIG>.

<FIG> shows an example coaxial coil loop portion <NUM> that includes a round center conductor wire <NUM>, an outer concentric shield <NUM>, and a dielectric material <NUM> in between. The center conductor wire <NUM> may be similar to the conductor wires described above with respect to <FIG> (e.g., comprised of copper wire) and the dielectric material <NUM> may be similar to the dielectric materials described above (e.g., comprised of pTFE). The outer concentric shield <NUM> may encase or otherwise surround the dielectric material <NUM> and center conductor wire <NUM> and may be comprised of braided copper or other suitable conductive material. The center conductor, dielectric material, and outer shield all share a common central axis. Further, while not shown in <FIG>, in some examples an outer jacket (e.g., comprised of dielectric material) may surround the outer shield <NUM>. While two coaxial conductors (center conductor wire <NUM> and outer shield <NUM>) are shown in <FIG>, an RF coil loop portion may include three or more coaxial conductors, encapsulated and separated from each other by dielectric material.

<FIG> shows another example coaxial loop portion <NUM> that includes am inner shield <NUM>, an outer concentric shield <NUM>, and a dielectric material <NUM> in between. The dielectric material may be similar to the dielectric materials described above (e.g., comprised of pTFE). The inner shield <NUM> and outer concentric shield <NUM> may be comprised of braided copper or other suitable conductive material. The outer concentric shield <NUM> may encase or otherwise surround the dielectric material and inner shield. The inner shield <NUM> may surround a hollow core, or the inner shield <NUM> may surround a core comprising a dielectric material. The inner shield, dielectric material, and outer shield all share a common central axis. Further, while not shown in <FIG>, in some examples an outer jacket (e.g., comprised of dielectric material) may surround the outer shield <NUM>. While two coaxial conductors (inner shield <NUM> and outer shield <NUM>) are shown in <FIG>, an RF coil loop portion may include three or more coaxial shields, encapsulated and separated from each other by dielectric material.

<FIG> shows an example coil loop portion <NUM> comprised of micro-strip conductors, including a first micro-strip conductor <NUM> and a second micro-strip conductor <NUM> separated by (and encased in) a dielectric material <NUM>. The dielectric material may be similar to the dielectric materials described above (e.g., comprised of pTFE). The micro-strip conductors may be rectangular (in cross-section) parallel conductors that may be comprised of copper and may be looped in a manner similar to the wire loops described above with respect to <FIG>. Further, while two micro-strip conductors are shown in <FIG>, an RF coil loop portion may include more than two micro-strips in parallel, with adjacent micro-strips separated by dielectric material.

The RF coils presented above with respect to <FIG> and <FIG> may be utilized in order to receive MR signals during an MR imaging session. As such, the RF coils of <FIG> and <FIG>may be non-limiting examples of elements in RF coil unit <NUM> of <FIG> and may be configured to be coupled to a downstream component of the MRI system, such as a processing system. The RF coils of <FIG> and <FIG> may be present in an array of RF coils having various configurations. <FIG> illustrates various embodiments for RF coil arrays and accompanying coil-interfacing cables that may include one or more of the RF coils described above with respect to <FIG> and <NUM>-<NUM>.

First RF coil array <NUM> includes a coil loop and an electronics unit coupled to each coil loop, and a coil-interfacing cable connected to and extending from each coupling electronics unit. Accordingly, RF coil array <NUM> includes four coil loops, four electronics units, and four coil-interfacing cables. For example, one RF coil of RF coil array <NUM> includes a loop portion <NUM>, electronics unit <NUM>, and coil-interfacing cable <NUM>. Loop portion <NUM> may include a suitable number of conductors, such as two conductor wires (similar to the RF coils illustrated in <FIG> and <FIG>), four conductor wires (similar to the RF coil loop portion illustrated in <FIG>), or six conductor wires (similar to the RF coil loop portion illustrated in <FIG>).

Second RF coil array <NUM> includes a separate electronics unit for each coil loop, with each electronics unit coupled to a respective coil-interfacing cable. Array <NUM> includes four coil loops, four electronics units, and four coil-interfacing cables that are bundled together in a single grouping of four coil-interfacing cables, and may be referred to as an integrated balun cable harness. For example, the two coil-interfacing cables coupled to the two top electronics units are bundled together, and they are bundled with the two coil-interfacing cables from the two bottom electronics units. Similar to the RF coil array described above, each coil loop of each RF coil in array <NUM> may include two or more conductors.

Third RF coil array <NUM> includes a separate electronics unit for each coil loop, with each electronics unit coupled to a respective coil-interfacing cable. Array <NUM> includes four coil loops, four electronics units, and four coil-interfacing cables that are bundled together in a single grouping of four coil-interfacing cables, and may be referred to as an integrated balun cable harness. Similar to the RF coil arrays described above, each coil loop of each RF coil in array <NUM> may include two or more conductors.

The individual coupling electronics units may be housed in a common electronics housing in some examples. Each coil loop of the coil array may have respective coupling electronics unit (e.g., a decoupling circuit, impedance inverter circuit, and pre-amplifier) housed in the housing. In some examples, the common electronics housing may be detachable from the coil loop or RF coil array. In particular, if the individual coupling electronics are configured as in the RF coil array <NUM> of <FIG>, the electronics may be placed in a separable assembly and disconnected from the coil array. A connector interface could be placed at, for example, the junctions between the conductor loop portions (e.g., the drive ends described above) and the coupling electronics for each individual coupling electronics unit.

The conductor wires and coil loops used in the RF coil or RF coil array may be manufactured in any suitable manner to get the desired resonance frequency for a desired RF coil application. The desired conductor wire gauge, such as <NUM> or <NUM> American Wire Gauge (AWG) or any other desired wire gauge may be paired with one or more parallel conductor wires of the same gauge and encapsulated with a dielectric material using an extrusion process or a three-dimensional (3D) printing or additive manufacturing process. This manufacturing process may be environmentally friendly with low waste and low-cost.

Thus, the RF coil described herein includes a twin lead, triplet lead, quadruplet lead, sextuplet lead, or other suitable lead conductor wire loop encapsulated in a pTFE dielectric with optional cut(s) in one or more of the parallel conductors and a miniaturized coupling electronics PCB coupled to each coil loop (e.g., very small coupling electronics PCB approximately the size of <NUM><NUM> or smaller). The PCBs may be protected with a conformal coating or an encapsulation resin. In doing so, traditional components are eliminated and capacitance is "built in" the integrated capacitor (INCA) coil loops. Interactions between coil elements are reduced or eliminated. The coil loops are adaptable to a broad range of MR operating frequencies by changing the gauge of conductor wire used, spacing between conductor wires, number of conductors, loop diameters, loop shapes, dielectric material, loop core material, and the number and placement of cuts in the conductor wires. The coil loops are transparent in PET/MR applications, aiding dose management and signal-to-noise ratios (SNR). The miniaturized coupling electronics PCB includes decoupling circuitry, impedance inverter circuitry with impedance matching circuitry and an input balun, and a pre-amplifier. The pre-amplifier sets new standards in coil array applications for lowest noise, robustness, and transparency. The pre-amplifier provides active noise cancelling to reduce current noise, boost linearity, and improve tolerance to varying coil loading conditions. Additionally, as explained in more detail below, a cable harness with baluns for coupling each of the miniaturized coupling electronics PCBs to the RF coil array connector that interfaces with the MRI system may be provided.

The RF coil described herein is exceptionally lightweight, and may weigh less than <NUM> grams per coil element versus <NUM> grams per coil element with General Electric Company's Geometry Embracing Method (GEMS) suite of flexible RF coil arrays. For example, a <NUM>-channel RF coil array according to the disclosure may weigh less than <NUM>. The RF coil described herein is exceptionally flexible and durable as the coil is extremely simple with very few rigid components and allowing floating overlaps. The RF coil described herein is exceptionally low-cost, e.g., greater than ten times reduction from current technology. For example, a <NUM>-channel RF coil array could be comprised of components and materials of less than $<NUM>. The RF coil described herein does not preclude current packaging or emerging technologies and could be implemented in RF coil arrays that do not need to be packaged or attached to a former, or implemented in RF coil arrays that are attached to flexible formers as flexible RF coil arrays or attached to rigid formers as rigid RF coil arrays.

The combination of an INCA coil loop and associated coupling electronics is a single coil element, which is functionally independent and electrically immune to its surrounding environment or neighboring coil elements. As a result, the RF coil described herein performs equally well in low and high-density coil array applications. The exceptional isolation between coil elements allows the overlap between coil elements to be maximized without degrading performance across coil elements. This allows for a higher density of coil elements than is possible with traditional RF coil array designs.

In contrast to the RF coil arrays described herein, a traditional RF coil array may include four RF coil loops that include copper traced on PCB, which is rigid and maintains the RF coils at fixed positions relative to each other. Traditional RF coils include lumped elements (e.g., capacitors) and a relatively large set of coupling electronics, as compared to the electronics of the RF coil arrays described herein. For example, a traditional RF coil array includes a PCB on which copper traces are formed and lumped elements are present. A set of coupling electronics may include bulky and rigid elements, such as a balun. Further, due to the configuration of the traditional RF coil array (e.g., due to heat generation by the coil array), a rigid and/or bulky housing material is required. Further, the traditional RF coil array may comprise only a portion of a traditional overall RF coil array element actually used during MR imaging. For example, a traditional overall RF coil array element may include four separate traditional RF coil arrays, further increasing the size, weight, and cost of a traditional overall RF coil array element.

The RF coils described herein are not supported by or surrounded by a substrate. While the wires in the RF coil loops are encapsulated in dielectric material, at least in some examples, no other substrates are present around the entirety of the RF coils. The RF coils may be housed in fabric or other flexible enclosures, but the RF coils may remain flexible in multiple dimensions and may not be fixedly connected to one another. In some examples, the RF coils may be slidably movable relative to each other, such that varying amounts of overlap among coil elements is provided. In contrast, the coil elements of a traditional RF array are fixed in position relative to each other and are surrounded by substrate (e.g., PCB). Thus, even when the substrate is flexible, the movement of the coil elements of a traditional RF coil array is limited.

The image quality generated by signals received by an RF coil may be defined by a quality factor, referred as Q. In an RF coil, Q is defined as Q=ωL/R where L is the coil inductance, R is the circuit resistance, and ω is the angular frequency. An increasing Q results in an increased SNR and a sharper frequency response. The Q value is inversely related to the fraction of energy in an oscillation system lost in oscillation cycle. Accordingly, to increase SNR, it may be desirable to generate an RF coil array with a relatively high Q value. Q may be determined during an unloaded state where no patient is present during imaging, which is referred to as the unloaded Q of an RF coil. The RF coils described herein may have varying unloaded Q depending on the number of conductors present. For example, twin lead RF coils (such as those described above with respect to <FIG> and <FIG>) may have relatively low unloaded Q, which may be lower than the unloaded Q of a traditional copper trace RF coil. In contrast, the RF coils that include an increased number of conductors, such as the RF coil described above with respect to <FIG> that includes six conductors, may have an unloaded Q similar to the unloaded Q of a traditional copper trace RF coil.

As mentioned previously, the RF coil array of the present disclosure may be coupled to a RF coil array interfacing cable that includes contiguous, distributed baluns or common-mode traps in order to minimize high currents or standing waves, independent of positioning. High stress areas of the RF coil array interfacing cable may be served by several baluns. Additionally, the thermal load may be shared through a common conductor. The inductance of the central path and return path of the RF coil array interfacing cables are not substantially enhanced by mutual inductance, and therefore are stable with geometry changes. Capacitance is distributed and not substantially varied by geometry changes. Resonator dimensions are ideally very small, but in practice may be limited by blocking requirements, electric and magnetic field intensities, local distortions, thermal and voltage stresses, etc..

<FIG> illustrates a block schematic diagram of a continuous common mode trap assembly <NUM> formed in accordance with various embodiments. The common mode trap assembly <NUM> may be configured, for example, for use in an MRI system, such as the MRI apparatus <NUM> described herein above. For example, in the illustrated embodiment, the common mode trap assembly <NUM> is configured as a transmission cable <NUM> configured for transmission of signals between a processing system <NUM> and a RF coil array <NUM> of an MRI system. Transmission cable <NUM> is a non-limiting example of a RF coil array interfacing cable <NUM>, processing system <NUM> is a non-limiting example of controller unit <NUM>, and RF coil array <NUM> is a non-limiting example of a plurality of RF coils <NUM> and coupling electronics portion <NUM> of <FIG>.

In the illustrated embodiment, the transmission cable <NUM> (or RF coil array interfacing cable) includes a central conductor <NUM> and plural common mode traps <NUM>, <NUM>, <NUM>. It may be noted that, while the common mode traps <NUM>, <NUM>, and <NUM> are depicted as distinct from the central conductor <NUM>, in some embodiments, the common mode traps <NUM>, <NUM>, <NUM> may be integrally formed with or as a part of the central conductor <NUM>.

The central conductor <NUM> in the illustrated embodiment has a length <NUM>, and is configured to transmit a signal between the MRI RF coil array <NUM> and at least one processor of an MRI system (e.g., processing system <NUM>). The central conductor <NUM> may include one or more of a ribbon conductor, a wire, or a coaxial cable bundle, for example. The length <NUM> of the depicted central conductor <NUM> extends from a first end of the central conductor <NUM> (which is coupled to the processing system <NUM>) to a second end of the central conductor <NUM> (which is coupled to the RF coil array <NUM>). In some embodiments, the central conductor may pass through a central opening of the common mode traps <NUM>, <NUM>, <NUM>.

The depicted common mode traps <NUM>, <NUM>, <NUM> (which may be understood as cooperating to form a common mode trap unit <NUM>), as seen in <FIG>, extend along at least a portion of the length <NUM> of the central conductor <NUM>. In the illustrated embodiment, common mode traps <NUM>, <NUM>, <NUM> do not extend along the entire length <NUM>. However, in other embodiments, the common mode traps <NUM>, <NUM>, <NUM> may extend along the entire length <NUM>, or substantially along the entire length <NUM> (e.g., along the entire length <NUM> except for portions at the end configured to couple, for example, to a processor or RF coil array). The common mode traps <NUM>, <NUM>, <NUM> are disposed contiguously. As seen in <FIG>, each of the common mode traps <NUM>, <NUM>, <NUM> is disposed contiguously to at least one other of the common mode traps <NUM>, <NUM>, <NUM>. As used herein, contiguous may be understood as including components or aspects that are immediately next to or in contact with each other. For example, contiguous components may be abutting one another. It may be noted that in practice, small or insubstantial gaps may be between contiguous components in some embodiments. In some embodiments, an insubstantial gap (or conductor length) may be understood as being less than <NUM>/<NUM>th of a wavelength of a transmit frequency in free space. In some embodiments, an insubstantial gap (or conductor length) may be understood as being two centimeters or less. Contiguous common mode traps, for example, have no (or insubstantial) intervening gaps or conductors therebetween that may be susceptible to induction of current from a magnetic field without mitigation provided by a common mode trap.

For example, as depicted in <FIG>, the common mode trap <NUM> is contiguous to the common mode trap <NUM>, the common mode trap <NUM> is contiguous to the common mode trap <NUM> and the common mode trap <NUM> (and is interposed between the common mode trap <NUM> and the common mode trap <NUM>), and the common mode trap <NUM> is contiguous to the common mode trap <NUM>. Each of the common mode traps <NUM>, <NUM>, <NUM> are configured to provide an impedance to the receive transmitter driven currents of an MRI system. The common mode traps <NUM>, <NUM>, <NUM> in various embodiments provide high common mode impedances. Each common mode trap <NUM>, <NUM>, <NUM>, for example, may include a resonant circuit and/or one or more resonant components to provide a desired impedance at or near a desired frequency or within a target frequency range. It may be noted that the common mode traps <NUM>, <NUM>, <NUM> and/or common mode trap unit <NUM> may also be referred to as chokes or baluns by those skilled in the art.

In contrast to systems having separated discrete common mode traps with spaces therebetween, various embodiments (e.g., the common mode trap assembly <NUM>) have a portion over which common mode traps extend continuously and/or contiguously, so that there are no locations along the portion for which a common mode trap is not provided. Accordingly, difficulties in selecting or achieving particular placement locations of common mode traps may be reduced or eliminated, as all locations of interest may be included within the continuous and/or contiguous common mode trap. In various embodiments, a continuous trap portion (e.g., common mode trap unit <NUM>) may extend along a length or portion thereof of a transmission cable. The continuous mode trap portion may be formed of contiguously-joined individual common mode traps or trap sections (e.g., common mode traps <NUM>, <NUM>, <NUM>). Further, contiguous common mode traps may be employed in various embodiments to at least one of lower the interaction with coil elements, distribute heat over a larger area (e.g., to prevent hot spots), or help ensure that blocking is located at desired or required positions. Further, contiguous common mode traps may be employed in various embodiments to help distribute voltage over a larger area. Additionally, continuous and/or contiguous common mode traps in various embodiments provide flexibility. For example, in some embodiments, common mode traps may be formed using a continuous length of conductor(s) (e.g., outer conductors wrapped about a central conductor) or otherwise organized as integrally formed contiguous sections. In various embodiments, the use of contiguous and/or continuous common mode traps (e.g., formed in a cylinder) provide for a range of flexibility over which flexing of the assembly does not substantially change the resonant frequency of the structure, or over which the assembly remains on frequency as it is flexed.

It may be noted that the individual common mode traps or sections (e.g., common mode traps <NUM>, <NUM>, <NUM>) in various embodiments may be constructed or formed generally similarly to each other (e.g., each trap may be a section of a length of tapered wound coils), but each individual trap or section may be configured slightly differently than other traps or sections. For example, in some embodiments, each common mode trap <NUM>, <NUM>, <NUM> is tuned independently. Accordingly, each common mode trap <NUM>, <NUM>, <NUM> may have a resonant frequency that differs from other common mode traps of the same common mode trap assembly <NUM>.

Alternatively or additionally, each common mode trap may be tuned to have a resonant frequency near an operating frequency of the MRI system. As used herein, a common mode trap may be understood as having a resonant frequency near an operating frequency when the resonant frequency defines or corresponds to a band that includes the operating frequency, or when the resonant frequency is close enough to the operating frequency to provide on-frequency blocking, or to provide a blocking impedance at the operating frequency.

Further additionally or alternatively, each common mode trap may be tuned to have a resonant frequency below an operating frequency of the MRI system (or each common mode trap may be tuned to have resonant frequency above an operating frequency of the MRI system). With each trap having a frequency below (or alternatively, with each trap having a frequency above) the operating frequency, the risk of any of the traps canceling each other out (e.g., due to one trap having a frequency above the operating frequency and a different trap having a frequency below the operating frequency) may be eliminated or reduced. As another example, each common mode trap may be tuned to a particular band to provide a broadband common mode trap assembly.

In various embodiments, the common mode traps may have a two (2D) or three-dimensional (3D) butterfly configuration to counteract magnetic field coupling and/or local distortions.

<FIG> is a perspective view of a RF coil array interfacing cable <NUM> including a plurality of continuous and/or contiguous common mode traps according to an embodiment of the disclosure. The RF coil array interfacing cable <NUM> includes an outer sleeve or shield <NUM>, a dielectric spacer <NUM>, an inner sleeve <NUM>, a first common mode trap conductor <NUM>, and a second common mode trap conductor <NUM>.

The first common mode trap conductor <NUM> is wrapped in a spiral about the dielectric spacer <NUM>, or wrapped in a spiral at a tapering distance from a central conductor (not shown) disposed within the bore <NUM> of the RF coil array interfacing cable <NUM>, in a first direction <NUM>. Further, the second common mode trap conductor <NUM> is wrapped in a spiral about the dielectric spacer <NUM>, or wrapped in a spiral at a tapering distance from the central conductor disposed within the bore <NUM>, in a second direction <NUM> that is opposite to the first direction <NUM>. In the illustrated embodiment, the first direction <NUM> is clockwise and the second direction <NUM> is counter-clockwise.

The conductors <NUM> and <NUM> of the RF coil array interfacing cable <NUM> may comprise electrically-conductive material (e.g., metal) and may be shaped as ribbons, wires, and/or cables, for example. In some embodiments, the counterwound or outer conductors <NUM> and <NUM> may serve as a return path for a current passing through the central conductor. Further, in various embodiments, the counterwound conductors <NUM> and <NUM> may cross each other orthogonally (e.g., a center line or path defined by the first common mode trap conductor <NUM> is perpendicular to a center line or path defined by the second common mode trap conductor <NUM> as the common mode trap conductors cross paths) to eliminate, minimize, or reduce coupling between the common mode trap conductors.

It may be further noted that in various embodiments the first common mode trap conductor <NUM> and the second common mode trap conductor <NUM> are loosely wrapped about the dielectric spacer <NUM> to provide flexibility and/or to reduce any binding, coupling, or variation in inductance when the RF coil array interfacing cable <NUM> is bent or flexed. It may be noted that the looseness or tightness of the counterwound outer conductors may vary by application (e.g., based on the relative sizes of the conductors and dielectric spacer, the amount of bending or flexing that is desired for the common mode trap, or the like). Generally, the outer or counterwound conductors should be tight enough so that they remain in the same general orientation about the dielectric spacer <NUM>, but loose enough to allow a sufficient amount of slack or movement during bending or flexing of the RF coil array interfacing cable <NUM> to avoid, minimize, or reduce coupling or binding of the counterwound outer conductors.

In the illustrated embodiment, the outer shielding <NUM> is discontinuous in the middle of the RF coil array interfacing cable <NUM> to expose a portion of the dielectric spacer <NUM> which in some embodiments is provided along the entire length of the RF coil array interfacing cable <NUM>. The dielectric spacer <NUM>, may be comprised, as a non-limiting example, of Teflon or another dielectric material. The dielectric spacer <NUM> functions as a capacitor and thus may be tuned or configured to provide a desired resonance. It should be appreciated that other configurations for providing capacitance to the RF coil array interfacing cable <NUM> are possible, and that the illustrated configurations are exemplary and non-limiting. For example, discrete capacitors may alternatively be provided to the RF coil array interfacing cable <NUM>.

Further, the RF coil array interfacing cable <NUM> includes a first post <NUM> and a second post (not shown) to which the first common mode trap conductor <NUM> and the second common mode trap conductor <NUM> are fixed. To that end, the first post <NUM> and the second post are positioned at the opposite ends of the common mode trap, and are fixed to the outer shielding <NUM>. The first post <NUM> and the second post ensure that the first and second common mode trap conductors <NUM> and <NUM> are positioned close to the outer shielding <NUM> at the ends of the RF coil array interfacing cable <NUM>, thereby providing a tapered butterfly configuration of the counterwound conductors as described further herein.

The tapered butterfly configuration includes a first loop formed by the first common mode trap conductor <NUM> and a second loop formed by the second common mode trap conductor <NUM>, arranged so that an induced current (a current induced due to a magnetic field) in the first loop <NUM> and an induced current in the second loop <NUM> cancel each other out. For example, if the field is uniform and the first loop <NUM> and the second loop <NUM> have equal areas, the resulting net current will be zero. The tapered cylindrical arrangement of the loops <NUM> and <NUM> provide improved flexibility and consistency of resonant frequency during flexing relative to two-dimensional arrangements conventionally used in common mode traps.

Generally, a tapered butterfly configuration as used herein may be used to refer to a conductor configuration that is flux cancelling, for example including at least two similarly sized opposed loops that are symmetrically disposed about at least one axis and are arranged such that currents induced in each loop (or group of loops) by a magnetic field tends to cancel out currents induced in at least one other loop (or group of loops). For example, with reference to <FIG>, in some embodiments, counterwound conductors (e.g., conductors wound about a central member and/or axis in opposing spiral directions) may be spaced a distance radially from the central conductor <NUM> to form the common mode traps <NUM>, <NUM>, <NUM>. As depicted in <FIG>, the radial distance may be tapered towards the end of the common mode traps to reduce or altogether eliminate fringe effects. In this way, the common mode traps <NUM>, <NUM>, <NUM> may be continuously or contiguously positioned without substantial gaps therebetween.

The tapered spiral configuration of the common mode trap conductors described herein above is particularly advantageous when multiple common mode trap conductors are contiguously disposed in a common mode trap assembly. As an illustrative example, <FIG> is a perspective view of a RF coil array interfacing cable <NUM> including a plurality of continuous and/or contiguous common mode traps coupling an RF coil array <NUM> to a processing system <NUM>. RF coil array interfacing cable <NUM> includes a first common mode trap <NUM> and a second common mode trap <NUM> positioned adjacent to each other on a central conductor <NUM>.

The first common mode trap <NUM> includes a first common mode trap conductor <NUM> and a second common mode trap conductor <NUM> counterwound in a tapered spiral configuration. To that end, the first and second conductors <NUM> and <NUM> are fixed to posts <NUM> and <NUM>. It should be noted that the posts <NUM> and <NUM> are aligned on a same side of the common mode trap <NUM>.

Similarly, the second common mode trap <NUM> includes a third common mode trap conductor <NUM> and a fourth common mode trap conductor <NUM> counterwound in a tapered spiral configuration and fixed to posts <NUM> and <NUM>. It should be noted that the posts <NUM> and <NUM> are aligned on a same side of the common mode trap <NUM>.

As depicted, the common mode traps <NUM> and <NUM> are separated by a distance, thereby exposing the central conductor <NUM> in the gap <NUM> between the common mode traps. Due to the tapering spiral configuration of the common mode trap conductors of the common mode traps, the gap <NUM> can be minimized or altogether eliminated in order to increase the density of common mode traps in a common mode trap assembly without loss of impedance functions of the common mode traps. That is, the distance can be made arbitrarily small such that the common mode traps are in face-sharing contact, given the tapered spiral configuration.

It should be appreciated that while the RF coil array interfacing cable <NUM> includes two common mode traps <NUM> and <NUM>, in practice a RF coil array interfacing cable may include more than two common mode traps.

Further, the common mode traps <NUM> and <NUM> of the RF coil array interfacing cable <NUM> are aligned such that the posts <NUM>, <NUM>, <NUM>, and <NUM> are aligned on a same side of the RF coil array interfacing cable. However, in examples where cross-talk between the common mode traps may be possible, for example if the tapering of the counterwound conductors is more severe or steep, the common mode traps may be rotated with respect to one another to further reduce fringe effects and/or cross-talk between the traps.

Additionally, other common mode trap or balun configurations are possible. For example, the exterior shielding of each common mode trap may be trimmed such that the common mode traps can be overlapped or interleaved, thus increasing the density of the common mode traps.

Claim 1:
A radio frequency (RF) coil assembly for a magnetic resonance imaging (MRI) system, comprising:
a loop portion (<NUM>) comprising at least three distributed capacitance conductor wires (<NUM>, <NUM>, <NUM>) encapsulated and separated by a dielectric material (<NUM>);
a coupling electronics portion (<NUM>) including a pre-amplifier; and
a coil-interfacing cable (<NUM>) extending between the coupling electronics portion and an interfacing connector of the RF coil assembly,
wherein the loop portion further includes a core (<NUM>) surrounded by the at least three distributed capacitance conductor wires, characterised in that the core is made of a second dielectric material having different dielectric properties than the dielectric material (<NUM>).