JP6453568B2 - Gamma camera adjustment device, gamma camera system - Google Patents

Description

  The present invention relates to a gamma camera adjustment device and a gamma camera system for adjusting a gamma camera.

  For example, a gamma camera is used to visualize the distribution of environmental radiation in the decontamination target area and to grasp the contamination status. Here, the gamma camera displays a distribution state of gamma rays emitted from a subject as a two-dimensional image, as described in Patent Document 1, for example.

JP 2013-33009 A

  By the way, in the gamma camera as described above, the camera is adjusted using a reference radiation source (hereinafter also referred to as a radiation source) sealed with a substance that emits radiation. It is very small and becomes a point source, so that the two-dimensional image of the gamma camera cannot be adjusted.

  Therefore, in the past, a large number of radiation sources were prepared and a two-dimensional source was created with many of these prepared to adjust the two-dimensional image, or the two-dimensional image was adjusted at the site where the radiation source was actually emitted. It is.

  However, various restrictions are imposed on the handling of radiation sources that are radioactive materials. For this reason, if a plurality of such items are possessed, a burden is imposed on the user. In addition, if the gamma camera is adjusted at the site where the radiation source is emitted, it takes extra time to adjust, and there is a possibility that the human body will be adversely affected by extending the stay time at the site.

  Furthermore, since the imaging target captured by the above-mentioned gamma camera covers a wide range such as environmental radiation, for example, a decontamination target area, a planned condemned area, and a restricted residential area, the gamma camera has a viewing angle to capture a wide range. It is necessary to increase the viewing angle (for example, a viewing angle of 100 degrees), and the sensitivity of the gamma camera sensor varies due to the widening of the viewing angle.

  For this reason, it is necessary to frequently adjust the gamma camera in order to suppress even a slight variation in sensitivity, but it is difficult to frequently adjust the gamma camera with the current adjustment method.

  In view of the above problems, it is a primary object of the present invention to provide a gamma camera adjustment device that can safely adjust a two-dimensional image of a gamma camera without imposing a burden on the user.

  A gamma camera adjustment device of the present invention is a gamma camera adjustment device for adjusting a gamma camera that displays a two-dimensional image in which a distribution state of a radiation dose emitted from a subject is superimposed on an image of the subject, A holding mechanism for holding the radiation source in a movable manner is provided, and the holding mechanism moves the radiation source at a constant or variable speed.

According to the above-described configuration, the locus drawn by the radiation source moved by the holding mechanism becomes a pseudo two-dimensional radiation source. Therefore, if there is at least one radiation source, the two-dimensional radiation source can be configured, and a large number of radiations can be formed. The two-dimensional image of the gamma camera can be adjusted without using a source, and the burden on the user can be reduced.
In addition, since the two-dimensional image of the gamma camera can be adjusted using the pseudo two-dimensional source without going to the site where the radiation source is emitted, the gamma camera can be adjusted safely.
Furthermore, when the radiation dose of the imaging target imaged by the gamma camera of the present invention is a relatively low radiation dose of about several μSv / h, such as a planned refuge area, a residential restricted area, and a worker's exposure dose, a line to be used A source that does not require storage in a management area of less than 1 GBq can be used (for example, about 1 MBq). Therefore, in the present invention, the place where the gamma camera adjustment device is used is not limited, and the gamma camera adjustment device can be used freely at an arbitrary place. In addition, the gamma camera adjustment device and the gamma camera can be used. If it is configured as a portable type, the gamma camera adjustment device and the gamma camera can be carried to a location desired by the user for adjustment.
Further, even when it is necessary to adjust the gamma camera frequently, the gamma camera can be easily adjusted using the gamma camera adjusting device of the present invention.

  Here, when the holding mechanism of the gamma camera adjustment device moves the radiation source at a constant speed, the locus drawn by the radiation source becomes a pseudo two-dimensional source with a constant dose, and the holding mechanism moves the radiation source at a variable speed. In this case, the locus drawn by the radiation source becomes a pseudo two-dimensional source with a changed dose. Therefore, by appropriately changing the speed at which the holding mechanism moves the radiation source, it is possible to increase the variation of the dose of the pseudo two-dimensional source, and to adjust the dose of the pseudo two-dimensional source according to the subject imaged by the gamma camera. By changing, the gamma camera can be adjusted accurately.

  As a specific aspect of the pseudo two-dimensional radiation source with increased dose variation, the holding mechanism divides a moving range in which the radiation source is moved into a plurality of regions, and at different speeds for each region, The thing which moves the said radiation source can be mentioned.

  With this configuration, since the dose of the pseudo two-dimensional source can be changed for each region, a plurality of regions having different doses are formed in one pseudo two-dimensional source. Therefore, it is possible to finely adjust the gamma camera by providing dose variations in one pseudo two-dimensional source.

  As another specific aspect of the gamma camera adjusting device according to the present invention, the holding mechanism can move the radiation source to any position on two coordinate axes perpendicularly intersecting each other. .

  With this configuration, it is possible to increase the variation of the form of the pseudo two-dimensional source by increasing the variation of the trajectory along which the radiation source moves, so that the pseudo two-dimensional source according to the form of the subject imaged by the gamma camera Adjustments can be made using.

A gamma camera system including the gamma camera adjustment device configured as described above and a gamma camera that displays a distribution state of the radiation dose emitted from the subject as a two-dimensional image is also one aspect of the present invention.
Specifically, the gamma camera system of the present invention includes a gamma camera adjustment device configured as described above, and a gamma camera that displays a distribution state of a radiation dose emitted from a subject as a two-dimensional image, The imaging area for imaging the subject is divided into a reference area and at least one other area other than the reference area, and the sensitivity of the other area is detected based on the sensitivity of the reference area, and the sensitivity of the other area is detected. Is calculated so as to be the sensitivity of the reference region.

As described above, when the gamma camera captures a wide area such as a planned condemned area or a residential restricted area, it is necessary to relatively widen the viewing angle of the gamma camera (for example, a viewing angle of 100 degrees). If the angle is widened, the distance between each subject arranged in the imaging region and the gamma camera varies, and variations in detection sensitivity occur.
However, since the gamma camera system of the present invention detects the sensitivity of other regions based on the sensitivity of the reference region, and calculates a correction coefficient for correcting the sensitivity of the other region to be the sensitivity of the reference region. Even when the viewing angle is widened in order to capture the image, it is possible to suppress variations in sensitivity based on this correction coefficient.

  ADVANTAGE OF THE INVENTION According to this invention, the gamma camera adjustment apparatus which can perform the adjustment of the two-dimensional image of a gamma camera safely without imposing a burden on a user can be provided.

Schematic which shows the gamma camera system in this embodiment. The top view which shows the gamma camera adjustment apparatus in 1st Embodiment. The top view which shows the gamma camera adjustment apparatus in 2nd Embodiment. (A) (b) The top view which shows the locus | trajectory which a radiation source draws in the gamma camera adjustment apparatus in 2nd Embodiment. The schematic diagram which shows an example of the gamma camera system in this embodiment. The table | surface which shows the viewing angle of the gamma camera in the gamma camera system in this embodiment, a captured image, and count number. The graph which shows the sensitivity ratio with respect to the viewing angle of the gamma camera system in this embodiment. The schematic diagram which shows the imaging area | region of the gamma camera in the gamma camera system in this embodiment.

  The gamma camera system of the present invention is a radiation dose emitted from a subject in, for example, a planned evacuation area or a residential restriction area set in an accident such as a nuclear accident, a worker's exposure dose, or a pollution priority survey area. And a gamma camera X that displays a distribution state of the radiation dose emitted from the subject as a two-dimensional image, and a gamma camera adjustment device 1 that adjusts the gamma camera X. Note that the term “adjustment” here means correction or calibration of the gamma camera X.

The gamma camera X will be described.
The gamma camera X in the present embodiment displays the distribution state of the radiation dose emitted from the subject in a two-dimensional image. In this embodiment, the ETCC (Electron Track Detection Compton) using the principle of Compton scattering is used. Using a gamma ray camera). This is because the recoil electrons and scattered gamma rays generated when the incident gamma rays cause Compton scattering are detected by the electron track detector and the scintillation detector, respectively, and the incident direction of the incident gamma rays can be specified. In the present embodiment, the gamma camera X can be a portable type.

Accordingly, the gamma camera adjustment device 1 of the present embodiment is a portable device that is arranged to face the gamma camera X and adjusts the gamma camera X as shown in FIG. The gamma camera adjustment device 1 will be described below using two embodiments.
<First Embodiment>

  As shown in FIG. 2, the gamma camera adjusting apparatus 1a according to the first embodiment moves the radiation source 6 sealed with the substance that emits radiation, and images the locus of the radiation source 6 with the gamma camera X. The holding mechanism 2 that holds the radiation source 6 movably and the control unit 3 that controls the holding mechanism 2 are provided. Note that the radiation source 6 in the present embodiment is hermetically sealed.

  The holding mechanism 2 includes a holding unit 4 that holds the radiation source 6 and a drive unit 5 that rotationally drives the holding unit 4.

The holding unit 4 includes a holding unit main body 4a that holds the radiation source 6, and a support shaft 4b that serves as a rotation center when the holding unit main body 4a is rotationally driven.
The holding portion main body 4a includes a hollow cylindrical member 41 and a plurality of frame bones 42 that intersect at a substantially central portion of the cylindrical member 41, and at least one of the frame bones 42 holds the radiation source 6 therein. .
The support shaft 4b is inserted into a hole provided in an intersecting portion 43 where a plurality of frame bones 42 intersect each other.

  The drive unit 5 includes a capacitor, a motor, and the like. The drive unit 5 is connected to the support shaft 4b. The drive unit main body 5a rotates the holding unit body 4a by rotating the support shaft 4b. A power supply unit 5b having a casing shape for supplying power is connected to the drive unit main body 5a and the power supply unit 5b, and a cord (not shown) for supplying power from the power supply unit 5b to the drive unit main body 5a is included. And a cylindrical connecting portion 5c.

  The control unit 3 is structurally composed of a computer body including a CPU, a memory, an A / D converter, a D / A converter, a communication port, and the like, an input means such as a keyboard and a mouse connected to the computer body, and a display. It consists of Then, based on information input from the input means, the CPU and peripheral devices operate in cooperation with each other according to a control program stored in a predetermined area of the internal memory.

  The operation of the gamma camera adjustment device 1a of the first embodiment will be described below.

  When the operator presses a start button (not shown) for starting adjustment of the gamma camera X provided in the input means of the control unit 3, the control unit 3 receives the start information and operates the holding mechanism 2.

  In the holding mechanism 2, power is supplied from the power supply unit 5 b to the drive unit main body 5 a through the connection unit 5 c, and the drive unit main body 5 a rotates the support shaft 4 b to rotate the holding unit main body 4 a in a predetermined direction. . Then, the radiation source 6 held by the holding unit main body 4a rotates. Therefore, the radiation source 6 draws a circular locus.

The gamma camera adjustment device 1a in a state where the radiation source 6 is rotated in this way is imaged by the gamma camera X.
At this time, if the gamma camera X is left for a predetermined time with the shutter opened, the gamma camera X captures an image of the locus drawn by the radiation source 6. That is, since the locus drawn by the radiation source 6 becomes a pseudo two-dimensional source, the gamma camera X can be adjusted using the pseudo two-dimensional source. In this embodiment, since the radiation source 6 draws a circular locus, the gamma camera X can be adjusted using a circular pseudo two-dimensional line source.

  The gamma camera adjustment device 1a configured as described above has the following special effects.

In other words, the locus drawn by the radiation source 6 moved by the holding mechanism 2 becomes a pseudo two-dimensional radiation source, so that if there is at least one radiation source 6, a two-dimensional radiation source can be configured, and a large number of radiation sources can be formed. The two-dimensional image of the gamma camera X can be adjusted without using the, and the burden on the user can be reduced.
Further, since the two-dimensional image of the gamma camera X can be adjusted using the pseudo two-dimensional source without going to the site where the radiation source 6 is emitted, the gamma camera X can be adjusted safely. Can do. In addition, since the said radiation source 6 is sealed, safety can be improved more.
Furthermore, since the radiation dose of the imaging target imaged by the gamma camera X is a relatively low radiation dose of about several μSv / h, such as a planned refuge area, a residential restricted area, and a worker's exposure dose, Those that do not require storage in a management area of less than 1 GBq can be used (for example, about 1 MBq). Therefore, the place where the gamma camera adjustment device 1a is used is not limited, and the gamma camera adjustment device 1a can be used freely at an arbitrary place. In addition, the gamma camera adjustment device 1a and the gamma camera X can be used. If it is configured as a portable type, the gamma camera adjustment device 1a and the gamma camera X can be carried to a location desired by the user for adjustment.
Even when the gamma camera X is frequently adjusted, the gamma camera X can be easily adjusted using the gamma camera adjustment device 1a.
Second Embodiment

  The gamma camera adjustment device 1b in the second embodiment is different from the gamma camera adjustment device 1a in the first embodiment in the configuration of the holding mechanism that holds the radiation source 6. In addition, the same code | symbol is attached | subjected about the part similar to 1st Embodiment, and description is abbreviate | omitted.

  As shown in FIG. 3, the gamma camera adjusting device 1 b according to the second embodiment includes a robot arm, and includes a holding mechanism 10 that holds the radiation source 6 movably and a control unit 3 that controls the holding mechanism 10. It has.

  The holding mechanism 10 movably holds the radiation source 6 at an arbitrary position on two axes perpendicularly intersecting each other, and has a plurality of arm portions 12 (12a, 12b, 12c) and a movable range. And a plurality of node portions 13 (13a, 13b) for connecting the arm portions 12 to each other, and a housing-shaped base portion 15 including a power supply source such as a motor.

  Here, in the present embodiment, the two axes perpendicular to each other indicate a direction in which one is in the horizontal direction and the other is in the vertical direction without changing the relative distance between the gamma camera X and the radiation source 6. .

  In the present embodiment, the arm portion 12a is connected to the arm portion 12b via the node portion 13a. The arm portion 12b is connected to the arm portion 12c via the node portion 13b. The arm portion 12c is connected to the base portion 15 via a connection member 14 that provides a movable range in the arm portion 12c.

Thus, the radiation source 6 is held at the tip of the arm portion 12a arranged at the extreme end.
Each of the joint portions 13a, 13b, 13c and the connecting member 14 is provided with a gear (not shown), and power is supplied to the gear from a power supply source of the base portion 15 via a cord (not shown). . By rotating the gear by this power, the arm portion 12 (12a, 12b, 12c) is rotationally moved about the node portion 13 (13a, 13b) or the connecting member 14 as a rotation axis.

  The operation of the gamma camera adjustment device 1b of the second embodiment will be described below.

  When the operator presses a start button (not shown) that starts adjustment of the gamma camera X provided in the input means of the control unit 3, the control unit 3 receives the start information and activates the holding mechanism 10, and the operator inputs in advance. A control signal is generated based on the program, and the control signal is transmitted to the holding mechanism 10. The holding mechanism 10 receives the control signal and moves the radiation source 6. Specifically, the power supplied from the power supply source to the gears provided in the node portion 13 and the connection member 14 is controlled, and the arm portions 12 (12a, 12b, 12c) are moved so that the radiation sources 6 are perpendicular to each other. Move to a desired position on two intersecting coordinate axes.

  The radiation source 6 may be moved in a straight line or reciprocally moved in a specific direction. In this case, for example, as shown in FIG. 4, the radiation source 6 is linearly moved with respect to the gamma camera X in the horizontal direction (hereinafter referred to as the A direction), and the direction perpendicular to the A direction (hereinafter described). Therefore, it is moved linearly in the direction opposite to the A direction (hereinafter referred to as C direction), and moved linearly in the B direction. The control unit 3 transmits a control signal so as to repeat the operation of linear movement.

  Alternatively, it can be moved to converge toward one point. In this case, for example, as shown in FIG. 4A, the radiation source 6 is linearly moved with respect to the gamma camera X in the horizontal direction (hereinafter, referred to as D direction), and the direction perpendicular to the D direction ( For the sake of explanation, it is linearly moved in the direction E, and then moved in the direction opposite to the direction D (hereinafter referred to as the F direction for explanation). Therefore, the controller 3 transmits a control signal so as to repeat the operation of linearly moving in the G direction and linearly moving in the D direction, and gradually decreasing the distance of the movement.

  Furthermore, in the above-described operation, it is possible to provide a gradual speed.

Then, the gamma camera adjustment device 1b in a state where the radiation source 6 is moved is imaged by the gamma camera X.
At this time, as in the first embodiment, if the gamma camera X is left for a predetermined time with the shutter opened, the gamma camera X images the locus drawn by the radiation source 6. That is, since the locus drawn by the radiation source 6 becomes a pseudo two-dimensional source, the gamma camera X can be adjusted using the pseudo two-dimensional source. In the present embodiment, when the radiation source 6 moves linearly, a rectangular trajectory is drawn, so that the gamma camera X can image a rectangular pseudo two-dimensional source. When the radiation source 6 reciprocates in a predetermined direction or converges toward one point, the radiation source 6 draws a substantially square trajectory, so that the gamma camera X has a substantially square pseudo two-dimensional line. The source can be imaged.

  Further, if the moving speed of the radiation source 6 is made constant, the dose of the pseudo two-dimensional image can be made constant, and if the moving speed of the radiation source 6 is set to be gentle, the pseudo two-dimensional image of the pseudo two-dimensional image can be increased if the moving speed becomes faster. The dose can be reduced and the dose of the pseudo two-dimensional image can be increased if the moving speed is decreased.

  Therefore, for example, as shown in FIG. 4B, when the radiation source 6 is reciprocated in a predetermined direction, the range to be moved is divided into a plurality of regions (A region, B region, C region), respectively. By moving the radiation source 6 at a constant speed (a speed, b speed, c speed) for each of the regions (A region, B region, C region), the dose in one pseudo two-dimensional source Variations can be provided.

  The gamma camera adjustment device 1b configured as described above has the following special effects.

  That is, in the holding mechanism 10 according to the second embodiment, the radiation source 6 can be moved to any position on two coordinate axes that intersect perpendicularly to each other, so that variations in the trajectory for moving the radiation source 6 can be increased. . Therefore, since variations in the form of the pseudo two-dimensional source can be increased, adjustment can be performed using the pseudo two-dimensional source according to the form of the subject imaged by the gamma camera X.

  Further, when the holding mechanism 10 moves the radiation source 6 at a constant speed, the locus drawn by the radiation source 6 becomes a pseudo two-dimensional source with a constant dose, and the holding mechanism 10 moves the radiation source 6 at a variable speed. In this case, since the locus drawn by the radiation source 6 becomes a pseudo two-dimensional radiation source with a changed dose, the holding mechanism 10 appropriately changes the speed at which the radiation source 6 is moved to change the dose of the pseudo two-dimensional radiation source. Variations can be increased. Therefore, the gamma camera X can be accurately adjusted by changing the dose of the pseudo two-dimensional source in accordance with the subject imaged by the gamma camera X.

  In addition, when the radiation source 6 is reciprocated in a predetermined direction, the moving range is divided into a plurality of regions (A region, B region, C region), and each region (A region, B region, C) is divided. Since the moving speed (a speed, b speed, c speed) for moving the radiation source 6 in the region) is changed, the dose of the pseudo two-dimensional source is changed for each region, and the dose in one pseudo two-dimensional source is changed. A plurality of different regions can be provided. Therefore, the gamma camera X can be more finely adjusted with one pseudo two-dimensional source provided with dose variations.

<Gamma camera system>
Next, the gamma camera system of the present embodiment using the above-described gamma camera adjustment device will be described.

  As described above, the trajectory of the movement of the radiation source by the gamma camera adjustment device becomes a pseudo two-dimensional source, but here the dose of the pseudo two-dimensional source depends on the positional relationship between the gamma camera and the source. It turns out to change depending on.

  For example, when the gamma camera adjustment device moves the radiation source at a constant linear velocity in the horizontal direction, the dose of the substantially rectangular pseudo two-dimensional source consisting of the locus drawn by the radiation source is the same at any position. Although ideal, in practice, the dose of the pseudo-two-dimensional source is different.

  FIG. 6 shows the radiation dose distribution of the pseudo two-dimensional radiation source imaged by the gamma camera when the gamma camera adjustment device causes the radiation source to move linearly at a constant speed in the horizontal direction.

  Here, as shown in FIG. 5, the viewing angle refers to a line extending horizontally from a substantially central point in front of the gamma camera X as a reference line, and the reference line and the radiation held by the one point and the gamma camera adjustment device. It is the angle between the line connecting the source. The count number is the electrons counted by the gamma camera during 3000 sec.

  As shown in FIG. 6, the radiation angle distribution at the viewing angle of 0 degree, that is, in front of the gamma camera X is high in the central portion and the count number is 365.36, while the viewing angle is 12.2. In the radiation dose distribution at 5 degrees or -12.5 degrees, the radiation dose at the central portion is smaller and the count number is smaller than when the viewing angle is 0 degrees, and the radiation when the viewing angle is 25 degrees or -25 degrees. In the dose distribution, it can be seen that the radiation dose at the central portion is reduced and the count number is smaller than when the viewing angles are 0 degrees, 12.5 degrees, and -12.5 degrees.

  FIG. 7 is based on the count number when the viewing angle is 0 degree, and the sensitivity ratio at each count number is obtained when the viewing angle is 12.5 degrees, −12.5 degrees, 25 degrees, and −25 degrees, respectively. It is a graph. This sensitivity ratio is obtained by obtaining the sensitivity at each viewing angle from the count number when the viewing angle sensitivity is 1 when the viewing angle is 0 degree, and when the viewing angle is 12.5 degrees. The sensitivity is 0.89, the sensitivity is 0.92 when the viewing angle is −12.5 degrees, the sensitivity is 0.7 when the viewing angle is 25 degrees, and the sensitivity is 0.72 when the viewing angle is −25 degrees. Become. That is, as shown in this graph, it can be seen that the sensitivity is maximized when the viewing angle is 0 degrees, and the sensitivity decreases as the viewing angle increases.

  For this reason, the detection sensitivity decreases as the viewing angle of the gamma camera increases, and this needs to be corrected.

  Therefore, the gamma camera system of the present embodiment divides the imaging area captured by the gamma camera into a reference area and at least one other area, and a correction coefficient for correcting the sensitivity of the other area based on the sensitivity of the reference area. Is calculated.

  Specifically, as shown in FIG. 8, the imaging area to be imaged at a viewing angle of 0 degrees is a reference area, the area from a viewing angle of 0 degrees to 10 degrees is a first area, and the viewing angle is from 10 degrees to 20 degrees. The second region, the region with a viewing angle of 20 degrees to 30 degrees is referred to as a third region, the region with a viewing angle of 30 degrees to 40 degrees is referred to as a fourth region, and the region with a viewing angle of 40 degrees to 50 degrees is referred to as a fifth region. As described above, the imaging area captured by the gamma camera is divided into a reference area and a plurality of other areas according to the range of viewing angles.

Then, using the count number of the reference area as a reference, the correction coefficient is calculated from the count numbers of the other areas (first area, second area, third area, fourth area, and fifth area).
For example, if the count number for 3000 seconds in the reference area is 360 and the count number for 3000 seconds in the first area is 330, the correction coefficient for the first area is 360/330 to 1.09.

  Then, by correcting the count number of each imaging region using this correction coefficient, it is possible to perform imaging with a gamma camera with higher accuracy.

  In the gamma camera system of the present invention configured as described above, when imaging a wide area such as a planned condemned area or a residential restricted area, a wide viewing angle is required to visualize the distribution in a predetermined area. Even when the viewing angle of the gamma camera is greatly expanded, the sensitivity of other areas is detected based on the sensitivity of the reference area, and the correction coefficient is corrected so that the sensitivity of the other area becomes the sensitivity of the reference area. Since the calculation is performed, it is possible to perform imaging with high accuracy while suppressing variations in sensitivity based on the correction coefficient.

  The present invention is not limited to the above embodiment.

  The gamma camera used in the gamma camera adjustment apparatus of the present embodiment is not limited to the ETCC described above, and for example, a pinhole type can be used.

  The radiation source held by the holding mechanism is not limited to one, and a plurality of radiation sources may be held.

  Further, the holding mechanism is not limited to the first embodiment or the second embodiment described above, and various configurations may be used as long as the radiation source can be moved at a constant or variable speed, for example. Can do.

  The configuration in which the holding mechanism changes the moving speed of the radiation source is not limited to the second embodiment. For example, in the holding mechanism in the first embodiment, the rotation speed of the radiation source can be changed.

  Furthermore, the configuration in which the range in which the radiation source is moved is divided into a plurality of regions is not limited to the second embodiment. For example, when moving the radiation source so that it converges toward one point, the range in which the radiation source is moved is divided into a plurality of areas according to the distance from the point to be converged, and the movement speed becomes faster as the area is closer to one point. If constructed in this way, it is possible to create a pseudo two-dimensional source with a higher radiation dose as it approaches one point.

  Also, when calculating the correction coefficient for correcting the gamma camera, in the above embodiment, the viewing angle is 0 degree as the reference area, but the correction coefficient is set with the position of the viewing angle other than 0 degree as the reference area. It may be calculated.

  The present invention can be variously modified without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Gamma camera adjustment apparatus 2, 10 ... Holding mechanism 6 ... Radiation source

Claims (4)

A gamma camera adjustment device for measuring environmental radiation, for adjusting a gamma camera that displays a distribution state of a radiation dose emitted from a subject as a two-dimensional image,
A holding mechanism for holding the radiation source in a movable manner;
The holding mechanism moves the radiation source at a constant or variable speed ;
Gamma camera adjustment device, characterized in portable der Rukoto.   The gamma camera adjustment device according to claim 1, wherein the holding mechanism divides a moving range in which the radiation source is moved into a plurality of regions and moves the radiation source at a different speed for each region.   The gamma camera adjusting apparatus according to claim 1, wherein the holding mechanism is capable of moving the radiation source to an arbitrary position on two coordinate axes perpendicular to each other. A gamma camera adjustment apparatus according to claim 1, 2 or 3, and a gamma camera for measuring environmental radiation, wherein the gamma camera displays a distribution state of a radiation amount emitted from a subject as a two-dimensional image. Prepared,
The gamma camera divides an imaging area for imaging the subject into a reference area and at least one other area, and calculates a correction coefficient for correcting the sensitivity of the other area based on the sensitivity of the reference area. A gamma camera system featuring.