JPS63178508A - Magnetic field correcting apparatus - Google Patents

Abstract

PURPOSE:To effectively correct error magnetic field element by defining the origin to the center of basic magnetic field generated by a main coil, supposing a right angle coordinate in the direction of basic magnetic field and providing magnetic material for correction to the specified position. CONSTITUTION:A magnetic field correction apparatus to be used to an imaging apparatus utilizing nuclear magnetic resonance is formed as explained hereunder. First, the origin (Z = 0) is set to the center of basic magnetic field generated by a main coil and the Z axis of a right angle coordinate is defined in the basic magnetic field direction. In this case, the magnetic field element at the freely defined coordinates on the spherical surface where Z = 0 is expressed by development of spherical harmonic function. Here, at least one magnetic material is arranged to the position where the (2n+1) order magnetic element for Z axis is not generated to correct the (2n+1) order magnetic field generating an error in the basic magnetic field. As explained above, error magnetic field element existing in the main magnetic field is effectively and easily corrected using a small magnetic material.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a magnetic field correction device used in an imaging device using nuclear magnetic resonance (hereinafter referred to as NMR).

(Prior art) NMR is used in imaging devices for medical diagnosis, etc.
Since a highly uniform magnetic field is required, the coil that generates the magnetic field (hereinafter referred to as the main coil) is designed with special care to make the magnetic field uniform.

However, in reality, a deviation occurs in the uniformity of the magnetic field due to manufacturing errors in the main coil itself or the influence of magnetic material existing around the main coil, and an error component is generated.

A device for eliminating this error component and obtaining a highly uniform magnetic field is a magnetic field correction device, and there are devices called magnetic field correction coils (shim coils) and iron shims that use a magnetic material such as iron. The iron shim places a magnetic body in the magnetic field (hereinafter referred to as the main magnetic field) generated by the main coil, magnetizes the magnetic body, and uses the magnetic field generated by the magnetic body for magnetic field correction.

As an example of magnetic field correction using conventional iron shims, see the document “5UP
ERCONDUCTING MAGNETS PORM
RI”, IEEE Transactions on
Nuclear 5science, Vol, N5-
31°No, 4. There is a method described in August 19g4, which will be explained with reference to FIG. Figure 4 (
For both a) and (b), take the origin (Z-〇) at the center of the base magnetic field generated by the main coil 1, take the Z-axis in the direction of the base magnetic field (that is, the central axis direction of the main coil), and find the range that requires correction. This is the range indicated by numeral 3 in the figure. In (a), iron shims 2 and 2' are placed at both ends of range 3 that requires correction, that is, at symmetrical positions with respect to Z-0, and generate a correction magnetic field in the positive direction with respect to the Z axis. ing. (b) is arranged so that the center of the iron shim 4 lies with respect to the center of the range 3 requiring correction, that is, Z-0, and generates a correction magnetic field in the negative direction with respect to the Z axis. If a small magnetic material such as a ring shape is used as the iron shim, locally changing magnetic fields are likely to be generated, so the iron shims 2 and 2' used here are all made from a large sheet-like magnetic material.

(Problems to be Solved by the Invention) However, when using a large sheet-like magnetic material as described above, there is a problem in that it is extremely difficult to handle it. SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a magnetic field correction device that can efficiently and easily correct the error magnetic field component present in the main magnetic field using a small magnetic body.

[Structure of the invention]

(Means for Solving the Problems) The present invention provides an origin (
Z-0), the Z axis of the rectangular coordinate system is taken in the direction of the base magnetic field,
At a position where a 2n+1-order (hereinafter, n is an integer of 0 or more determined for each magnetic material) magnetic field component with respect to the Z axis does not occur when spherical harmonic function expansion is performed on a spherical surface centered on the origin. , at least one magnetic body is arranged, and the magnetic body may include a ring-shaped magnetic body with the Z-axis as the central axis, or a plurality of magnetic bodies arranged on the circumference with the Z-axis as the central axis. An aggregate of small magnetic materials can be used.

(Function) If the origin (2-0) is taken at the center of the base magnetic field generated by the main coil, and the Z axis of the orthogonal coordinate system is taken in the direction of the base magnetic field, then any arbitrary point on the spherical surface centered at Z-0 The magnetic field component at the coordinate point is expressed by spherical harmonic expansion. In this case, by arranging at least one magnetic body at a position where a 2n+1-order magnetic field component with respect to the Z-axis does not occur, the 2n+1-order magnetic field component that causes an error in the base magnetic field is corrected. (n+
1) When each magnetic body is arranged, 1, 3.
5. ..., each 2n+1-order error magnetic field component is corrected.

(Example) An example of the present invention will be described with reference to FIG. Consider a rectangular coordinate system in which the origin (z-0) is set at the center of the base magnetic field generated by the main coil 1 and the Z axis is set in the direction of the base magnetic field (that is, the central axis direction of the main coil). A circular iron shim 5 is arranged so as to match the circumference of the coordinate Q(Z,R)CC in this coordinate system. When the Z-axis direction component B of the magnetic field B at the measurement point P in the main coil 1 is expanded by a spherical harmonic function, it is expressed as follows (1). In this equation, r1θ is the coordinate of the measurement point P on the measurement sphere 6 expressed by a spherical machine with the center point Z-0 as the origin. In this equation (1), the above-mentioned iron shim 5 is z-
The components included in the magnetic field B generated near 0 are expressed as follows.

B2 San ao+a1f1+a2f2+a3C3+...
・・・＋af ＋・・・・・・ ・・・・・・・・・
・(2) n Here, n is an integer greater than or equal to 0, and f is “
・P ・An n-th order function regarding the Z coordinate expressed by (COSθ), where a is a coefficient of the function f and is determined by the position where the iron shim is placed.

Note that equation (2) is used not only for ring-shaped magnetic bodies such as the iron shim 5 shown in Fig. 1, but also for the case where small magnetic bodies are arranged in a ring shape to form an iron shim. be able to.

The main magnetic field B generated by the main coil 1 can also be expressed in the same manner as in equation (2). In this case, since the main coil 1 is symmetrical with respect to the Z-0 plane, theoretically, equation (2) is only a 2n-order magnetic field component, and B −A +A f +−...+A2nf2n
+・・・・・・・・・(3)

However, in reality, due to manufacturing errors in the main coil itself and the influence of magnetic materials around the main coil, the main coil is not completely symmetrical with respect to the Z-0 plane, and a 2n+1-order magnetic field component is generated as an error component. To do Bl■Ao+A1fl+A2
f2+-=-・+A f+...
...(4) n.

In this equation (4), Ao is the base magnetic field and Atf
The error component below t is to be erased by the magnetic material. Therefore, if the error components to be eliminated are up to the n-th order, equation (4) can be expressed as follows. Here, al,j is i included in the magnetic field generated by the j-th (j is an integer of 1 or more) magnetic material pair.
It is a coefficient of the next (i is an integer greater than or equal to 1) component, and Vt is a quantity related to the size of the iron shim placed at each position,
The magnitude of the magnetic field generated by an iron shim of the standard size is 1
This means placing an iron shim whose generated magnetic field has a magnitude of vl.

When determining vl by solving equation (5), the matrix (a
, , j) contains more zero components, the easier the solution can be obtained. In particular, it is easiest if the matrix (a, , j) is a unit matrix, which means that an iron shim installed at a certain position generates a magnetic field of only one order component. However, in order to generate such a magnetic field, iron shims must be placed at a plurality of positions with respect to the Z-axis and combined, which is not practical because a large number of iron shims are required.

Therefore, in the present invention, by installing the iron shim in a position where the 2n+1-order component regarding the Z-axis does not occur, the 2n+1-order error magnetic field component regarding the Z-axis can be efficiently corrected with a small amount of iron shims. In this way, it is possible to prevent the generation of components of only one order with one magnetic body, and it is easy to find the position where such a magnetic body should be installed. Furthermore, an application has been filed for a method for correcting the extra even-order error components that occur when iron shims are installed in positions where odd-order components do not occur (Japanese Patent Application No. 1986-2).
No. 56358).

The position where the 2n+1-order component does not occur is the angle n θ [deg] in Figure 3 where a f -0 in equation (2), and if the solution that gives f -0 is α, then from θ-tan-1α Seek.

Table 1 Degree 1.3. ..., to erase the 2n+1 error magnetic field component, arbitrarily select n+1 iron shims on the angle θ where the component of order 20+3 does not occur on either the + side or the - side with respect to the Z-0 plane. Just place it.

Another embodiment of the invention is shown in FIG. The coordinate system and the positional relationship with the main coil (not shown) in this figure are the same as those in FIG. 1. Here, the orders of the error magnetic field components to be corrected are assumed to be first and third orders. In this case, three angles of 23.9 degrees at 0, θ, and 90 degrees in the case of order n-5 in Table 1 are positions that do not produce a fifth-order component.

47.9°, 71.6° or 90° θ<108.4° at 180°, 1B2.1°.

Select 2 arbitrarily from 156.1°, and add 2 on each angle.
Place iron shims. In Fig. 2, the iron shim 8 is θ-
The iron shim 10 is placed on the 47°9° line, and the iron shim 10 is placed on the θ-23.9° line. Although the diameters of the iron shims 8 and 9 in the figure are the same, they may be different as long as they are placed on the line of angle θ.

In this case, equation (5) can be expressed as follows.

Here a −0, a3. -Q, so 6 iron 1.
1 The sizes of the shims V i and V 2 can be easily determined.

Still another embodiment of the invention is shown in FIG. In this case as well, the coordinate system and the positional relationship with the main coil (not shown) in the figure are the same as in FIG. 1. here,
The error magnetic field components to be corrected are up to the first order. In this case, the order n in Table 1 is taken as a position that does not produce a third-order component.
32.6° at 90', 65
．． 0" or 90° x θ x 180°, choose one from 115.0° and 147.4°, and install one iron shim on each angle. In the figure, iron shim 1
2 is placed on the line θ-1156.

In this case, equation (5) can be expressed as follows.

(A1)+ (al,,)(vl) -0-・-・-(
7) The size vl of the iron shim can be determined from the above formula.

〔Effect of the invention〕

As explained above, according to the present invention, by arranging at least one small iron shim at a position that does not produce a 2n+1-order component with respect to the Z-axis in spherical harmonic expansion,
It is possible to efficiently and easily correct the 2n+1-order error magnetic field component included in the main magnetic field generated by the main coil.

[Brief explanation of the drawing]

Fig. 1 is a vertical cross-sectional view showing the arrangement of iron shims in one embodiment of the present invention, Figs. 2 and 3 are longitudinal cross-sectional views showing other embodiments of the present invention, and Fig. 4 is a conventional magnetic field correction method. FIG. 2 is a vertical cross-sectional view showing an outline of the device. 1... Main coil, 2.2', 4, 5, 8, 10°1
2... Iron shim, 3... Range requiring correction, 6...
Measurement spherical surface, 7, 9...Position where the iron shim does not generate a fifth-order error magnetic field component, 11...Position where the iron shim does not generate a third-order error magnetic field component. Applicant's agent Sato -Yukon 1 Diagram R 應 2 Kuniko 3 Mouth■ Color 4 Diagram

Claims (1)

[Claims] 1. The origin (Z=0) is located at the center of the base magnetic field generated by the main coil.
), the Z-axis of the orthogonal coordinate system is taken in the direction of the base magnetic field, and 2n+1 order (n is 0 determined for each magnetic material) with respect to the Z-axis is expanded by spherical harmonics on a spherical surface centered on the origin. A magnetic field correction device characterized in that at least one magnetic body is disposed at a position where a magnetic field component of (an integer greater than or equal to) is not generated. 2. The magnetic field correction device according to claim 1, wherein the magnetic body is a ring-shaped magnetic body whose central axis is the Z-axis. 3. The magnetic field correction device according to claim 1, wherein the magnetic body is composed of an aggregate of a plurality of small magnetic bodies arranged on a circumference with the Z-axis as the central axis. correction device. 4. In the magnetic field correction device according to claim 1, 2n+3 regarding the Z-axis in the spherical harmonic expansion.
A magnetic field correction device characterized in that (n+1) magnetic bodies are arranged at each position where the following (n is an integer of 0 or more determined for each magnetic body) magnetic field component does not occur.