JP2018051027A - Radiation tomography apparatus and control program therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiographic apparatus capable of increasing a degree of freedom when a user combines a radiation dose, an image reconstruction condition, and image noise quantity for creation of a reconstructed image.SOLUTION: Provided is a radiation tomography apparatus comprising: a first reconstructed-image creation unit for creating a first reconstructed image Im1; a second reconstructed-image creation unit for creating a second reconstructed image Im2; a third reconstructed-image creation unit for creating a third reconstructed image Im by adding the first reconstructed image Im1 and the second reconstructed image Im2; an input device for accepting an input of an X-ray dose and an image noise quantity in the third reconstructed image Im3; and a specification unit for specifying an addition ratio on the basis of the input and a relation of the addition ratio between the first reconstructed image Im1 and the second reconstructed image Im2 with the X-ray dose and the image noise quantity.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a radiation tomography apparatus and its control program for acquiring projection data by irradiating an imaging target with radiation and performing an image reconstruction process on the projection data to create a reconstructed image.

  A radiation imaging apparatus that creates a reconstructed image based on projection data obtained by a radiation scan for an imaging target performs an image reconstruction process on the projection data according to a required reconstruction condition to create a reconstructed image. By changing the reconstruction conditions, it is possible to obtain reconstructed images with different image quality, such as a high-resolution reconstructed image or a reconstructed image with reduced image noise. The image quality of the reconstructed image also changes depending on the radiation dose.

  In the radiation imaging apparatus, there are cases where a plurality of reconstruction conditions can be selected (see, for example, Patent Document 1). The user selects an image reconstruction condition that can obtain a reconstructed image having a desired image quality from the viewpoint of resolution, image noise, and the like. The user can also set the radiation dose.

JP 2013-192827 A

  For example, when the user wants to perform radiography with a predetermined dose, the obtained reconstructed image may not have a desired amount of image noise regardless of which of a plurality of image reconstruction conditions is selected. On the other hand, there is a limit to setting image reconstruction conditions that can obtain a desired image quality at a dose desired by the user, and setting many possible image reconstruction conditions leads to an increase in the cost of the apparatus. . Therefore, there is a demand for a radiation imaging apparatus and a control program therefor that can increase the degree of freedom of the combination of the radiation dose, the image reconstruction condition, and the image noise amount by the user when creating a reconstructed image.

  The invention according to one aspect made to solve the above-described problem includes a scan device that performs scanning by irradiating an imaging target with radiation, and a first image based on projection data obtained by the scan. A first reconstructed image creating unit that creates a first reconstructed image by performing an image reconstructing process based on the reconstructing condition; and an image reconstructing process based on the second image reconstructing condition based on the projection data. A second reconstructed image creation unit that creates a second reconstructed image in a row, and adds a first reconstructed image and a second reconstructed image to create a third reconstructed image 3 is a reconstructed image creation unit and an input device that accepts an input by an operator, wherein the input is an input of a dose of the radiation and an image noise amount in the third reconstructed image, or Dose and The input includes an image noise amount in the third reconstructed image and at least one of the first image reconstruction condition and the second image reconstruction condition, or the first image reconstruction condition and An input device that is an input including the second image reconstruction condition and at least one of the radiation dose and the image noise amount in the third reconstruction image; the radiation dose, the image noise amount; A storage device that stores the relationship between the addition ratio of the first reconstructed image and the second reconstructed image, and a specifying unit that specifies the addition ratio based on the input received by the input device and the relationship The third reconstructed image creating unit creates the third reconstructed image at the addition ratio specified by the specifying unit.

  According to the above aspect, the relationship between the radiation dose, the amount of image noise, the addition ratio of the first reconstructed image and the second reconstructed image is stored in the storage device, and Based on the input received by the input device and the relationship, the addition ratio of the first reconstructed image and the second reconstructed image is specified, and a third reconstructed image is created. Thereby, the freedom degree of the combination by the user of the dose of the radiation at the time of producing a reconstructed image, image reconstruction conditions, and the amount of image noise can be raised.

It is a figure which shows schematically the structure of the hardware of the X-ray CT apparatus which concerns on embodiment. It is a functional block diagram of the operation console of the X-ray CT apparatus shown in FIG. It is a conceptual diagram explaining preparation of a 1st reconstruction image, a 2nd reconstruction image, and a 3rd reconstruction image. It is a figure which shows an example of a table. It is explanatory drawing which shows the several image reconstruction function in the relationship between a spatial resolution and an image noise amount. It is a figure which shows the user interface which sets the amount of image noises. It is a figure which shows the state which made the slider in a user interface slide.

  Hereinafter, embodiments of the present invention will be described. FIG. 1 shows an X-ray CT apparatus 1 which is an example of an embodiment of a radiation tomography apparatus according to the present invention. As shown in FIG. 1, the X-ray CT apparatus 1 includes a gantry 2, an imaging table 4, and an operation console 6.

  The gantry 2 includes an X-ray tube 21, an aperture 22, a collimator device 23, an X-ray detector 24, a data collection unit 25, a rotation unit 26, a high voltage power supply 27, an aperture drive device 28, and a rotation drive A device 29 and a gantry table control unit 30 are provided.

  The X-ray tube 21 and the X-ray detector 24 are arranged to face each other with the opening 2B interposed therebetween. While the X-ray tube 21 and the X-ray detector 24 rotate with the rotation of the rotating unit 26, X-rays are irradiated from the X-ray tube 21 onto the imaging target 5, and scanning is performed. The X-ray tube 21 and the X-ray detector 24 are an example of an embodiment of a scan device in the present invention.

  The aperture 22 is disposed between the X-ray tube 21 and the opening 2B. X-rays radiated from the X-ray focal point of the X-ray tube 21 toward the X-ray detector 24 are formed into a fan beam and a cone beam.

  The collimator device 23 is disposed between the opening 2 </ b> B and the X-ray detector 24. The collimator device 23 removes scattered radiation incident on the X-ray detector 24.

  The X-ray detector 24 is a plurality of two-dimensionally arranged in the spreading direction (referred to as the channel direction) and the thickness direction (referred to as the column direction) of the fan-shaped X-ray beam emitted from the X-ray tube 21. It has an X-ray detection element. Each X-ray detection element detects a transmission X-ray of the imaging object 5 arranged in the opening 2B, and outputs an electric signal corresponding to the intensity. The imaging target 5 is a living body such as a human being or an animal.

  The data collection unit 25 receives an electrical signal output from each X-ray detection element of the X-ray detector 24, converts it into X-ray data, and collects it. This X-ray data is referred to as projection data.

  The rotating part 26 is supported so as to be rotatable around the opening 2B. An X-ray tube 21, an aperture 22, a collimator device 23, an X-ray detector 24, and a data collection unit 25 are mounted on the rotation unit 26.

  The imaging table 4 includes a cradle 41 and a cradle driving device 42. The imaging target 5 is placed on the cradle 41. The cradle driving device 42 puts the cradle 41 into and out of the opening 2B of the gantry 2, that is, the photographing space.

  The high voltage power supply 27 supplies a high voltage and current to the X-ray tube 21.

  The aperture driving device 28 drives the aperture 22 to deform its opening.

  The rotation drive device 29 drives the rotation unit 26 to rotate.

  The gantry / table control unit 30 controls each device / unit in the gantry 2, the imaging table 4, and the like.

  The operation console 6 receives various operations from the operator. The operation console 6 includes an input device 61, a display device 62, a storage device 63, and an arithmetic processing device 64. In this example, the operation console 6 is configured by a computer.

  The input device 61 includes a button for receiving an instruction and information input from an operator, a keyboard, and the like, and further includes a pointing device. The display device 62 is an LCD (Liquid Crystal Display), an organic EL (Electro-Luminescence) display, or the like. The input device 61 is an example of an embodiment of the input device in the present invention.

  The storage device 63 is an HDD (Hard Disk Drive), a semiconductor memory such as a RAM (Random Access Memory), a ROM (Read Only Memory), or the like. The operation console 6 may have all of the HDD, RAM, and ROM as the storage device 63.

  The arithmetic processing device 64 is a processor such as a CPU (central processing unit).

  An external storage medium 90 may be connected to the operation console 6. The external storage medium 90 is a non-transitory non-transitory storage medium such as a CD (Compact Disk), a DVD (Digital Versatile Disk), a USB (Universal Serial Bus) memory, and a hard disk.

  The storage device 63 and the external storage medium 90 are an example of an embodiment of a storage device in the present invention.

  Here, as shown in FIG. 1, the body axis direction of the imaging target 5, that is, the conveyance direction of the imaging target 5 by the imaging table 4 is the z direction. The vertical direction is the y direction, and the horizontal direction orthogonal to the y direction and the z direction is the x direction.

  As shown in FIG. 2, the operation console 6 includes, as function blocks, a scan control unit 71, a first reconstructed image creating unit 72, a second reconstructed image creating unit 73, and a third reconstructed image creating unit 74. And a specifying unit 75 and a display control unit 76. The arithmetic processing device 64 uses the predetermined program (program), the scan control unit 71, the first reconstructed image creating unit 72, the second reconstructed image creating unit 73, and the third reconstructed image creating unit 74 described above. The functions of the specifying unit 75 and the display control unit 76 are executed. For example, the predetermined program is stored in a non-transitory storage medium such as an HDD or a ROM constituting the storage device 63. The program may be stored in an externally connected non-transitory external storage medium 90.

  The scan control unit 71 controls the gantry / table control unit 30 so that a scan is performed in a required range in the body axis direction (z direction) of the imaging target 5 in accordance with an operation of the operator.

  The first reconstructed image creating unit 72 creates a first reconstructed image by performing image reconstruction processing based on the first image reconstruction condition based on the projection data obtained by the X-ray scan. . The first reconstructed image creating unit 72 is an example of an embodiment of the first reconstructed image creating unit in the present invention.

  Based on the projection data, the second reconstructed image creating unit 73 performs image reconstruction processing under a second image reconstruction condition that is different from the first image reconstruction condition, and generates a second reconstructed image. create. The second reconstructed image creating unit 73 is an example of an embodiment of the second reconstructed image creating unit in the present invention.

  The third reconstructed image creating unit 74 adds the first reconstructed image and the second reconstructed image to create a third reconstructed image. The third reconstructed image creating unit 74 is an example of an embodiment of a third reconstructed image creating unit in the present invention.

  For example, the specifying unit 75 specifies the addition ratio of the first reconstructed image and the second reconstructed image. Details will be described later. The specifying unit 75 is an example of an embodiment of the specifying unit in the present invention.

  The display control unit 76 controls the display device 62 to display various images and text (text) on the screen.

  Next, processing in the X-ray CT apparatus 1 according to the present embodiment will be described. In the X-ray CT apparatus 1, the X-ray tube 21 and the X-ray detector 24 rotate around the body axis of the subject to perform X-ray scanning and collect projection data. Projection data is collected at least for the number of views necessary for image reconstruction (projection data of a plurality of views corresponding to 180 ° + fan angle α or 360 °).

  When the projection data is collected, an image reconstruction process is performed after a predetermined pre-process is performed on the projection data. The image reconstruction process will be specifically described. As shown in FIG. 3, the first reconstructed image creation unit 72 performs image reconstruction processing on the projection data PD according to the first image reconstruction condition to create data of the first reconstructed image Im1. To do. The first image reconstruction condition is a first image reconstruction function. In addition, the second reconstructed image creating unit 73 performs image reconstruction processing on the projection data PD according to the second image reconstruction condition to create data of the second reconstructed image Im2. The second image reconstruction condition is a second image reconstruction function.

As shown in FIG. 3, the third reconstructed image creating unit 74 adds the data of the first reconstructed image Im1 and the data of the second reconstructed image Im2 at a predetermined ratio, thereby performing the third reconstructed image. Data of the image Im3 is created. In FIG. 3, the data of the third reconstructed image Im3 is created by the following (Formula 1). However, (Formula 1) is an example.
Im3 = Im1 × α + Im2 × (1−α) (Formula 1)
In (Formula 1), 0 <α <1.

  The display control unit 76 may display the third reconstructed image Im3 on the display device 63.

  The third reconstructed image creating unit 74 creates the third reconstructed image Im3 after the specifying unit 75 specifies the addition ratio of the first reconstructed image Im1 and the second reconstructed image Im2. . The specification of the addition ratio will be described. The timing at which the addition ratio is specified is, for example, when the X-ray CT apparatus 1 is installed in a facility such as a hospital or immediately before the actual imaging is performed. The storage device 63 stores the relationship between the X-ray dose, the image noise amount, and the addition ratio of the first reconstructed image Im1 and the second reconstructed image Im2. This relationship may be stored in the external storage medium 90. The specifying unit 75 specifies the addition ratio based on the stored relationship and the user input received by the input device 61. The specifying unit 75 receives an input received by the input device 61 that is not received by the input device among the X-ray dose, the amount of image noise, the first image reconstruction function, and the second image reconstruction function. And the relationship is further specified, and the addition ratio is specified.

  The relationship will be described. The relationship is a table TA that defines a relationship between the addition ratio determined according to, for example, the X-ray dose and the image noise amount. For example, as shown in FIG. 4, a plurality of tables TA may be stored according to the X-ray dose. In FIG. 4, four tables TA1, TA2, TA3, and TA4 are shown as the plurality of tables TA. However, these tables TA1 to TA4 are examples, and different tables or more than four tables may be stored.

  Here, tables TA1 to TA4 corresponding to the X-ray doses D1 and D2 are shown. In the tables TA1 to TA4, in accordance with the X-ray doses D1 and D2, the first reconstructed image created by the first image reconstruction function and the second reconstructed function created by the second image reconstruction function are used. An image noise amount corresponding to the addition ratio with the reconstructed image is determined. In each of the tables TA1 to TA4, the addition ratio of the first reconstructed image created by the first image reconstruction function is shown in the upper stage, and the second created by the second image reconstruction function is shown in the middle stage. The addition ratio of the reconstructed image is shown, and the amount of image noise is shown in the lower part.

  The tables TA1 to TA4 will be described in more detail. The X-ray doses D1 and D2 are, for example, absorbed doses and are CTDI values. The tables TA1 to TA4 are tables in which at least one of the first image reconstruction function for creating the first reconstruction image and the second image reconstruction function for creating the second reconstruction image is different from the other tables. Is included. Specifically, in the tables TA1 and TA3, the first image reconstruction function is the function Kernel1, and the second image reconstruction function is the function Kernel2. In the tables TA2 and TA4, the first image reconstruction function is the function Kernel2 and the second image reconstruction function is the function Kernel3.

  The first image reconstruction function and the second image reconstruction function included in the table TA are any of a plurality of image reconstruction functions stored in advance in the storage device 63 or the external storage medium 90. These image reconstruction functions are used in conventional image reconstruction processing, and are a plurality of image reconstruction functions from Kernel-1 to Kernel-n, for example, as shown in FIG. In FIG. 5, the spatial resolution in the reconstructed image is low and the image noise amount is small toward the left side, and the spatial resolution in the reconstructed image is high and the image noise amount is large toward the right side.

  In each of the tables TA1 to TA4, a plurality of addition ratios are defined. In each of the tables TA1 to TA4, the addition ratio is expressed in percent (%), and the image noise amount is determined every 10% from 10% to 90%. Therefore, in the above (Formula 1), 0.1 ≦ α ≦ 0.9.

  The image noise amount in the tables TA1 to TA4 is the image noise amount in the third reconstructed image, for example, the standard deviation (SD) of the CT value in the third reconstructed image.

  In order to specify the addition ratio, the user performs input using the input device 61. The input received by the input device 61 from the user will be described. For example, the user inputs an X-ray dose with the input device 61. The display control unit 76, based on the input X-ray dose, displays an image corresponding to a normal image reconstruction function that is set in advance separately from the first image reconstruction function and the second image reconstruction function. The amount of noise is specified and displayed on the display device 62. As shown in FIG. 6, the display control unit 76 may display a user interface UI indicating the specified image noise amount on the display device 62. This user interface UI includes a bar B and a slider S indicating the specified image noise amount in the bar B. The bar B displays a scale for each of the standard deviations 10 to 20 of CT values as the amount of image noise. Here, the slider S is at the position “10” in the bar B, and indicates that the standard deviation of the CT value specified as the image noise amount is 10.

  The user can set a desired amount of image noise using the displayed user interface UI. The desired image noise amount is the image noise amount in the third reconstructed image. Specifically, the input device 61 receives an input for sliding the slider S by the user. The input for sliding the slider S is an example of the embodiment of the input of the image noise amount in the present invention. The user uses the input device 61 to slide the slider S to the position of the desired image noise amount on the bar B.

  When the input device 61 receives an input for sliding the slider S, the specifying unit 75 uses the table TA based on the amount of image noise corresponding to the position of the slider S and the X-ray dose input as described above. Thus, the addition ratio of the first reconstructed image and the second reconstructed image is specified. The specifying unit 75 is created from the table TA by using the first image reconstruction function, the second image reconstruction function, and the first image reconstruction function corresponding to the input image noise amount and X-ray dose. The addition ratio of the second reconstructed image created by the first reconstructed image and the second image reconstruction function is specified. If at least one of the input image noise amount and the X-ray dose does not exist in the table TA, the specifying unit 75 specifies, for example, the closest image noise amount and X-ray dose in the table TA, and first The image reconstruction function, the second image reconstruction function, and the addition ratio may be specified.

  The first reconstructed image creation unit 72 creates data of the first reconstructed image Im1 using the first image reconstruction function specified by the specifying unit 75. In addition, the second reconstructed image creating unit 73 creates data of the second reconstructed image Im2 using the second image reconstruction function specified by the specifying unit 75. Then, the third reconstructed image creation unit 74 weights and adds the data of the first reconstructed image Im1 and the data of the second reconstructed image Im2 at the addition ratio specified by the specifying unit 75, 3 of the reconstructed image Im3 is created. The third reconstructed image Im3 is the amount of image noise input by the user or an amount of image noise close thereto.

  According to the X-ray CT apparatus 1 of the present example described above, when a user inputs an X-ray dose and an image noise amount, instead of creating a reconstructed image by a stored image reconstruction function, The first reconstructed image Im1 and the second reconstructed image Im2 are added to create a third reconstructed image Im3. Therefore, the third reconstructed image Im3 having a desired image noise amount can be obtained with the X-ray dose desired by the user.

  In addition, since the reconstructed image is not created by the stored image reconstruction function, the X-ray dose, the first image reconstruction function, the second image when the third reconstructed image is created The degree of freedom of combination of the image reconstruction function and the image noise amount by the user can be increased.

  As mentioned above, although this invention was demonstrated by the said embodiment, of course, this invention can be variously implemented in the range which does not change the main point. For example, the input items by the user for specifying the addition ratio are not limited to those described in the above embodiment. For example, the X-ray dose and the image noise amount in the third reconstruction image may be input by the user, and at least one of the first image reconstruction function and the second image reconstruction function may be input. In this case, the identifying unit 75 identifies an image reconstruction function that has not been input, out of the first image reconstruction function and the second image reconstruction function, based on the input item and the table TA. Furthermore, the addition ratio is specified. Further, the first image reconstruction function and the second image reconstruction function may be input by the user, and at least one of the X-ray dose and the image noise amount in the third reconstruction image may be input. In this case, the specifying unit 75 specifies the X-ray dose and the image noise amount that are not input based on the input items and the table TA, and further specifies the addition ratio.

  The storage device 63 or the external storage medium 90 stores a table that defines the relationship between the addition ratio and the X-ray dose determined according to the amount of image noise in the third reconstructed image, instead of the table TA. May be. In this case, a plurality of tables may be stored according to the amount of image noise.

  In addition, in the storage device 63 or the external storage medium 90, instead of the above-described table, a transfer function having the X-ray dose and the image noise amount in the third reconstructed image as inputs and the addition ratio as an output is stored. May be. The transfer function is a function that can specify the first image reconstruction function and the second image reconstruction function in addition to the addition ratio based on the input. Similar to the first image reconstruction function and the second image reconstruction function in the table TA, the first image reconstruction function and the second image reconstruction function are also stored in the storage device 63 and the external storage medium 90. May be any one of a plurality of image reconstruction functions stored in advance. When the input device 61 receives the input of the X-ray dose and the image noise amount by the user, the specifying unit 75 specifies the first image reconstruction function and the second image reconstruction function by the transfer function, and the addition ratio Is identified.

  In addition, the first reconstructed image creating unit 72 and the second reconstructed image creating unit 73 may perform image reconstruction processing by a successive approximation method instead of image reconstruction processing using an image reconstruction function. . In this case, the first image reconstruction condition is the first convergence condition in the successive approximation method, and the second image reconstruction condition is the second convergence condition in the successive approximation method. Accordingly, in the above-described table and transfer function, the first convergence condition and the second convergence condition are used instead of the first image reconstruction function and the second image reconstruction function.

  A program for causing a computer to function as each means for performing control and processing in the X-ray CT apparatus is also an example of an embodiment of the invention.

DESCRIPTION OF SYMBOLS 1 X-ray CT apparatus 3 Central processing unit 21 X-ray tube 24 X-ray detection part 61 Input device 63 Storage device 72 1st reconstruction image creation part 73 2nd reconstruction image creation part 74 3rd reconstruction image creation Part 75 Specific part 90 External storage medium

Claims (13)

A scanning device that performs scanning by irradiating a subject with radiation;
A first reconstructed image creating unit that creates a first reconstructed image by performing image reconstruction processing according to a first image reconstruction condition based on the projection data obtained by the scan;
A second reconstructed image creating unit for creating a second reconstructed image by performing image reconstruction processing based on the second image reconstruction condition based on the projection data;
A third reconstructed image creating unit that creates a third reconstructed image by adding the first reconstructed image and the second reconstructed image;
An input device that accepts an input by an operator, wherein the input is an input of the radiation dose and an image noise amount in the third reconstructed image, or the radiation dose and the third reconstructed image. Or an input including at least one of the first image reconstruction condition and the second image reconstruction condition, or the first image reconstruction condition and the second image reconstruction. An input device that is an input including a condition and at least one of the radiation dose and the amount of image noise in the third reconstructed image;
A storage device for storing a relationship between the radiation dose, the amount of image noise, the addition ratio of the first reconstructed image and the second reconstructed image;
Based on the input received by the input device and the relationship, a specifying unit that specifies the addition ratio,
With
The radiation tomography apparatus according to claim 3, wherein the third reconstructed image creating unit creates the third reconstructed image at the addition ratio specified by the specifying unit.   The specifying unit receives the radiation dose, the image noise amount, the first image reconstruction condition, and the second image reconstruction condition that are not received by the input device. The radiation tomography apparatus according to claim 1, further specifying based on the input and the relationship.   The specification unit further specifies the first image reconstruction condition and the second image reconstruction condition based on the input received by the input device and the relationship. The radiation tomography apparatus described.   4. The radiation tomography according to claim 1, wherein the first image reconstruction condition is a first image reconstruction function, and the second image reconstruction condition is a second image reconstruction function. Shooting device.   The first image reconstruction condition is a first convergence condition in the successive approximation method, and the second image reconstruction condition is a second convergence condition in the successive approximation method. The radiation tomography apparatus according to any one of claims.   The radiation tomography apparatus according to claim 1, wherein the relationship is a table that defines a relationship between the addition ratio determined according to the radiation dose and the image noise amount. .   The radiation tomography apparatus according to claim 1, wherein the relationship is a table that defines a relationship between the addition ratio determined according to the amount of image noise and a dose of the radiation. .   The radiation tomography apparatus according to claim 6, wherein the table includes a plurality of addition ratios.   As the table, a plurality of tables are stored in the storage device, and the plurality of tables differ from other tables in at least one of the first image reconstruction condition and the second image reconstruction condition. The radiation tomography apparatus according to claim 6, further comprising a table.   The radiation tomography apparatus according to claim 1, wherein the relationship is a transfer function having the radiation dose and the image noise amount as inputs and the addition ratio as an output. .   The first image reconstruction condition and the second image reconstruction condition are any one of a plurality of image reconstruction conditions stored in the storage device. The radiation tomography apparatus according to claim 1. A scanning device that performs scanning by irradiating a subject with radiation;
An input device that accepts input by the operator;
A storage device;
A processor;
Characterized by comprising,
The processor is programmed to
A first reconstructed image creation function for creating a first reconstructed image by performing an image reconstruction process according to a first image reconstruction condition based on the projection data obtained by the scan;
A second reconstructed image creating function for creating a second reconstructed image by performing image reconstruction processing based on the second image reconstruction condition based on the projection data;
A third reconstructed image creating function for creating a third reconstructed image by adding the first reconstructed image and the second reconstructed image;
Specific functions,
It is characterized by performing
The input received by the input device is an input of the radiation dose and an image noise amount in the third reconstructed image, or the radiation dose and an image noise amount in the third reconstructed image, The input includes at least one of a first image reconstruction condition and the second image reconstruction condition, or the first image reconstruction condition and the second image reconstruction condition, and the radiation dose. And at least one of the amounts of image noise in the third reconstructed image,
The storage device stores the relationship between the radiation dose, the amount of image noise, the addition ratio of the first reconstructed image and the second reconstructed image,
The identification function is to identify the addition ratio based on the input received by the input device and the relationship.
The radiation tomography apparatus according to claim 3, wherein the third reconstructed image creation function creates the third reconstructed image at the addition ratio specified by the specifying unit. A scanning device that performs scanning by irradiating a subject with radiation;
An input device that accepts input by the operator;
A storage device;
A processor;
A control program for a radiation tomography apparatus comprising:
In the processor,
A first reconstructed image creation function for creating a first reconstructed image by performing an image reconstruction process according to a first image reconstruction condition based on the projection data obtained by the scan;
A second reconstructed image creating function for creating a second reconstructed image by performing image reconstruction processing based on the second image reconstruction condition based on the projection data;
A third reconstructed image creating function for creating a third reconstructed image by adding the first reconstructed image and the second reconstructed image;
Specific functions,
A control program characterized in that
The input received by the input device is an input of the radiation dose and an image noise amount in the third reconstructed image, or the radiation dose and an image noise amount in the third reconstructed image, The input includes at least one of a first image reconstruction condition and the second image reconstruction condition, or the first image reconstruction condition and the second image reconstruction condition, and the radiation dose. And at least one of the amounts of image noise in the third reconstructed image,
The storage device stores the relationship between the radiation dose, the amount of image noise, the addition ratio of the first reconstructed image and the second reconstructed image,
The identification function is to identify the addition ratio based on the input received by the input device and the relationship.
The control program for a radiation tomography apparatus, wherein the third reconstructed image creating function creates the third reconstructed image at the addition ratio specified by the specifying unit.