KR102125555B1 - Radiofrequency Coil - Google Patents

Abstract

The present disclosure relates to an RF coil used in a magnetic resonance imaging (MRI) system, comprising: a main loop coil having a first electrical conductor and a second electrical conductor parallel to a B ₀ magnetic field direction; And a first auxiliary loop coil having third and fourth electrical conductors facing each other parallel to the first electrical conductor with the first electrical conductor of the main loop coil interposed therebetween. An RF coil used in a resonance imaging (MRI) system, comprising: a main loop coil having a first electrical conductor and a second electrical conductor parallel to a B ₀ magnetic field direction; And an auxiliary loop coil having a third electrical conductor and a fourth electrical conductor parallel to the first electrical conductor between the first electrical conductor and the second electrical conductor of the main loop coil. will be.

Description

RF coil

The present disclosure (Disclosure) relates to an RF coil used in a Magnetic Resonance Imaging (MRI) system as a whole, and more particularly, to an RF coil that improves the uniformity of a B ₁ magnetic field.

1 is a view described in US Patent Publication No. 7002347 as an example showing a general MRI system. However, for convenience of explanation, terms and symbols have been changed. The MRI system includes a magnet (1) that generates a main magnetic field, a transmitting RF coil (2) that generates a magnetic field that makes the hydrogen nuclei of the inspection target (4) excited, and the excited hydrogen nuclei of the inspection target (4). It consists of a receiving RF coil (3) that receives the RF signal that comes out when returning to a stable state, and a table (5) for placing the inspection target (4). In general, the main magnetic field is referred to as a B ₀ magnetic field and the magnetic field produced by the transmitting RF coil 2 is called a B ₁ magnetic field. The direction of the B ₀ magnetic field is formed in the Z-axis direction, and the direction of the B ₁ magnetic field is formed in the X-axis direction perpendicular to the B ₀ magnetic field. The transmitting RF coil 2 not only generates a magnetic field, but also serves to receive an RF signal. It is also possible that the receiving RF coil 3 not only receives the RF signal, but also generates a B ₁ magnetic field if necessary. Therefore, when not separately described below, the term RF coil is used as a term including both a transmitting RF coil and a receiving RF coil. The quality and uniformity of the B ₀ magnetic field are important for the quality of MRI images. Furthermore, the uniformity of the B ₁ magnetic field is also important. In the case of the B ₁ magnetic field produced by the double transmitting RF coil 2, even if the transmitting RF coil 2 makes the B ₁ magnetic field uniform, the distance from the inspection object 4 is not constant, so in the inspection object requiring measurement, B _{1 The} magnetic field becomes non-uniform.

FIG. 2 shows that the B ₁ magnetic field created by the RF coil becomes non-uniform in the inspection object due to a difference in distance from the inspection object.

The inspection targets 7 and 8 are placed between the RF coils 6. When the shape of the inspection object is rectangular (7), the distance between the RF coil 6 and the inspection object 7 is constant at L. However, when the shape of the inspection object is circular (8), the distance between the RF coil 6 and the inspection object 8 changes to L ₁ and L ₂ depending on the position. As is well known to those skilled in the art, the farther from the RF coil 6, the weaker the strength of the B ₁ magnetic field. Therefore, the intensity of the B ₁ magnetic field generated by the RF coil 6 is the same as everywhere in the inspection object (7) in the inspection object (7) with a constant distance L, but in the inspection object (8) with the distance L ₁ , L ₂ It depends on the distance between the object 8 and the RF coil 6. Where the distance between the RF coil 6 and the object to be inspected 8 is different, the excitation state of the hydrogen nuclei is different because the intensity of the B ₁ magnetic field is different, and this is also the RF signal of the hydrogen nucleus used to make an MRI image of the object to be inspected. It is different and degrades the quality of MRI images. Of course, even when the distance from the inspection target 7 is constant, the B ₁ magnetic field may be uneven due to the problem of the RF coil itself, and in this case, the quality of the MRI image is deteriorated.

Various means have been developed to solve this problem.

Prior art for improving the uniformity of the B ₁ magnetic field includes a number of patents such as U.S. Patent Registration No. 5017872, U.S. Patent Registration No. 7002347, U.S. Patent Registration No. 7,724,192, and U.S. Patent Registration No. 8188737. .

3 is a view showing an example for uniformly making the B ₁ magnetic field described in US Patent Publication No. 5017872. However, for convenience of explanation, terms and symbols have been changed.

The RF coil structure 9 is composed of an RF coil 10, an RF shield 11, and a high dielectric material 12. When the inspection object 13 is placed inside the RF coil structure 9, the B ₁ magnetic field becomes non-uniform. The present invention has solved this non-uniformity problem by filling the high dielectric material 12 between the RF coil 10 and the RF shield 11.

4 is a view showing an example for uniformly making the B ₁ magnetic field described in US Patent Publication No. 72242192. However, for convenience of explanation, terms and symbols have been changed.

The RF coil structure 14 is composed of a main RF coil 15 and an auxiliary RF coil 16. Although the present invention is not described in the drawings, when the RF coil structure 14 is used, the distance between the inspection object and the RF coil structure 14 is not constant, and thus the B ₁ magnetic field is not uniform, so that the auxiliary RF coil 16 It was solved by placing.

However, among the means for uniformizing the B ₁ magnetic field as described above, in the case of the means disclosed in FIG. 3, a high dielectric material is uniformly disposed between the RF shield and the RF coil to solve the effect due to the difference in distance between the inspection object and the RF coil. It is difficult, and the method disclosed in FIG. 4 has the inconvenience of using an auxiliary RF coil in addition to the main RF coil.

This will be described at the end of'Details for Carrying Out the Invention'.

Here, an overall summary of the present disclosure is provided, and this should not be understood as limiting the appearance of the present disclosure (This section provides a general summary of the disclosure and is not a comprehensive disclosure of its full scope or all of its features).

According to one aspect of the present disclosure (According to one aspect of the present disclosure), in an RF coil used in a magnetic resonance imaging (MRI) system, a first electrical conductor parallel to a B ₀ magnetic field direction and a second electrical conductor Main loop coil having a; In addition, an RF coil is provided comprising a first auxiliary loop coil having third and fourth electrical conductors parallel to the first electrical conductor with the first electrical conductor of the main loop coil interposed therebetween.

According to another aspect of the present disclosure (According to another aspect of the present disclosure), in an RF coil used in a magnetic resonance imaging (MRI) system, a first electrical conductor and a second electrical conductor parallel to a B ₀ magnetic field direction Main loop coil having a; And an auxiliary loop coil having a third electrical conductor and a fourth electrical conductor parallel to the first electrical conductor between the first electrical conductor and the second electrical conductor of the main loop coil. do.

This will be described at the end of'Details for Carrying Out the Invention'.

1 is a view showing an example of a general MRI system,
2 is a view showing that the B ₁ magnetic field made by the RF coil becomes non-uniform in the inspection object due to a difference in distance from the inspection object;
3 is a view showing an example for uniformly making the B ₁ magnetic field described in US Patent Publication No. 5017872,
4 is a view showing an example for uniformly making the B ₁ magnetic field described in U.S. Patent Publication No. 72242192,
Figure 5 is a view showing the problems of the prior art,
6 is a view showing an example of an RF coil according to the present disclosure,
7 is a view showing a cross-section of the RF coil 200 in FIG. 6 taken along line AA',
8 is a view showing another example of an RF coil according to the present disclosure,
9 is a view showing a cross-section of the RF coil 400 in FIG. 8 along AA' line,
10 is a view showing another example of the RF coil according to the present disclosure,
11 is a view showing a cross section of the RF coil 600 in FIG. 10 taken along line AA'.

Hereinafter, the present disclosure will be described in detail with reference to the accompanying drawings (The present disclosure will now be described in detail with reference to the accompanying drawing(s)).

5 is a view showing a problem in the prior art.

The RF coil 100 includes a first electrical conductor 101 and a second electrical conductor 102 parallel to the B ₀ magnetic field direction, and includes a capacitor 103. An electrical conductor means a conductor made of copper, silver, etc., which is a material in which current flows well. As known to those skilled in the art, the B ₁ magnetic field that makes the hydrogen nucleus or the like to be inspected excited is mainly made by the electrical conductors 101 and 102 of the RF coil 100 parallel to the B ₀ magnetic field direction. The section 110 cut along the AA' of the RF coil 100 is inspected when the strength of the B ₁ magnetic field created by the RF coil 100 is different between the inspection targets 120, 130, and 140 and the RF coil 100 It shows that it is different in objects 120, 130, and 140. That is, since the distance 161 between the inspection target 140 and the RF coil 100 is farther than the distance 160 between the inspection targets 120 and 130 and the RF coil, the inspection target 140 as described in FIG. 2 ), the strength of the B ₁ magnetic field 150 is weaker than the strength of the B ₁ magnetic fields 151 and 152 in the inspection targets 120 and 130, so that the same B ₁ magnetic field is found anywhere in the inspection targets 120, 130 and 140. It has no century. In order to solve this problem, U.S. Patent Publication No. 7242192 has been proposed, but in this case, there is a hassle of having a main RF coil and a secondary RF coil, respectively, and having an RF source in each.

6 shows an example of an RF coil according to the present disclosure.

The RF coil 200 is sandwiched between the main loop coil 210 and the first electrical conductor 211 including the first electrical conductor 211 and the second electrical conductor 212 parallel to the B ₀ magnetic field direction. It includes a first auxiliary loop coil 220 including a third electrical conductor 221 and a fourth electrical conductor 222 parallel to the first electrical conductor 211. Furthermore, the RF coil 200 is coupled with the first auxiliary loop coil 220 and the second electrical conductor 212 of the main loop coil 210 therebetween, and the fifth electrical conductor parallel to the second electrical conductor 212. A second auxiliary loop coil 230 including 231 and a sixth electrical conductor 232 may be included. For convenience of description, the capacitor in the RF coil is omitted. The directions of the arrows in the main loop coil 210 and the first and second auxiliary loop coils 220 and 230 indicate the direction in which current flows in each loop coil. In addition, it includes an RF source (RF Source) 240 for applying a current to the RF coil 200. In this figure, the RF source 240 is shown as applying current to the RF coil 200, but a voltage may be applied. In addition, the RF source 240 is required only for the transmitting RF coil, and may not be required when the RF coil functions as the receiving RF coil. The direction of the current flowing through the electrical conductor is indicated by an arrow 250. Unlike the invention described in U.S. Patent No. 7242192, which is a prior art, one RF coil 200 constitutes the main loop coil 210 and the auxiliary loop coils 220 and 230, so if there is only one RF source 240 Suffice. In the drawing, the indication of the direction in which the current flows is indicated to explain the principle of improving the uniformity of the B1 magnetic field based on when the RF coil performs the function of the transmitting RF coil. This is because, as is well known to those skilled in the art, the direction in which the current flows determines the direction of the magnetic field generated thereby. Therefore, the indication of the direction in which the current flows in the drawing does not limit the scope of the present disclosure, and in the following drawings, the indication of the direction in which the current flows was used for the same purpose.

FIG. 7 shows a cross-section of the RF coil 200 in FIG. 6 taken along line AA'.

The cross section 300 of the RF coil 200 cut along the AA' line is how the RF coil 200 according to the present disclosure is inspected at different distances from the RF coil 200 (310, 320, 330) B ₁ Show if the uniformity of the magnetic field strength is improved. That is, the intensity of the B ₁ magnetic fields 341 and 342 in the inspection objects 310 and 330 close to the RF coil 200 is greater than the intensity of the B ₁ magnetic field 340 in the inspection object 320 that is far away. Therefore, in order to make the intensity of the B ₁ magnetic field uniform throughout the inspection target, the place where the strength of the B ₁ magnetic field is weak may be strengthened or the strength may be weakened. The RF coil 200 according to the present disclosure creates a magnetic field 350 and 351 in the opposite direction to the B ₁ magnetic field created by the main loop coil 210 in the auxiliary loop coils 220 and 230, where the strength of the B ₁ magnetic field is strong To improve the uniformity of the strength of the B ₁ magnetic field. However, in order to prevent the magnetic fields produced by the auxiliary loop coils 220 and 230 from affecting the B ₁ magnetic field 340 created by the main loop coil, the third electrical conductors 221 and the fourth of the first auxiliary loop coils 220 The distance L ₁ between the electrical conductors 222 should be sufficiently smaller than the distance L between the first electrical conductors 211 and the second electrical conductors 212 of the main loop coil 210. Preferably, L ₁ is smaller than 0.25 L. Also, it is preferable that the distance L ₂ between the fifth electrical conductor 231 and the sixth electrical conductor 232 of the second auxiliary loop coil 230 is also less than 0.25 L.

8 shows another example of an RF coil according to the present disclosure.

The RF coil 400 is interposed between the main loop coil 410 and the first electrical conductor 411 including the first electrical conductor 411 and the second electrical conductor 412 parallel to the B ₀ magnetic field direction. It includes a first auxiliary loop coil 420 including a third electrical conductor 421 and a fourth electrical conductor 422 parallel to the first electrical conductor 411. Furthermore, the RF coil 400 is coupled with the first auxiliary loop coil 420 and the second electrical conductor 412 of the main loop coil 410 therebetween, and the fifth electrical conductor parallel to the second electrical conductor 412. A second auxiliary loop coil 430 including 431 and a sixth electrical conductor 432 may be included. For convenience of description, the capacitor in the RF coil is omitted. The directions of the arrows in the main loop coil 410 and the first and second auxiliary loop coils 420 and 430 indicate the direction in which current flows in each loop coil. It also includes an RF source 440 that applies current to the RF coil 400. In this figure, the RF source 440 is indicated as applying current to the RF coil 400, but a voltage may be applied. Also, the RF source 440 is necessary only for the transmitting RF coil, and may not be required when the RF coil functions as the receiving RF coil. The direction of the current flowing through the electrical conductor is indicated by an arrow 450. The RF coil 400 disclosed in FIG. 8 has a direction in which current flows in the corresponding first and second auxiliary loop coils 220, 230, 420, and 430, respectively, when compared to the RF coil 200 disclosed in FIG. It is in the opposite direction.

9 is a cross-sectional view of the RF coil 400 of FIG. 8 taken along line AA'.

Section 500 cut the RF coil 400 along the AA' line is how the RF coil 400 according to the present disclosure is inspected at different distances from the RF coil 400 (510, 520, 530) B ₁ Show if the uniformity of the magnetic field is improved. That is, the intensity of the B ₁ magnetic field 540 in the inspection object 520 that is close to the RF coil 400 is greater than the intensity of the B ₁ magnetic fields 541 and 542 in the inspection object 510 and 530 that are far away. Therefore, in order to make the intensity of the B ₁ magnetic field uniform throughout the inspection target, the place where the strength of the B ₁ magnetic field is weak may be strengthened or the strength may be weak. The RF coil 400 according to the present disclosure creates a magnetic field 550, 551 in the same direction as the B ₁ magnetic field created by the main loop coil 410 from the auxiliary loop coils 420 and 430 where the strength of the B ₁ magnetic field is weak By strengthening, the uniformity of the strength of the B ₁ magnetic field was improved.

As shown in Figs. 6 and 8, depending on how to design the direction of the current flowing through the auxiliary loop coil, the direction of the magnetic field produced by the auxiliary loop coil may be the same as the direction of the B ₁ magnetic field produced by the main loop coil or vice versa. In this way, the intensity of the B ₁ magnetic field can be made uniform at inspection objects at different distances. In FIGS. 6 and 8, the directions of the magnetic fields generated by the first auxiliary loop coils 220 and 420 and the second auxiliary loop coils 230 and 430 are the same, but may be different if necessary.

10 shows another example of an RF coil according to the present disclosure.

The RF coil 600 includes a main loop coil 610 including a first electrical conductor 611 and a second electrical conductor 612 parallel to the B ₀ magnetic field direction, a first electrical conductor 611 and a second electrical It includes an auxiliary loop coil 620 including a third electrical conductor 621 and a fourth electrical conductor 622 parallel to the first electrical conductor 611 between the conductors 612. For convenience of description, the capacitor in the RF coil is omitted. The direction of the arrow in the main loop coil 610 and the auxiliary loop coil 620 indicates the direction in which current flows in each loop coil. It also includes an RF source 630 that applies current to the RF coil 600. In this figure, the RF source 630 is shown as applying current to the RF coil 600, but a voltage may be applied. In addition, the RF source 630 is necessary only for the transmitting RF coil, and may not be required when the RF coil functions as the receiving RF coil. The direction of the current flowing through the electrical conductor is indicated by an arrow 640.

FIG. 11 shows a cross-section of the RF coil 600 in FIG. 10 taken along line AA'.

The cross-section 700 of the RF coil 600 cut along the AA' line is how the RF coil 600 according to the present disclosure is located at different distances from the RF coil 600 at the inspection targets 710, 720, and 730 B ₁ Show if the uniformity of the magnetic field strength is improved. That is, the intensity of the B ₁ magnetic fields 741 and 742 in the inspection objects 710 and 730 close to the RF coil 600 is greater than the intensity of the B ₁ magnetic field 740 in the inspection object 720 that is far away. Therefore, in order to make the intensity of the B ₁ magnetic field uniform throughout the inspection target, the place where the strength of the B ₁ magnetic field is weak may be strengthened or the strength may be weakened. The RF coil 600 according to the present disclosure makes the magnetic field 750 in the same direction as the B ₁ magnetic field created by the main loop coil 610 in the auxiliary loop coil 620, thereby strengthening the place where the strength of the B ₁ magnetic field is weak B ₁ The uniformity of the strength of the magnetic field was improved.

However, in order to prevent the magnetic field created by the auxiliary loop coil 620 from affecting the surrounding magnetic field, the distance L ₁ between the electrical conductors of the auxiliary loop coil 620 is the distance between the electrical conductors of the main loop coil 610 ( L). Preferably L ₁ is Should be less than 0.25L.

Hereinafter, various embodiments according to the present disclosure will be described.

(1) An RF coil used in a magnetic resonance imaging (MRI) system, comprising: a main loop coil having a first electrical conductor and a second electrical conductor parallel to a B ₀ magnetic field direction; And a first auxiliary loop coil having third and fourth electrical conductors parallel to the first electrical conductor with the first electrical conductor of the main loop coil interposed therebetween.

(2) RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the first auxiliary loop coil are opposite to each other.

(3) The RF coil characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the first auxiliary loop coil are the same.

(4) The RF coil, characterized in that the distance between the third electrical conductor and the fourth electrical conductor is smaller than 0.25 times the distance between the first electrical conductor and the second electrical conductor.

(5) An RF coil comprising a main loop coil and one RF source for applying a current flowing through the first auxiliary loop coil.

(6) An RF coil having a second auxiliary loop coil having fifth and sixth electrical conductors parallel to the second electrical conductor with the second electrical conductor of the main loop coil interposed therebetween.

(7) RF coil characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are opposite directions.

(8) RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are the same.

(9) The RF coil, characterized in that the distance between the fifth electrical conductor and the sixth electrical conductor is smaller than 0.25 times the distance between the first electrical conductor and the second electrical conductor.

(10) An RF coil having a second auxiliary loop coil having fifth and sixth electrical conductors parallel to the second electrical conductor with a second electrical conductor therebetween.

(11) RF coil characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are opposite directions.

(12) The RF coil characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are the same.

(13) The RF coil, characterized in that the distance between the fifth electrical conductor and the sixth electrical conductor is smaller than 0.25 times the distance between the first electrical conductor and the second electrical conductor.

(14) An RF coil used in a magnetic resonance imaging (MRI) system, comprising: a main loop coil having a first electrical conductor and a second electrical conductor parallel to a B ₀ magnetic field direction; And an auxiliary loop coil having a third electrical conductor and a fourth electrical conductor parallel to the first electrical conductor between the first electrical conductor and the second electrical conductor of the main loop coil.

(15) The RF coil characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the auxiliary loop coil between the first and second electrical conductors of the main loop coil are the same.

(16) RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the auxiliary loop coil between the first and second electrical conductors of the main loop coil are opposite to each other.

(17) The RF coil, characterized in that the distance between the third electrical conductor and the fourth electrical conductor is smaller than 0.25 times the distance between the first electrical conductor and the second electrical conductor.

By using the RF coil according to the present disclosure, it is possible to effectively reduce the non-uniformity of the B ₁ magnetic field in the inspection object caused by the difference in distance between the RF coil and the inspection object. In addition, only one RF source that applies current or voltage to the main loop coil and the auxiliary loop coil can be used to simplify the component configuration of the RF coil.

RF coil: 2, 3, 6, 10, 15, 16, 100, 200, 400, 600
101, 102, 211, 212, 221, 222, 231, 232, 411, 412, 421: electrical conductor
4, 7, 8, 13, 120, 130, 140, 310, 320, 330, 510, 520, 530: inspection target
210, 410, 610: main loop coil
220, 230, 420, 430, 620: auxiliary loop coil

Claims (17)

In the RF coil used in the magnetic resonance imaging (MRI) system,
B ₀ A main loop coil having a first electrical conductor and a second electrical conductor parallel to the magnetic field direction; And,
It includes; a first auxiliary loop coil having a third and fourth electrical conductor parallel to the first electrical conductor with the first electrical conductor of the main loop coil interposed therebetween;
The main loop coil and the first auxiliary loop coil are different coil parts of the same one coil connected in series, RF coil, characterized in that disposed on the same plane. The method according to claim 1,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the first auxiliary loop coil are opposite to each other. The method according to claim 1,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the first auxiliary loop coil. The method according to claim 1,
RF coil, characterized in that the distance between the third electrical conductor and the fourth electrical conductor is less than 0.25 times the distance between the first electrical conductor and the second electrical conductor. The method according to claim 1,
And an RF source for applying a current flowing through the main loop coil and the first auxiliary loop coil. The method according to claim 2,
And a second auxiliary loop coil having fifth and sixth electrical conductors parallel to the second electrical conductor with the second electrical conductor of the main loop coil interposed therebetween. The method according to claim 6,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are opposite to each other. The method according to claim 6,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil. The method according to claim 6,
RF coil, characterized in that the distance between the fifth electrical conductor and the sixth electrical conductor is less than 0.25 times the distance between the first electrical conductor and the second electrical conductor. The method according to claim 3,
And a second auxiliary loop coil having fifth and sixth electrical conductors parallel to the second electrical conductor with the second electrical conductor of the main loop coil interposed therebetween. The method according to claim 10,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil are opposite to each other. The method according to claim 10,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the second auxiliary loop coil. The method according to claim 10,
RF coil, characterized in that the distance between the fifth electrical conductor and the sixth electrical conductor is less than 0.25 times the distance between the first electrical conductor and the second electrical conductor. In the RF coil used in the magnetic resonance imaging (MRI) system,
B ₀ A main loop coil having a first electrical conductor and a second electrical conductor parallel to the magnetic field direction; And,
And an auxiliary loop coil having a third electrical conductor and a fourth electrical conductor parallel to the first electrical conductor between the first electrical conductor and the second electrical conductor of the main loop coil.
The main loop coil and the auxiliary loop coil are different coil parts of the same one coil connected in series, RF coil, characterized in that disposed on the same plane. The method according to claim 14,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the auxiliary loop coil. The method according to claim 14,
RF coil, characterized in that the direction of the magnetic field produced by the main loop coil and the direction of the magnetic field produced by the auxiliary loop coil are opposite to each other. The method according to claim 14,
RF coil, characterized in that the distance between the third electrical conductor and the fourth electrical conductor is less than 0.25 times the distance between the first electrical conductor and the second electrical conductor.

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