JP5965043B2 - Correction image creating apparatus, radiation image photographing apparatus, photographing apparatus, program, and correction image creating method - Google Patents

Description

  The present invention relates to a correction image creating apparatus, a radiographic image capturing apparatus, a photographing apparatus, a program, and a correction image creating method, and in particular, a correction image creating apparatus for creating a correction image for offset correction, and a radiation image. The present invention relates to an imaging device, an imaging device, a program, and a correction image creation method.

  Conventionally, in an imaging apparatus such as a television camera, the black level of an imaging result is set to a predetermined signal level by a clamping process. For example, in a CCD solid-state imaging device, incident light is photoelectrically converted by sensor units arranged in a matrix, and the accumulated charges obtained as a result are sequentially transferred and output. In the CCD solid-state imaging device, an optical black region is created by shielding a part of the imaging surface in which the sensor units are arranged in a matrix in this way, and the optical black region is optically controlled by the output signal level of the optical black region. The black level can be detected. As a result, in the imaging device, the output signal of the imaging device obtained from the optical black region is integrated to obtain a predetermined evaluation value, and the output signal level of the imaging device is offset so that the evaluation value becomes a predetermined value. Thus, a feedback loop is formed to set the black level of the imaging result to a predetermined signal level.

  However, in this imaging apparatus, when the signal level of the imaging result obtained from the optical black region changes instantaneously due to noise mixing, the evaluation value changes temporarily, and the black level is corrected so as to correct this change. Will be corrected.

  As a technique for solving this problem, Patent Document 1 discloses that in an imaging apparatus, an optical black level based on an output signal level of an optical black area in which a partial area of an imaging surface is shielded is detected, and according to the detected value. A technique for offsetting an output signal level of an image sensor is disclosed. Specifically, this imaging apparatus integrates the luminance level obtained from the optical black area in units of frames, detects an evaluation value indicating the optical black level of the imaging result, and calculates the integration value based on the detection data. The detection value is set, the luminance level of the image data is offset by the correction value based on the detection value, and the black level of the imaging result is clamped to a predetermined signal level.

  In recent years, there has been a digital photographing apparatus that directly digitizes a radiation image without using an optical system or the like by using a radiation flat panel detector (FPD) in which a phosphor and a large area amorphous silicon sensor are closely attached. It has been put into practical use. An FPD that converts radiation into electrons using amorphous selenium, lead iodide (PbI2), mercury iodide (HgI2), etc., and detects the electrons with a large area amorphous silicon sensor has also been put into practical use. These FPDs are expected as next-generation digital photographing devices because they can shoot not only still images but also moving images in principle.

  The sensor used for FPD consists of several million pixels, but the characteristics of each pixel are different. Particularly important characteristics as an image sensor are dark current characteristics and sensitivity characteristics. Therefore, the FPD performs offset correction for correcting these characteristics, and is used as a sensor with substantially uniform characteristics of each pixel.

Japanese Patent Laid-Open No. 2003-110943

  In the technique of the above-mentioned patent document 1, when acquiring a correction value for offset correction, an original function is required to obtain a correction value with high accuracy from which noise is removed, and the correction value is acquired. There was a problem that it took a certain amount of time to do so. There has been a demand for a technique for easily creating a correction image with less noise for offset correction in an imaging apparatus and a radiographic imaging apparatus.

  The present invention has been made in order to solve the above-described problems, and does not create a correction image on which noise is superimposed when creating a correction image for offset correction, and a correction image with less noise. It is an object of the present invention to provide a correction image generation apparatus, a radiographic image capturing apparatus, an image capturing apparatus, a program, and a correction image generation method.

  In order to achieve the above object, the correction image creating apparatus of the present invention acquires at least one original image that is used when creating a correction image used for offset correction with respect to an image obtained by shooting. Determining means for determining whether or not external noise, which is at least one of noise caused by scattered radiation of radiation, noise caused by impact, and noise caused by electromagnetic waves, is superimposed on the original image; and the determining means And creating means for creating the correction image using only the original image determined to have no external noise superimposed thereon.

  According to this correction image creating apparatus, at least one original image that is used when creating a correction image used for offset correction with respect to an image obtained by shooting is acquired by the acquisition unit, and the determination unit It is determined whether or not noise from the outside, which is at least one of noise caused by scattered radiation of radiation, noise caused by impact, and noise caused by electromagnetic waves, is superimposed on the original image. The correction image is created using only the original image that is determined not to be superimposed with noise.

  Thus, according to this correction image creating apparatus, only the original image on which no external noise, which is at least one of noise due to scattered radiation of radiation, noise due to impact, and noise due to electromagnetic waves, is superimposed is used. By creating a correction image, it is possible to avoid creating a correction image on which noise is superimposed. As a result, it is possible to easily create a correction image with less noise for offset correction.

  In the correction image creating apparatus according to the present invention, the acquisition unit irradiates the subject with radiation from a radiation generation source, and detects the radiation transmitted through the subject with a detector, thereby capturing a radiation image of the subject. The radiographic image captured without irradiating the subject from the radiation generation source may be acquired as the original image by the imaging device. Thereby, it is possible to easily create a correction image with less noise for offset correction on the radiation image.

  In the correction image creating apparatus of the present invention, the acquisition unit may acquire an image photographed by a solid-state imaging device in the absence of incident light as the original image. Thereby, it is possible to easily create a correction image with less noise for offset correction on an image shot by visible light shooting.

  Further, in the correction image creating apparatus according to the present invention, the determination means compares the average value of the pixel values in the plurality of regions in the original image with a predetermined threshold value, thereby comparing noise caused by scattered radiation. It may be determined whether or not is superimposed. Thereby, it is possible to easily detect noise due to scattered rays superimposed on the correction image for offset correction.

  Further, in the correction image creating apparatus according to the present invention, the determination means includes a difference between pixel values of corresponding pixels between the offset correction image that has already been created and the original image, and corresponding pixels of the original images. Pixel value difference, difference image obtained from a plurality of original images on which noise is not superimposed and the difference between the pixel values of corresponding pixels of the original image, or an average image of a plurality of original images on which noise is not superimposed Determine whether noise due to impact is superimposed based on the difference in pixel value of the corresponding pixel from the original image and the number of pixels in the difference from the reference value of the histogram expressed by the number of pixels relative to the difference You may make it do. Thereby, it is possible to easily detect noise due to an impact superimposed on a correction image for offset correction.

  In the correction image creating apparatus according to the present invention, the determination unit may calculate a difference between pixel values of corresponding pixels between the offset correction image that has already been created and the original image, and the number of pixels corresponding to the difference. Whether or not noise due to electromagnetic waves is superimposed may be determined based on the degree to which the represented histogram spreads. Thereby, it is possible to easily detect noise due to electromagnetic waves superimposed on the correction image for offset correction.

  In the correction image creating apparatus of the present invention, the determination unit may use, as the original image, an image obtained by removing noise due to a defective pixel by a median filter in the original image. Thereby, it is possible to accurately detect noise superimposed on the correction image for offset correction.

  On the other hand, in order to achieve the above object, the radiographic imaging device of the present invention irradiates a subject with radiation from the correction image creation device of the present invention and a radiation generation source, and detects the radiation transmitted through the subject with a detector. By doing so, an imaging device for taking a radiographic image of the subject is provided.

  Therefore, according to the radiographic image capturing apparatus of the present invention, since it operates in the same manner as the correction image generating apparatus of the present invention, noise is generated when a correction image is generated as in the correction image generating apparatus of the present invention. It is possible to easily create a correction image with less noise for offset correction without creating a superimposed correction image.

  On the other hand, in order to achieve the above object, a photographing apparatus of the present invention includes the correction image creating apparatus of the present invention and a photographing apparatus having a solid-state image sensor.

  Therefore, according to the photographing apparatus of the present invention, since it operates in the same manner as the correction image creation apparatus of the present invention, noise is superimposed when creating the correction image, as in the correction image creation apparatus of the present invention. Therefore, it is possible to easily create a correction image with less noise for offset correction.

  On the other hand, in order to achieve the above object, the program of the present invention causes a computer to function as the correction image creating apparatus of the present invention.

  Therefore, according to the program of the present invention, the computer can be operated in the same manner as the offset image creating apparatus of the present invention. Therefore, as with the offset image creating apparatus of the present invention, noise is generated when creating the correction image. It is possible to easily create a correction image with less noise for offset correction without creating a superimposed correction image.

  On the other hand, in order to achieve the above object, the offset image creation method of the present invention obtains at least one original image used when creating a correction image used for offset correction for an image obtained by shooting. An acquisition step; a determination step for determining whether or not noise from the outside, which is at least one of noise due to scattered radiation of radiation, noise due to impact, and noise due to electromagnetic waves, is superimposed on the original image; and the determination And a creation step of creating the correction image using only the original image determined to have no external noise superimposed in the step.

  According to the offset image creation method of the present invention, since it operates in the same manner as the offset image creation apparatus of the present invention, correction with noise superimposed when creating a correction image as in the offset image creation apparatus of the present invention. Therefore, a correction image with less noise for offset correction can be easily generated.

  According to the present invention, when a correction image for offset correction is created, a correction image on which noise is superimposed is not created, and a correction image with less noise can be easily created. Play.

It is a block diagram which shows the whole structure of the system by which the radiographic imaging system which concerns on embodiment is applied. It is a figure which shows an example of the arrangement | positioning state of each apparatus in the radiography room of the imaging system which concerns on embodiment. It is a figure which shows the internal structure of the electronic cassette concerning embodiment. It is a block diagram which shows the principal part structure of the electric system of the imaging | photography system which concerns on embodiment. It is a flowchart which shows the flow of the imaging | photography control processing in the imaging | photography system which concerns on embodiment. It is a figure which shows an example of the initial stage information input screen in the imaging | photography system which concerns on embodiment. It is a flowchart which shows the flow of the offset image update process in the imaging | photography system which concerns on 1st Embodiment. (A) is a schematic diagram which shows an example of the image which the impact noise generate | occur | produced in the imaging system which concerns on 1st Embodiment, (B) is the image of the electromagnetic wave noise which occurred in the imaging system which concerns on 1st Embodiment. It is a schematic diagram which shows an example. In the imaging system according to the embodiment, the pixel value of each pixel in the difference image between the image captured last time and the image captured this time is a histogram in which the horizontal axis represents the pixel value (QL value) and the vertical axis represents the number of pixels. Yes, (A) is a diagram showing a case where impact noise is not generated, and (B) is a diagram showing a case where impact noise is generated. It is the schematic for demonstrating the impact noise detection process in the imaging | photography system which concerns on embodiment. (A) shows the pixel value of each pixel in the difference image between the image captured last time and the image captured this time in the imaging system according to the embodiment, the horizontal axis indicates the pixel value (QL value), and the vertical axis indicates the number of pixels. (B) is a diagram showing the graph of (A) with the scale changed. It is the schematic for demonstrating the electromagnetic wave noise detection process in the imaging | photography system which concerns on embodiment. It is a figure which shows an example of the detection object area | region in the imaging | photography system which concerns on embodiment. It is a flowchart which shows the flow of the offset image update process in the imaging | photography system which concerns on 2nd Embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram showing an overall configuration of a system 10 to which a radiation image capturing system 18 according to the first embodiment is applied. First, an overall configuration of a system 10 to which a radiation imaging system (hereinafter referred to as “RIS (Radiology Information System)”) 18 according to the first embodiment is applied will be described with reference to FIG.

  The RIS 10 is a system for managing information such as medical appointments and diagnostic records in the radiology department, and constitutes a part of a hospital information system (hereinafter referred to as “HIS (Hospital Information System)”). To do.

  The RIS 10 includes a plurality of radiography requesting terminal devices (hereinafter referred to as “terminal devices”) 12, a RIS server 14, and a radiographic imaging system (or an operating room) installed in a radiography room (or operating room) in a hospital. (Hereinafter referred to as “imaging system”) 18, which are respectively connected by an in-hospital network 16 comprising a wired or wireless LAN (Local Area Network). The RIS 10 constitutes a part of the HIS provided in the same hospital, and an HIS server (not shown) that manages the entire HIS is also connected to the in-hospital network 16.

  The terminal device 12 is a device for a doctor or a radiographer to input or view diagnostic information and facility reservation, and a radiographic image capturing request and imaging reservation are also performed via the terminal device 12. Each terminal device 12 includes a display device and a personal computer, and can communicate with each other via the RIS server 14 and the hospital network 16.

  On the other hand, the RIS server 14 receives an imaging request from each terminal device 12 and manages a radiographic imaging schedule in the imaging system 18, and includes a database 14A.

  Database 14A includes patient (subject) attribute information (name, sex, date of birth, age, blood type, weight, patient ID (Identification), etc.), medical history, medical history, radiation images taken in the past, etc. Information on the patient, identification number (ID information) of the electronic cassette 32, which will be described later, used in the imaging system 18, model, size, sensitivity, usable imaging part (content of imaging request that can be handled), and date of start of use Information regarding the electronic cassette 32 such as the date and the number of times of use, and an environment in which a radiographic image is taken using the electronic cassette 32, that is, an environment in which the electronic cassette 32 is used (for example, a radiographic room or an operating room) It contains information.

  The imaging system 18 captures a radiographic image by an operation of a doctor or a radiographer according to an instruction from the RIS server 14. The imaging system 18 includes a radiation generator 34 that irradiates a subject with radiation X (see also FIG. 3) that is a dose according to the exposure conditions from a radiation source 130 (see also FIG. 2), and a subject. Electrons that incorporate a radiation detector 60 (see also FIG. 3) that absorbs radiation X transmitted through the imaging region of the person and generates charges and generates image information indicating a radiation image based on the amount of generated charges. A cassette 32, a cradle 40 that charges a battery built in the electronic cassette 32, an electronic cassette 32, a radiation generator 34, and a console 42 that controls the cradle 40 are provided.

  The console 42 acquires various types of information included in the database 14A from the RIS server 14 and stores them in an HDD 110 (see FIG. 4) described later. Based on the information, the electronic cassette 32, the radiation generator 34, and the cradle 40 are stored. Control.

  FIG. 2 is a diagram illustrating an example of an arrangement state of each device in the radiation imaging room 44 of the imaging system 18 according to the first embodiment. As shown in FIG. 2, the radiation imaging room 44 is provided with a rack 45 used when performing radiation imaging in a standing position and a bed 46 used when performing radiation imaging in a lying position. The space in front of the rack 45 is a subject imaging position 48 when performing radiography in a standing position, and the space above the bed 46 is an imaging position 50 of a subject in performing radiography in a prone position. It is said that.

  The rack 45 is provided with a holding unit 150 that holds the electronic cassette 32, and the electronic cassette 32 is held by the holding unit 150 when a radiographic image is taken in a standing position. Similarly, the bed 46 is provided with a holding unit 152 that holds the electronic cassette 32, and the electronic cassette 32 is held by the holding unit 152 when a radiographic image is taken in the prone position.

  Further, in the radiation imaging room 44, the radiation source 130 is arranged around a horizontal axis (see FIG. 5) in order to enable radiation imaging in a standing position and in a standing position by radiation from a single radiation source 130. 2 is provided, and a support moving mechanism 52 is provided which can be rotated in the vertical direction (arrow B direction in FIG. 2) and supported so as to be movable in the horizontal direction (arrow C direction in FIG. 2). It has been. Here, the support moving mechanism 52 includes a drive source that rotates the radiation source 130 about a horizontal axis, a drive source that moves the radiation source 130 in the vertical direction, and a drive source that moves the radiation source 130 in the horizontal direction. Each is provided (not shown).

  On the other hand, the cradle 40 is formed with an accommodating portion 40 </ b> A capable of accommodating the electronic cassette 32.

  When the electronic cassette 32 is not in use, the built-in battery is charged in a state of being accommodated in the accommodating portion 40A of the cradle 40. When a radiographic image is captured, the electronic cassette 32 is taken out from the cradle 40 by a radiographer or the like, and the imaging posture is established. If it is in the up position, it is held in the holding section 150 of the rack 45, and if it is in the upright position, it is held in the holding section 152 of the bed 46.

  Here, in the imaging system 18 according to the present embodiment, various types of information are transmitted and received between the radiation generator 34 and the console 42 and between the electronic cassette 32 and the console 42 by wireless communication.

  Note that the electronic cassette 32 is not used only in the radiography room or the operating room, but can be used for, for example, examinations and rounds in hospitals because of its portability.

  FIG. 3 is a diagram showing an internal configuration of the electronic cassette 32 according to the first embodiment. As shown in FIG. 3, the electronic cassette 32 includes a housing 54 made of a material that transmits the radiation X, and has a waterproof and airtight structure. When the electronic cassette 32 is used in an operating room or the like, there is a risk that blood and other germs may adhere. Therefore, one electronic cassette 32 can be used repeatedly by sterilizing and cleaning the electronic cassette 32 as necessary with a waterproof and airtight structure.

  Inside the housing 54, a grid 58 for removing scattered radiation of the radiation X by the subject and the radiation X transmitted through the subject are detected from the irradiation surface 56 side of the housing 54 to which the radiation X is irradiated. A radiation detector 60 and a lead plate 62 that absorbs backscattered rays of radiation X are arranged in this order. Note that the irradiation surface 56 of the housing 54 may be configured as a grid 58.

  In addition, an electronic circuit including a microcomputer and a chargeable and detachable battery 96 </ b> A are arranged on one end side inside the housing 54. The radiation detector 60 and the electronic circuit are operated by electric power supplied from a battery 96 </ b> A disposed in the case 31. In order to avoid various circuits housed in the case 31 from being damaged by the radiation X irradiation, it is desirable to arrange a lead plate or the like on the irradiation surface 56 side of the case 31. The electronic cassette 32 according to the present embodiment is a rectangular parallelepiped whose irradiation surface 56 has a rectangular shape, and a case 31 is disposed at one end in the longitudinal direction.

  In addition, at a predetermined position on the outer wall of the casing 54, there are a power switch 54A, an operation mode such as an on / off state of the power switch 54A (on state), “ready state”, “during data transmission”, a battery 96A. A display unit 56 </ b> A is provided that performs a display indicating an operation state of the electronic cassette 32 such as a remaining capacity state. In the electronic cassette 32 according to the present embodiment, a light emitting diode is applied as the display unit 56A. However, the present invention is not limited to this, and other light emitting elements other than the light emitting diode, a liquid crystal display, an organic EL display, and the like are used. It may be a display means.

  Further, a handle 54 </ b> B that is gripped when the electronic cassette 32 is moved is provided at a predetermined position on the outer wall of the housing 54. In the electronic cassette 32 according to the present exemplary embodiment, the handle 54B is provided at the central portion of the side wall of the casing 54 that extends in the longitudinal direction of the irradiation surface 56. It may be provided at other positions such as the central portion of the side wall extending in the short direction of the surface 56, a position deviated by a distance considering the deviation of the center of gravity of the electronic cassette 32 from the central portion of these side walls, etc. Needless to say.

  Next, with reference to FIG. 4, the configuration of the main part of the electrical system of the imaging system 18 according to the first embodiment will be described. FIG. 4 is a block diagram showing the main configuration of the electrical system of the imaging system 18 according to the first embodiment.

  As shown in FIG. 4, the radiation detector 60 built in the electronic cassette 32 is configured by laminating a photoelectric conversion layer that absorbs radiation X and converts it into charges on a TFT active matrix substrate 66. The photoelectric conversion layer is made of amorphous a-Se (amorphous selenium) containing, for example, selenium as a main component (for example, a content rate of 50% or more), and when irradiated with radiation X, a charge corresponding to the amount of irradiated radiation. By generating a certain amount of charge (electron-hole pairs) internally, the irradiated radiation X is converted into a charge. The radiation detector 60 is indirectly charged using a phosphor material and a photoelectric conversion element (photodiode) instead of the radiation-charge conversion material that directly converts the radiation X such as amorphous selenium into an electric charge. May be converted to As phosphor materials, gadolinium sulfate (GOS) and cesium iodide (CsI) are well known. In this case, radiation X-light conversion is performed using a phosphor material, and light-charge conversion is performed using a photodiode of a photoelectric conversion element. Moreover, you may apply the thing using an organic photoelectric conversion material as said photoelectric conversion element. Furthermore, CsI (Tl) or the like may be applied as the cesium iodide.

  Further, on the TFT active matrix substrate 66, a pixel portion 74 (in FIG. 4) provided with a storage capacitor 68 for storing the charge generated in the photoelectric conversion layer and a TFT 70 for reading out the charge stored in the storage capacitor 68. A number of photoelectric conversion layers corresponding to the individual pixel portions 74 are schematically shown as the photoelectric conversion portions 72.) A large number of photoelectric conversion layers are arranged in a matrix, and photoelectric conversion occurs as the electronic cassette 32 is irradiated with the radiation X. The charges generated in the layers are stored in the storage capacitors 68 of the individual pixel portions 74. As a result, the image information carried on the radiation X irradiated to the electronic cassette 32 is converted into charge information and held in the radiation detector 60.

  The TFT active matrix substrate 66 is extended in a certain direction (row direction), a plurality of gate wirings 76 for turning on / off the TFTs 70 of the individual pixel portions 74, and a direction orthogonal to the gate wirings 76. A plurality of data wirings 78 are provided so as to read the stored charge from the storage capacitor 68 via the TFT 70 which is extended in the (column direction) and turned on. Individual gate lines 76 are connected to a gate line driver 80, and individual data lines 78 are connected to a signal processing unit 82. When charges are accumulated in the storage capacitors 68 of the individual pixel portions 74, the TFTs 70 of the individual pixel portions 74 are sequentially turned on in units of rows by a signal supplied from the gate line driver 80 via the gate wiring 76. The charge stored in the storage capacitor 68 of the pixel unit 74 for which is turned on is transmitted as an analog electrical signal through the data wiring 78 and input to the signal processing unit 82. Accordingly, the charges accumulated in the storage capacitors 68 of the individual pixel portions 74 are sequentially read out in units of rows.

  The electronic cassette 32 may be configured by a back side reading method (so-called PSS (Penetration Side Sampling) method) in which a photoelectric conversion layer and a TFT active matrix substrate 66 are laminated in order from the surface side irradiated with the radiation X. Alternatively, the TFT active matrix substrate 66 and the photoelectric conversion layer may be stacked in order from the surface side irradiated with the radiation X (surface reading method (so-called ISS (Irradiation Side Sampling) method)).

  On the other hand, the signal processing unit 82 includes an amplifier and a sample and hold circuit provided for each data line 78, and the charge signal transmitted through the individual data line 78 is amplified by the amplifier and then supplied to the sample and hold circuit. Retained. Further, a multiplexer and an A / D (analog / digital) converter are sequentially connected to the output side of the sample and hold circuit, and the charge signals held in the individual sample and hold circuits are sequentially (serially) input to the multiplexer. The digital image data is converted by an A / D converter.

  An image memory 90 is connected to the signal processing unit 82, and image data output from the A / D converter of the signal processing unit 82 is sequentially stored in the image memory 90. The image memory 90 has a storage capacity capable of storing image data for a plurality of frames, and image data obtained by imaging is sequentially stored in the image memory 90 every time a radiographic image is captured.

  The image memory 90 is connected to a cassette control unit 92 that controls the operation of the entire electronic cassette 32. The cassette control unit 92 includes a microcomputer, and includes a CPU (Central Processing Unit) 92A, a memory 92B including a ROM (Read Only Memory) and a RAM (Random Access Memory), an HDD (Hard Disk Drive), and a flash memory. A non-volatile storage unit 92 </ b> C is provided.

  A wireless communication unit 94 is connected to the cassette control unit 92. The wireless communication unit 94 according to the present embodiment corresponds to a wireless LAN (Local Area Network) standard represented by IEEE (Institute of Electrical and Electronics Engineers) 802.11a / b / g and the like. Controls the transmission of various information to and from external devices. The cassette control unit 92 can wirelessly communicate with the console 42 via the wireless communication unit 94, and can transmit and receive various information to and from the console 42.

  The electronic cassette 32 is provided with a power supply unit 96, and the various circuits and elements described above (gate line driver 80, signal processing unit 82, image memory 90, wireless communication unit 94, cassette control unit 92, etc.) The power is supplied from the power supply unit 96. The power supply unit 96 incorporates the above-described battery (secondary battery) 96A so as not to impair the portability of the electronic cassette 32, and supplies power from the charged battery 96A to various circuits and elements. In FIG. 4, illustration of wirings connecting the power supply unit 96 to various circuits and elements is omitted.

  On the other hand, the console 42 is configured as a server computer, and includes a display 100 that displays an operation menu, captured radiographic images, and the like, and a plurality of keys, and inputs various information and operation instructions. An operation panel 102.

  The console 42 according to the present embodiment includes a CPU 104 that controls the operation of the entire apparatus, a ROM 106 that stores various programs including a control program in advance, a RAM 108 that temporarily stores various data, and various data. It includes an HDD 110 that stores and holds, a display driver 112 that controls display of various types of information on the display 100, and an operation input detection unit 114 that detects an operation state of the operation panel 102. In addition, the console 42 transmits and receives various types of information such as an exposure condition, which will be described later, to and from the radiation generator 34 and also transmits and receives various types of information such as image data to and from the electronic cassette 32 by wireless communication. A wireless communication unit 118 is provided.

  The CPU 104, the ROM 106, the RAM 108, the HDD 110, the display driver 112, the operation input detection unit 114, and the wireless communication unit 118 are connected to each other via a system bus BUS. Therefore, the CPU 104 can access the ROM 106, RAM 108, and HDD 110, controls display of various information on the display 100 via the display driver 112, and the radiation generator 34, via the wireless communication unit 118. Control of transmission and reception of various types of information with the electronic cassette 32 can be performed. Further, the CPU 104 can grasp the operation state of the user with respect to the operation panel 102 via the operation input detection unit 114.

  On the other hand, the radiation generator 34 includes a radio communication unit 132 that transmits and receives various types of information such as an exposure condition between the radiation source 130 and the console 42, and a line that controls the radiation source 130 based on the received exposure condition. A source control unit 134.

  The radiation source control unit 134 is also configured to include a microcomputer, and stores the received exposure conditions and the like. The exposure conditions received from the console 42 include information such as tube voltage, tube current, and exposure period. The radiation source controller 134 irradiates the radiation X from the radiation source 130 based on the received exposure conditions.

  Next, the flow of shooting control processing in the shooting system 18 according to the first embodiment will be described.

  FIG. 5 is a flowchart showing the flow of the imaging control process in the imaging system 18 according to the first embodiment. The radiography control process is executed by the CPU 104 of the console 42 when radiographic images are radiographed, and the radiography control process program is stored in advance in a predetermined area of the ROM 106.

  In step S <b> 201, the CPU 104 controls the display driver 112 so that a predetermined initial information input screen is displayed on the display 100.

  FIG. 6 is a diagram illustrating an example of an initial information input screen in the imaging system 18 according to the first embodiment. As shown in FIG. 6, the initial information input screen shows the name of the subject who is going to take a radiographic image, the imaging region, the posture at the time of imaging (in the present embodiment, standing or standing), and at the time of imaging. A message prompting the user to input information on various items such as radiation X exposure conditions (in this embodiment, tube voltage, tube current, and exposure period when the radiation X is exposed), An input area for initial information and an end button indicating that the input by the photographer has ended are displayed. The photographer inputs initial information regarding various items via the operation panel 102 according to the initial information input screen, and then selects an end button.

  In step S203, the CPU 104 determines whether or not input of initial information is completed. At this time, the CPU 104 determines that the input of the initial information is completed, for example, when the end button on the initial information input screen is selected.

  If it is determined in step S203 that the input of the initial information has been completed, in step S205, the CPU 104 determines, based on the input initial information, the radiation X based on the time point when the radiation detector 60 starts charge accumulation. Is estimated (hereinafter referred to as “exposure end point”).

  Note that, in the imaging system 18 according to the present embodiment, the exposure end time is set to the time point when charge accumulation by the radiation detector 60 is started in response to the processing of step 224 described later in the electronic cassette 32, and the radiation generator 34. The charge accumulation by the radiation detector 60 is started in advance by the period from the time when the start of the exposure of the radiation X is instructed by the processing of step 226 described later to the time when the exposure is actually started. Then, it is estimated by adding the exposure period input on the initial information input screen to the period from when the radiation X is actually started.

  Next, in step S207, the CPU 104 causes the radiation detector 60 to perform imaging in the same charge accumulation period as the applied charge accumulation period without generating radiation from the radiation generator 34, thereby causing the radiation detector 60 to perform imaging. Offset image update for generating image data (hereinafter referred to as “offset image data”) for correcting image data (hereinafter referred to as “subject image data”) obtained by radiographic image capture by Execute the process.

  FIG. 7 is a flowchart showing a flow of offset image update processing in the imaging system 18 according to the first embodiment. The offset image update processing is executed by the CPU 104 of the console 42, and the offset image update processing program is stored in advance in a predetermined area of the ROM 106.

  In step S <b> 301, the CPU 104 displays instruction information for instructing execution of the photographing execution process in order to acquire an original image used when creating a correction image used for offset correction in the applied charge accumulation period. And information indicating the number of times of photographing (4 times in the present embodiment) are transmitted to the electronic cassette 32 via the wireless communication unit 118. In response to this, the electronic cassette 32 is designated to perform imaging by the radiation detector 60 in the received applied charge accumulation period after performing a reset operation for discharging the charges accumulated in the radiation detector 60 at this time. The image data obtained by the number of times of photographing is transmitted to the console 42 via the wireless communication unit 94.

  In step S303, the CPU 104 determines whether image data has been received from the electronic cassette 32 via the wireless communication unit 118. At this time, the CPU 104 determines that the image data has been received when image data indicating a plurality of images obtained by the number of times of the designated number of times is received.

  If it is determined in step S303 that image data has been received, the CPU 104 generates various noises in the image (image for creating an image for offset correction) for each image indicated by the received image data. It is determined whether or not. In the first embodiment, the CPU 104 determines whether or not each of impact noise, electromagnetic wave noise, and scattered radiation noise is generated for each image.

  The impact noise is noise generated when the portable electronic cassette 32 falls or collides with an object such as an obstacle, and vibration is applied to the electronic cassette 32. The electromagnetic wave noise is noise generated by electromagnetic waves generated from other devices such as a PC (Personal Computer) disposed in the vicinity of the electronic cassette 32. In addition to the radiation generator 34, scattered radiation noise is generated when other radiation generators that generate radiation such as X-rays are arranged in the vicinity of the electronic cassette 32. Noise generated when the scattered radiation enters the electronic cassette 32.

  FIG. 8A is a schematic diagram illustrating an example of an image in which impact noise is generated in the imaging system 18 according to the first embodiment, and FIG. 8B is an electromagnetic wave in the imaging system 18 according to the first embodiment. It is a schematic diagram which shows an example of the image which noise generate | occur | produced. As shown in FIG. 8A, when an impact noise occurs in an image 160 photographed with the electronic cassette 32, a signal processing unit 82 is included in a part of the image 160 (the moment when the impact occurs in the electronic cassette 32). For example, linear noise N is temporarily generated in an area corresponding to the line from which the signal was read. Further, as shown in FIG. 8B, when electromagnetic noise is generated in an image 160 photographed by the electronic cassette 32, linear noise N is temporarily generated in the entire image 160.

  First, in step S305, the CPU 104 determines whether or not impact noise is detected from the received image data.

  FIG. 9 shows the pixel value of each pixel in the difference image between the image captured last time and the image captured this time in the imaging system 18 according to the first embodiment, the horizontal axis indicates the pixel value (QL value), and the vertical axis indicates the pixel value. It is the histogram represented by the number of pixels, (A) is a figure which shows the case where the impact noise has not occurred, and (B) is the figure which shows the case where the impact noise has occurred. The QL value is a value corresponding to the density of the film of the radiation image obtained by irradiating the radiation, and may be a gradation signal itself, or a signal obtained by performing a predetermined process on the gradation signal. It may be. Further, for example, 4000 QL is added to the pixel value of each pixel in the difference image to raise the pixel value in the entire image.

  As shown in FIG. 9A, when no impact noise is generated in the image captured by the electronic cassette 32, the pixel value in the difference image (that is, between the image captured last time and the image captured this time). The histogram of the difference between the pixel values of the corresponding pixels shows a normal distribution. On the other hand, as shown in FIG. 9B, when the impact noise is generated in the image captured by the electronic cassette 32, the impact noise shown in FIG. Corresponding noise is generated. This is because the pixel of each pixel in the difference image in the pixel area corresponding to the portion where the impact noise is generated when the impact noise is generated in either the image captured last time or the image captured this time. This is because the value increases.

  FIG. 10 is a schematic diagram for explaining impact noise detection processing in the imaging system 18 according to the first embodiment. As illustrated in FIG. 10, the CPU 104 generates a difference image between a first image and a second image among a plurality of images (four in the present embodiment). Note that the pixel value of each pixel in the difference image is raised by adding, for example, 4000 QL. Then, the CPU 104 performs an average reduction process on the generated difference image. In the average reduction process, a pixel area of a predetermined size (in this embodiment, a rectangular pixel area in the main direction 2 × sub-direction 2) is set to one pixel using the average value of the pixel values of the pixel area as a pixel value. It is processing. If the average reduction process is not necessary, the average reduction process may be omitted.

  Further, the CPU 104 performs a median filter process on the reduced image that has been subjected to the average reduction process (the difference image when the average reduction process is not performed). In the median filter processing, the pixel values located in the center when the pixel values for each pixel in a pixel area of a predetermined size (in this embodiment, a rectangular pixel area in the main direction 5 × sub-direction 5) are arranged in ascending order. This is processing for setting the pixel value of the center pixel of the pixel area. By this median filter processing, point-like noise due to pixel defects or the like can be removed from the average reduced image.

  Further, the CPU 104 determines, for each pixel, whether or not the difference between the pixel value and the reference value (QL value 4000) is equal to or more than a predetermined first threshold for the median image that has undergone the median filtering process. The total number of pixels that are greater than or equal to the first threshold is counted. The first threshold value is preferably set to an upper limit value that can be regarded as random noise in the histogram shown in FIG. In addition, a pixel having a pixel value equal to or greater than the first threshold has a large absolute value of a difference between pixel values of corresponding pixels between the first image and the second image, and there is a possibility that impact noise is generated. Is a pixel.

  When the total number of pixels that are equal to or greater than the first threshold is equal to or greater than a predetermined second threshold, the CPU 104 determines that impact noise has occurred in the first image or the second image. The second threshold value may be set to a numerical value indicating an upper limit value at which the total number of pixels equal to or greater than the first threshold value can be regarded as random noise. If it is known that no impact noise has occurred in the first image, it can be determined that impact noise has occurred in the second image.

  If the CPU 104 detects the impact noise in the first image and the second image as a result of performing the impact noise detection process on the first image and the second image, the CPU 104 The impact noise detection process is performed on the difference image between the second image and the third image. Similarly, when the impact noise is not detected in the third image, the impact noise detection process is performed on the difference image, the difference image of the third image, and the fourth image. At this time, if impact noise is detected in any of the first to fourth images at any stage, it is determined that the impact noise has been detected, and the impact noise detection process is stopped. . In this way, by generating a differential image of a plurality of other images in which no impact noise has been detected, and generating a differential image between this differential image and the image to be detected, errors due to random noise can be reduced. Can do.

  In the first embodiment, the difference image is used in the impact noise detection process. However, the present invention is not limited to this, and an average image may be used instead of the difference image in the impact noise detection process. That is, the impact noise detection processing is performed for the first image and the second image, and the impact noise detection processing is performed for the average image of the first image and the second image and the third image. The impact noise detection process may be performed on the average image and the fourth image of the first image to the third image.

  In the first embodiment, in the impact noise detection process, a difference image between the first image and the second image is generated by using the first image and the second image as detection target images. However, the present invention is not limited to this, and a difference image or an average image between an image already stored in the RAM 108 as an offset correction image and each of the first to fourth images is generated. Also good.

  If it is determined in step S305 that no impact noise has been detected, in step S307, the CPU 104 determines whether electromagnetic wave noise has been detected from the received image data.

  FIG. 11A shows the pixel value of each pixel in the difference image between the image captured last time and the image captured this time in the imaging system 18 according to the first embodiment, the horizontal axis indicates the pixel value (QL value), 11 is a histogram in which the vertical axis represents the number of pixels, and FIG. 11B shows the graph of FIG. 11A with the scale changed. Note that, for example, 4000 QL is added to the pixel value of each pixel in the difference image to raise the pixel value in the entire image.

  As shown in FIGS. 11A and 11B, when no electromagnetic wave noise is generated in an image captured by the electronic cassette 32, the histogram of pixel value difference shows a normal distribution having a sharp peak. On the other hand, when electromagnetic wave noise is generated in an image taken with the electronic cassette 32, the electromagnetic wave noise is noise generated in the entire image as described above. Unlike the case where it does not occur, the peak width becomes wider and the peak height becomes lower. This is because when there is no electromagnetic wave noise in the image taken last time and electromagnetic noise is generated in the image taken this time, between the image taken last time and the image taken this time in the entire image. This is because the difference between the pixel values of the corresponding pixels increases, that is, the pixel value of each pixel in the difference image increases.

  FIG. 12 is a schematic diagram for explaining electromagnetic wave noise detection processing in the imaging system 18 according to the first embodiment. As shown in FIG. 12, the CPU 104 generates a difference image between the previous image for offset correction (an image already stored in the RAM 108 as an image for offset correction) and the first image. Note that the pixel value of each pixel in the difference image is raised by adding 4000 QL, for example. The first image to the fourth image are subjected to the above-described average reduction process and median filter process.

  Further, the CPU 104 generates a histogram in which the horizontal axis represents the pixel value difference (QL value) and the vertical axis represents the number of pixels for the generated difference image, and derives the extent of the peak width in the histogram. Then, the CPU 104 determines whether or not the peak width is greater than or equal to a predetermined third threshold value. The third threshold value may be set to a numerical value indicating an upper limit value at which the peak width can be regarded as random noise. The CPU 104 considers that the peak width in the histogram becomes wide when electromagnetic noise is generated in the image captured this time, and if the peak width is equal to or greater than the third threshold, It is determined that electromagnetic noise is generated.

  The CPU 104 performs the electromagnetic wave noise detection process described above for the first image to the fourth image, and determines that the electromagnetic wave noise has been detected when the electromagnetic wave noise is detected in any of the images.

  If there is no image already stored in the RAM 108 as an offset correction image, a difference image is generated for each of the first to fourth images in the electromagnetic wave noise detection process described above. Good. When electromagnetic noise is generated in any one of the first image to the fourth image, it is possible to make use of the fact that the spread of the histogram is different from the other images. It can be determined that electromagnetic noise has occurred in images having different spreads with respect to the images.

  In the first embodiment, when determining whether or not electromagnetic noise is occurring, the determination is based on whether or not the peak width in the histogram is equal to or greater than a third threshold. The peak half-width is not less than the predetermined value, the peak height is not more than the predetermined value, and the ratio of the peak height to the peak half-width is not less than the predetermined value. The determination can be made based on whether or not there is any.

  If it is determined in step S307 that no electromagnetic wave noise has been detected, in step S309, the CPU 104 determines whether scattered radiation noise has been detected from the received image data. Here, when scattered rays such as X-rays enter the electronic cassette 32, the CPU 104 uses the fact that the pixel density in the incident pixel region is greatly different from the pixel density in the non-incident pixel region. The presence / absence of scattered radiation noise is determined by detecting the presence / absence of regions having greatly different densities. Note that the first image to the fourth image are subjected to the above-described average reduction process and median filter process.

  FIG. 13 is a diagram illustrating an example of the detection target region 160a in the imaging system 18 according to the first embodiment. As shown in FIG. 13, in each of the first image to the fourth image 160, a plurality of pixel areas (in this embodiment, nine positions) having a predetermined size at predetermined positions. Is preset as the detection target area 160a.

  The CPU 104 derives an average value of pixel values in each of the plurality of detection target areas 160a for each of the first image to the fourth image 160, and the derived average value is determined in advance. It is determined whether or not the fourth threshold is exceeded. The fourth threshold value may be a numerical value of an upper limit value that allows an average value of pixel values of each pixel in the detection target region 160a to be regarded as random noise. In addition, when the average value of the pixel values in any one of the detection target areas 160a is equal to or greater than the fourth threshold, the CPU 104 determines that scattered radiation noise has occurred in the determination target image.

  The CPU 104 determines that the scattered radiation noise is detected when the scattered radiation noise is detected in any one of the first image to the fourth image.

  If it is determined in step S309 that no scattered radiation noise has been detected, in step S311, the CPU 104 generates and generates an average image of the first image to the fourth image as an offset correction image. By storing the offset image in a predetermined area of the RAM 108, the offset correction image is updated.

  If it is determined in step S305 that impact noise has been detected, if it is determined in step S307 that electromagnetic noise has been detected, or if it is determined in step S309 that scattered radiation noise has been detected, in step S313, The CPU 104 does not generate an image for offset correction based on the image data received in step S303 and waits until a predetermined time (in this embodiment, 10 minutes) elapses. Then, the CPU 104 returns to step S301 and repeats the step. The processing from S301 to S313 is performed. The predetermined time may be a time required until the occurrence of various noises described above is stopped.

  On the other hand, when the photographer selects the end button of the initial information input screen in step S203, the electronic cassette 32 is placed on the bed 46 in accordance with the posture of the subject (the standing position or the standing position) input on the initial information input screen. After being held in the holding portion 152 provided, the subject is placed in a recumbent position at the imaging position 50 in the space above the bed 46 or the electronic cassette 32 is held in the holding portion 150 of the rack 45, The subject is placed at the imaging position 48 in the space in front of the rack 45. Next, the photographer operates the support moving mechanism 52 so that the radiation source 130 of the radiation generator 34 is arranged in front of the imaging region.

  In step S209, the CPU 104 sets the explosion condition by transmitting the exposure condition input on the initial information input screen to the radiation generator 34 via the wireless communication unit 118. In response to this, the radiation source control unit 134 prepares for exposure under the received exposure conditions.

  In step S <b> 211, the CPU 104 transmits instruction information for instructing to start execution of an imaging execution process for imaging radiographic images to the electronic cassette 32 via the wireless communication unit 118. In response to this, the electronic cassette 32 starts execution of a photographing execution process described later.

  In step S <b> 213, the CPU 104 transmits instruction information for instructing the start of exposure to the radiation generation apparatus 34 via the wireless communication unit 118. In response to this, the radiation generator 34 generates radiation X from the radiation source 130 at a tube voltage, a tube current, and an exposure period corresponding to the exposure conditions received from the console 42 according to the processing of step S209. And inject. In response to this, the electronic cassette 32 captures a radiographic image by the above-described imaging execution processing, and transmits subject image data obtained thereby to the console 42 via the wireless communication unit 94.

  Therefore, in step S215, the CPU 104 determines whether or not the subject image data has been received from the electronic cassette 32. If it is determined in step S215 that the subject image data has been received, in step S217, the CPU 104 sends the wireless communication unit 118 to the electronic cassette 32 with instruction information for instructing to stop power feeding started in step S205. Send through. In response to this, the electronic cassette 32 controls the power supply unit 96 to stop the power supply.

  In step S219, the CPU 104 performs offset correction by subtracting the image data of the image for offset correction updated in step S207 for each pixel from the received subject image data, Image processing for performing various corrections such as leakage current correction and amplifier offset voltage correction is executed.

  In step S <b> 221, the CPU 104 stores the subject image data subjected to the image processing (hereinafter referred to as “corrected image data”) in the HDD 110. In step S223, the CPU 104 controls the display driver 112 so that the radiation image indicated by the corrected image data is displayed on the display 100 for confirmation or the like. Further, in step S225, the CPU 104 transmits the corrected image data to the RIS server 14 via the in-hospital network 16, and then ends the radiation image capturing processing program. The corrected image data transmitted to the RIS server 14 is stored in the database 14A, so that a doctor can perform radiogram interpretation, diagnosis, and the like.

  As described above in detail, according to the first embodiment, at least one original image obtained when creating a correction image used for offset correction with respect to an image obtained by photographing is acquired, and the original image is acquired. Whether or not external noise is superimposed on the image, and if it is determined that external noise is superimposed on the original image, generation of a correction image using the original image on which noise is superimposed is stopped To do. Thereby, when creating a correction image for offset correction, a correction image on which noise is superimposed can be prevented from being created, and a correction image with less noise can be easily created.

  Note that the processes of steps S303, S305, and S307 are not necessarily performed in the order described above, and may be performed in an arbitrarily switched order. Further, it is not always necessary to execute the processes of steps S303, S305, and S307, and each of the processes of steps S303, S305, and S307 is selectively executed according to the characteristics of the apparatus, the shooting environment, and the like. Anyway.

  Further, during the offset image update process, when an instruction for a main shooting is input by the photographer, the main shooting may be started after the processes of steps S301 to S313 are completed. Alternatively, the offset image update process may be interrupted without updating the offset correction image, and the offset correction image already stored may be used. If there is an image being shot when an instruction for main shooting is input by the photographer while the offset image update processing is being performed, the offset image is updated when shooting of the image is completed. It is better to interrupt the process.

  The imaging system 18 according to the first embodiment creates an image for offset using a plurality of images obtained by a plurality of times of imaging in the offset image update processing, but is not limited to this. An offset image may be created by using one image obtained by the shooting of one time. In this case, when performing the impact noise detection process in step S305, it is preferable to use an image for offset correction already stored in the RAM 108 and one image obtained by photographing.

  In addition, the imaging system 18 according to the first embodiment performs the offset image update process immediately before performing the main imaging with the electronic cassette 32, but the timing for performing the offset image update process is not limited to this, and is performed at an arbitrary timing. be able to.

  In addition, the imaging system 18 according to the first embodiment performs offset image update processing on the electronic cassette 32 that captures a radiographic image, but is not limited thereto, and is offset relative to an imaging apparatus that captures images with a solid-state imaging device. Image update processing may be performed. In this case, the CPU 104 acquires, as an original image, an image captured by the solid-state image sensor in the absence of incident light.

[Second Embodiment]
Hereinafter, the radiographic imaging system 10 according to the second exemplary embodiment will be described in detail with reference to the accompanying drawings. The radiographic image capturing system 10 according to the second embodiment has a configuration as illustrated in FIGS. 1 to 4, similarly to the image capturing system 10 according to the first embodiment. In addition, the same code | symbol is attached | subjected to the structure same as 1st Embodiment, and the overlapping description is abbreviate | omitted.

  The imaging system 18 according to the first embodiment, when updating an image for offset correction, if noise occurs in any of the four images, the offset correction using the four images. However, when the image capturing system 18 according to the second embodiment generates noise in any of the four images, only the image that is not affected by the noise is displayed. Use to generate and update an image for offset correction.

  A flow of imaging control processing in the imaging system 18 according to the second embodiment will be described.

  First, the CPU 104 performs steps S201 to S205 in the same manner as in the first embodiment. In step S207, the CPU 104 performs an offset image update process.

  FIG. 14 is a flowchart showing a flow of offset image update processing in the imaging system 18 according to the second embodiment. The offset image update processing is executed by the CPU 104 of the console 42, and the offset image update processing program is stored in advance in a predetermined area of the ROM 106.

  In steps S401 through S403, the CPU 104 performs the same processing as in steps S301 through S303. In step S404, the CPU 104 selects an image that is the detection target of the above-described various noises from the image indicated by the received image data in step S403. In steps S405 to S409, the CPU 104 performs the same processing as in steps S305 to S309 on the image that is the detection target in step 404. If it is determined in step S409 that no scattered radiation noise has been detected, in step S411, the CPU 104 sets the image to be detected in steps S405 to S409 as an image used for generating an offset correction image. .

  Note that the CPU 104 uses the offset correction image already stored in the RAM 108 and one image obtained by photographing when performing the impact noise detection process in step S405.

  On the other hand, if it is determined in step S405 that impact noise has been detected, if it is determined in step S407 that electromagnetic noise has been detected, or if it is determined in step S409 that scattered radiation noise has been detected, in step S413, The CPU 104 sets the image to be detected in steps S405 to S409 as an image that is not used for generating an offset correction image.

  In step S415, the CPU 104 determines whether there is unprocessed image data, that is, an image that has not been subjected to the processing in steps S405 to S413. If it is determined in step S415 that there is unprocessed image data, the process returns to step S405, and the processes of steps S405 to 413 are performed on the image indicated by the unprocessed image data.

  If it is determined in step S415 that there is no unprocessed image data, in step S417, the CPU 104 is used to generate an image for offset correction in step S411, that is, an image for offset correction in step S411. It is determined whether there is an image as an image.

  If it is determined in step S415 that there is an image to be used for generating an image for offset correction, in step S419, the CPU 104 determines an average image of the images to be used for generating an image for offset correction in step S411. By storing the offset correction image in a predetermined area of the RAM 108, the offset correction image is updated. On the other hand, if it is determined in step S415 that there is no image to be used for generating an image for offset correction, the image for offset correction is not updated.

  Then, as in the first embodiment, the CPU 104 performs the processes of steps S209 to S225 and ends the shooting control processing program.

  As described above in detail, according to the second embodiment, a correction image is created using an original image determined that external noise is not superimposed. Thereby, when creating a correction image for offset correction, a correction image on which noise is superimposed can be prevented from being created, and a correction image with less noise can be easily created.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above-described embodiment without departing from the gist of the invention, and embodiments to which such modifications or improvements are added are also included in the technical scope of the present invention.

10 RIS
18 Radiation Imaging System 32 Electronic Cassette 34 Radiation Generator 42 Console 60 Radiation Detector 82 Signal Processing Unit 82A Amplifier 92 Cassette Control Unit 92A CPU
92B Memory 92C Storage unit 94 Wireless communication unit 96 Power supply unit 100 Display 102 Operation panel 104 CPU
106 ROM
118 Wireless communication unit 130 Radiation source

Claims (11)

An acquisition means for acquiring at least one original image when creating a correction image used for offset correction for an image obtained by shooting;
Determining means for determining whether or not noise from the outside that is at least one of noise caused by scattered radiation of radiation, noise caused by impact, and noise caused by electromagnetic waves is superimposed on the original image;
Creating means for creating the correction image using only the original image determined by the determining means that noise from the outside is not superimposed;
An image creating apparatus for correction. The acquisition means irradiates the subject with radiation from the radiation generation source, and detects the radiation transmitted through the subject with a detector, thereby causing the imaging device to capture a radiographic image of the subject to detect the radiation from the radiation generation source to the subject. The correction image creating apparatus according to claim 1, wherein a radiographic image captured in a state where no radiation is irradiated is acquired as the original image. The correction image creating apparatus according to claim 1, wherein the acquisition unit acquires an image captured by a solid-state imaging device in the absence of incident light as the original image. The determination unit determines whether or not noise due to scattered radiation of radiation is superimposed by comparing each of average values of pixel values in a plurality of regions in the original image with a predetermined threshold value. 4. The correction image creation apparatus according to any one of 1 to 3. The determination means does not superimpose a difference between pixel values of corresponding pixels between an image for offset correction that has already been created and the original image, a difference between pixel values of corresponding pixels between the original images, and noise. Difference between pixel values of corresponding pixels between a difference image obtained from a plurality of original images and the original image, or difference between pixel values of corresponding pixels between an average image of a plurality of original images on which noise is not superimposed and the original image And determining whether or not noise due to an impact is superimposed based on the number of pixels in a difference separated from a reference value of a histogram expressed by the number of pixels with respect to the difference. Correction image creation device. The determining means determines whether the histogram represented by the difference between the pixel values of the corresponding pixels of the offset correction image and the original image that have already been created and the number of pixels corresponding to the difference is widened. 6. The correction image creating apparatus according to claim 1, wherein it is determined whether or not noise due to is superimposed. The correction image creating apparatus according to claim 1, wherein the determination unit uses, as the original image, an image obtained by removing noise due to defective pixels by a median filter in the original image. A correction image creating apparatus according to claim 2;
An imaging device for capturing a radiation image of the subject by irradiating the subject with radiation from a radiation source and detecting the radiation transmitted through the subject with a detector;
A radiographic imaging apparatus comprising: A correction image creating apparatus according to claim 3;
An imaging device having a solid-state imaging device;
An imaging device with   A program for causing a computer to function as the correction image creating apparatus according to any one of claims 1 to 7. An acquisition step of acquiring at least one original image when creating a correction image used for offset correction for an image obtained by shooting;
A determination step of determining whether or not noise from the outside, which is at least one of noise due to scattered radiation of radiation, noise due to impact, and noise due to electromagnetic waves, is superimposed on the original image;
A creation step of creating the correction image using only the original image determined to have no external noise superimposed by the determination step;
A correction image creation method comprising:

Images