JP2012148055A - Photographic image displaying appratus and photographic image displaying method - Google Patents

Abstract

In displaying a captured image display, it is possible to easily recognize whether a captured image displayed to an observer is a captured image that has been two-dimensionally or three-dimensionally captured.
The photographed image data GD of a subject and the photographed image data GD are photographed image data GD obtained by two-dimensionally photographing the subject, or photographed image data GD obtained by photographing three-dimensionally. The photographed image data GD and the supplementary data FD are read from the image file GF having the supplementary data FD indicating a certain data attribute DP, and the photographed image G of the subject is displayed using the photographed image data GD. Each data attribute DP is displayed using the data FD.
[Selection] Figure 4

Description

  The present invention relates to a captured image display device and a captured image display method for reading captured image data from an image file and displaying the captured image. More specifically, the present invention relates to a captured image display device and a captured image display method for reading captured image data captured two-dimensionally or three-dimensionally from an image file and displaying the captured image.

  Conventionally, as a display of a captured image using captured image data, a captured image is displayed in a planar manner when the image file includes only captured image data captured from one imaging direction (hereinafter referred to as two-dimensional imaging). There is known a three-dimensional display in which a two-dimensional display and a three-dimensional display of a photographed image are provided when two photographed image data are taken from two different photographing directions (hereinafter referred to as three-dimensional photography). Yes.

  For this reason, when the captured images are sequentially displayed using the captured image data, it is necessary to recognize and display whether the captured image is taken two-dimensionally or three-dimensionally. Patent Document 1 proposes a captured image display device capable of switching between two-dimensional display and three-dimensional display manually or automatically.

JP 2003-18619 A

  However, when a plurality of photographed image data obtained by two-dimensional photographing or three-dimensional photographing is used to display a mixture of photographed images, the photographed image display device can perform only two-dimensional display or two-dimensional display. Alternatively, in a photographic image display device capable of switching between three-dimensional displays, when it is desired to compare the three-dimensional photographic images for each photographing direction, or when the user is tired from observing the three-dimensional display, the three-dimensional photographic images are taken. Even so, it may be set to two-dimensional display.

  Therefore, while displaying the captured image on the captured image display device capable of only two-dimensional display, the observer is photographed in any photographing direction even though the displayed photographed image is a three-dimensional photographed image. There is a risk of observing the image without being conscious of it, or while displaying a photographed image on a photographed image display device capable of switching between two-dimensional display and three-dimensional display, after setting to two-dimensional display, again There is a risk that the user forgets to switch to the three-dimensional display and observes a new three-dimensionally photographed image without realizing that the photographed image can be viewed stereoscopically.

  In view of the above circumstances, an object of the present invention is to provide a captured image display device and a captured image display method that allow an observer to easily recognize whether a displayed captured image is a captured image that has been two-dimensionally or three-dimensionally captured. To do.

  In order to solve the above-described problem, a captured image display device according to the present invention includes captured image data of a subject and captured image data obtained by two-dimensionally capturing the captured image data attached to the captured image data. A data reading unit for reading captured image data and incidental data from an image file including additional data indicating data attributes indicating whether the image data is captured image data obtained by three-dimensional imaging, or captured image data And a display unit for displaying a data attribute using supplementary data.

  In the photographed image display device according to the present invention, the display unit may display the data attribute as character information, and can perform both two-dimensional display and three-dimensional display of the photographed image of the subject. There may be. In the captured image display device according to the present invention, the captured image may be a radiographic image and the subject may be a breast.

  The photographed image display method according to the present invention includes photographed image data of a subject, and the photographed image data is photographed image data obtained by two-dimensionally photographing a subject, or photographed image data obtained by three-dimensional photographing. The captured image data and the incidental data are read out from the image file including the incidental data indicating whether or not the data attribute is present, and the captured image of the subject is displayed using the captured image data, and the data attribute is determined using the incidental data. Are displayed respectively.

  According to the photographed image display device and the photographed image display device of the present invention, the photographed image data of the subject and the photographed image data are photographed image data obtained by photographing the subject two-dimensionally, or three-dimensionally photographed. The captured image data and the incidental data are respectively read from the image file including the additional data indicating the data attribute indicating whether the captured image data is obtained, and the captured image of the subject is displayed using the captured image data. Since each data attribute is displayed using incidental data, the observer can easily recognize whether the displayed captured image is taken two-dimensionally or three-dimensionally by checking the displayed data attribute. it can. That is, the observer can easily recognize whether the displayed radiation image should be viewed in plan or whether it should be viewed stereoscopically but not stereoscopically viewed.

Schematic configuration diagram of radiation imaging system Schematic configuration diagram of radiation imaging equipment Partial front view of radiation imaging equipment Schematic configuration diagram of the captured image display device The figure which shows the display of the monitor which can only display 2D The figure which shows the display of the monitor which can display 3D Flow chart showing processing of photographed image display device

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram of a breast radiation imaging system 1 using a captured image display device 4 according to an embodiment of the present invention. The radiation imaging system 1 includes a plurality of radiation imaging apparatuses 2 that capture a radiation image G of the breast M, an image server 3, and a plurality of captured image display apparatuses 4 that display the radiation image G of the breast M. Each radiation imaging apparatus 2, image server 3, and each captured image display apparatus 4 are connected to each other via a network 5.

  In the radiation imaging system 1, each radiation imaging apparatus 2 performs radiation imaging of the breast M, stores captured image data GD of the captured radiation image G in an image file GF, and transmits the image file GF to the image server 3. The image server 3 stores the image file GF and transmits the image file GF to the photographic image display device 4 that requested the distribution via the network 5 in response to a distribution request from the photographic image display device 4. The captured image data GD is read from the image file GF received by the captured image display device 4 and the radiation image G of the breast M is displayed.

  First, the radiation imaging apparatus 2 will be described. The radiation imaging apparatus 2 acquires a radiation image G by performing two-dimensional imaging or three-dimensional imaging of the breast M, stores captured image data GD of the radiation image G, and transmits an image file GF to the image server 3. is there.

  2 is a schematic configuration diagram of the radiation imaging apparatus 2, and FIG. 3 is a partial front view of the radiation imaging apparatus 2. As shown in FIG. 1, the radiation imaging apparatus 2 includes a base 21, a base that is movable in the vertical direction (Z direction) with respect to the base 21, and can be rotated by a rotary shaft 22 and a rotary shaft 22. The arm part 23 connected with 21 is provided.

  The arm portion 23 has a C shape, and a radiation table 26 is attached to one end of the arm portion 23 so as to face the imaging table 24 at the other end. The rotation and vertical movement of the arm unit 23 are controlled by an arm controller 31 incorporated in the base 21.

  A radiation detector 25 such as a flat panel detector and a detector controller 33 that controls reading of a charge signal from the radiation detector 25 are provided inside the imaging table 24. The imaging table 24 includes a charge amplifier that converts the charge signal read from the radiation detector 25 into a voltage signal, a correlated double sampling circuit that samples the voltage signal output from the charge amplifier, and a voltage signal. A circuit board or the like provided with an A / D conversion unit for converting into a digital signal is provided.

  As shown in FIG. 2, the arm portion 23 is supported by the base 21 so as to be rotatable around the rotation shaft 22. In the two-dimensional imaging, when the arm unit 23 rotates, the imaging table 24 rotates in the same manner. In the three-dimensional imaging, even if the arm unit 23 rotates, the orientation of the imaging table 24 is set as the base. 21 can be fixed.

  The radiation detector 25 can perform recording and reading of charge signals repeatedly, and may use a so-called direct type radiation detector that directly receives radiation and generates charges. May be used as a so-called indirect radiation detector that once desensitizes the visible light and converts the visible light into an electrical signal.

  Further, as a charge signal reading method, it is desirable to use a so-called TFT reading method in which a charge signal is read by turning on and off a TFT (thin film transistor) switch. May be used.

  A radiation source 27 and a radiation source controller 32 are stored inside the radiation irradiation unit 26. The radiation source controller 32 controls the timing of irradiating radiation from the radiation source 27 and the radiation generation conditions (tube current (mA), irradiation time (ms), tube voltage (kV), etc.) in the radiation source 27. .

  Further, in the central portion of the arm portion 23, a compression plate 28 that is arranged in the information on the imaging table 24 and presses the breast M to press it, a support portion 30 that supports the compression plate 28, and a support portion 30 in the vertical direction. A moving mechanism 29 for moving in the (Z direction) is provided. The position and compression thickness of the compression plate 28 are controlled by the compression plate controller 34.

  The control unit 35 includes a central processing unit (CPU), a storage device such as a semiconductor memory, a hard disk, and an SSD, and an input unit 36. The control unit 35 outputs predetermined control signals to the various controllers 31 to 34 to perform overall control of the radiation imaging apparatus 2.

  The input unit 36 is configured by a pointing device such as a keyboard and a mouse, for example. The input unit 36 uses patient information, an imaging method for 2D imaging or 3D imaging, an imaging type such as CC (head-to-tail direction) and MLO (inside / outside oblique direction), and 3D imaging. As shown in FIG. 6, an input such as an imaging angle θ, which is an angle formed between a direction connecting the radiation source 27 and the center of the detection surface 25a and a direction perpendicular to the detection surface 25a, is received. In the present embodiment, as shown in FIG. 3, the photographing angle θ is clockwise as a positive direction and counterclockwise as a negative direction.

  The control unit 35 stores captured image data GD of a radiation image G based on a radiation image signal obtained by performing predetermined signal processing on a charge signal detected by the radiation detector 25 by two-dimensional imaging or three-dimensional imaging, and an image file. The captured image data GD and the captured image data GD are attached to the GF, and a data attribute DP indicating whether the captured image data GD is obtained by two-dimensional photography or three-dimensional photography is shown. The incidental data FD is stored in the image file GF and transmitted to the image server 3.

  The data attribute DP is not limited to the imaging type of 2D imaging or 3D imaging, and may include patient information, imaging conditions, and image information. Here, the imaging conditions are radiation generation conditions, radiation dose, that is, tube current product (mAs), imaging angle θ, and preceding and subsequent information of imaging in each of the captured image data constituting the captured image data GD, The image information is information regarding the resolution and contrast of the radiation image G calculated by the control unit 35 based on the captured image data GD. The information on the resolution and contrast may be the calculated resolution and contrast values, or for the radiographic image G taken in a three-dimensional manner, information that compares the levels of the radiographic images. Good.

  The operation of the radiation imaging apparatus 2 will be described. In the two-dimensional imaging and the three-dimensional imaging, the breast M is placed on the imaging table 24, and the breast M is compressed with a predetermined pressure by the compression plate 28. When the input unit 36 receives an input to start shooting, two-dimensional shooting or three-dimensional shooting starts. The control unit 35 reads the input photographing method and photographing type, and outputs information on the photographing method and photographing type to the arm controller 31. In the present embodiment, it is assumed that CC (head-to-tail direction) is input as a photographing type in two-dimensional photographing and three-dimensional photographing, but is not particularly limited.

  First, two-dimensional imaging by the radiation imaging apparatus 2 will be described. The control unit 35 receives information on two-dimensional imaging in the CC (head-to-tail direction), and the arm controller 31 outputs a control signal such that the arm unit 23 is substantially vertical to the arm unit 23.

  Then, in a state where the arm unit 23 is substantially vertical, the control unit 35 reads the radiation image and the captured image data GD obtained by the two-dimensional imaging with respect to the radiation source controller 32 and the detector controller 33. Output a control signal.

  In response to this control signal, the radiation source 27 emits radiation, the radiation detector 25 detects the emitted radiation, and the detector controller 33 reads the charge signal from the radiation detector 25. Based on the radiographic image signal obtained by subjecting the charge signal to predetermined signal processing, the control unit 35 stores the captured image data GD of the breast M, and the captured image data GD and the captured image data GD are obtained by two-dimensional imaging. The data attribute DP of “added” is attached to the photographed image data GD, stored in the image file GF, and transmitted to the image server 3.

  Next, three-dimensional imaging by the radiation imaging apparatus 2 will be described. The control unit 35 receives information on three-dimensional imaging in the CC (head-to-tail direction), reads two different combinations of imaging angles θ, and outputs information about one imaging angle θ to the arm controller 31. In this embodiment, it is assumed that θ = ± 2 ° is input as the imaging angle θ, but even when θ = 0 ° and θ = + 4 °, or θ = 0 ° and θ = −4 °. Good, not particularly limited.

  The control unit 35 receives information on the shooting angle θ = ± 2 °, and the arm controller 31 outputs a control signal for tilting the arm unit 23 so that the shooting angle θ is + 2 °. When the arm unit 23 is tilted and the imaging angle θ becomes + 2 °, the control unit 35 outputs a control signal for performing radiation irradiation and reading of the captured image data GD for the right eye to the radiation source controller 32 and the detector controller 33. To do.

  In response to this control signal, the radiation source 27 emits radiation, the radiation detector 25 detects the emitted radiation, and the detector controller 33 reads the charge signal from the radiation detector 25. Based on the radiation image signal obtained by subjecting the charge signal to predetermined signal processing, the control unit 35 stores captured image data GD for the right eye of the breast M.

  Next, the arm controller 31 outputs a control signal for tilting the arm unit 23 so that the photographing angle becomes −2 °. When the arm unit 23 is tilted and the imaging angle θ becomes −2 °, the control unit 35 sends a control signal for performing radiation irradiation and reading of the captured image data GD for the left eye to the radiation source controller 32 and the detector controller 33. Output.

  In response to this control signal, the radiation source 27 emits radiation, the radiation detector 25 detects the emitted radiation, and the detector controller 33 reads the charge signal from the radiation detector 25. Based on the radiation image signal obtained by subjecting the charge signal to predetermined signal processing, the control unit 35 stores captured image data GD for the left eye of the breast M.

  The control unit 35 attaches to the captured image data GD the captured image data GD for the right eye and the left eye of the breast M and the data attribute DP that each captured image data GD has been obtained by three-dimensional imaging. And transmitted to the image server 3.

  The image server 3 will be described again with reference to FIG. The image server 3 includes a recording medium 3A composed of a hard disk or the like and a server side computer 3B. The recording medium 3 </ b> A stores the image file GF transmitted from the radiation imaging apparatus 2, and when the server-side computer 3 </ b> B receives a distribution request from the captured image display apparatus 4 via the network 5, the image file via the network 5 is stored. The GF is transmitted to the captured image display device 4.

The captured image display device 4 will be described. FIG. 4 is a schematic configuration diagram of the captured image display device 4.
The captured image display device 4 includes a client-side computer 40 and a monitor 41 that displays data attributes DP of the radiation image G and the captured image data GD. A program for causing the client-side computer 40 to function as the captured image display device according to the present embodiment is installed.

  The client-side computer 40 includes a central processing unit (CPU) and a storage device such as a semiconductor memory, a hard disk, and an SSD. The control unit 42, the data reading unit 43, the image processing unit 44, and the display are provided by these hardware. The control unit 45 is configured. Further, the client computer 40 includes an input unit 40A.

  The input unit 40A includes a keyboard and the like, and includes the number of display screens of the monitor 41, the number of radiation images G on each display screen, the display position and the display direction, and the display position and display of a data attribute DP described later. The method and setting of whether to display the radiation image G in two dimensions or in three dimensions are input.

  The control unit 42 communicates with the image server 3 via the network 5 and controls the entire client computer 40. The data reading unit 43 reads the captured image data GD and the incidental data FD attached to the captured image data GD from the image file GF distributed via the network 5.

  The image processing unit 44 performs image processing so that the radiation image G can be displayed on the monitor 41 in the display position and display direction set by the input unit 40A. The display control unit 45 controls the monitor 41 so as to display the radiation image G in a two-dimensional display or a three-dimensional display based on the captured image data GD. The display control unit 45 also controls the monitor 41 so as to display the data attribute DP based on the incidental data FD.

  As described above, a plurality of captured image display devices 4 are connected to the radiation imaging system 1 via the network 5, and each captured image display device 4 can be a monitor capable of only two-dimensional display or three-dimensional display. There is a good monitor.

  First, the monitor 41 capable of only two-dimensional display will be described. FIG. 5 is a diagram showing the display of the monitor 41 capable of only two-dimensional display. As shown in FIG. 5, the monitor 41 includes one display screen 46. The upper diagram of FIG. 5 illustrates a two-dimensional display of a radiographic image G that has been two-dimensionally photographed, and the lower diagram of FIG.

  In the present embodiment, as shown in FIG. 5, in the input unit 40 </ b> A, the number of display screens is 1, and the chest wall MW is substantially horizontal and upward in the display screen 46 at a substantially central position for each radiographic image G. It is assumed that the two-dimensional display of the orientation is set. In addition, when two-dimensionally displaying a three-dimensional radiographic image G, it is assumed that the left-eye radiographic image G is set to be two-dimensionally displayed with the above contents.

  In the present embodiment, the data attribute DP is set to be displayed as a character at a position on the upper right side of the display screen 46, but the display position is not limited. Further, as shown in FIG. 5, the data attribute DP may be displayed outside the display area of the radiation image G on the display screen 46 or may be displayed within the display area of the radiation image G. The display position of the data attribute DP may be arbitrarily moved by operating the input unit 40A. Specifically, the data attribute DP is displayed as 2D if the radiation image G is two-dimensionally imaged, and is displayed as 3D if the radiation image G is three-dimensionally imaged, but the mark is not limited. The data attribute DP is not limited to character display, and can be displayed with an icon or the like.

  Further, the data attribute DP may be displayed in a blinking manner to attract the viewer's attention, and may be displayed in different colors according to the data attribute DP as long as the monitor 41 can perform color display. Further, if the captured image display device 4 has an audio output means, audio may be output together with the display of the data attribute DP, and the content of the audio may be content according to the data attribute DP. Good.

  Further, the blinking display, the color-coded display, and the display with sound may be performed only when the radiation image G taken in three dimensions is displayed on the monitor 41 capable of only two-dimensional display.

  When an instruction indicating that the radiation image G on which the input unit 40A is displayed is confirmed to be a three-dimensional image is received, the blinking display is turned on, the color-coded display is the same color display, and the voice is displayed. The data attribute DP itself may be canceled or canceled. The instruction of the input unit 40A may be received by pressing a specific key such as a keyboard, and is received by clicking a specific position on the display screen 46, for example, a display portion of the data attribute DP with a mouse. It may be.

  In the present embodiment, only the imaging type indicating whether the data attribute DP was captured by 2D imaging or 3D imaging is displayed. However, the present invention is not limited to this, and the displayed radiation image is displayed. Information related to the G imaging angle θ, radiation dose, resolution, or contrast may be further displayed. In the case of three-dimensional imaging, the thumbnail image of the other radiographic image that is not displayed may be displayed, or the imaging angle of the other radiographic image that is not displayed, the resolution of the image, and the like may be further displayed. .

  Thus, based on the displayed radiographic image G as shown in FIG. 5, it is possible to recognize whether the radiographic image G being displayed by the observer is taken two-dimensionally or three-dimensionally. Although difficult, it can be easily recognized by checking the data attribute DP on the display screen 46.

  Thereby, when the radiographic image G that has been two-dimensionally or three-dimensionally imaged is displayed on the monitor 41 that can only perform two-dimensional display, even if the radiographic image G that has been three-dimensionally imaged is displayed in two dimensions, It is possible to avoid the possibility of observing without being conscious of in which shooting direction the image was taken.

  Next, the monitor 41 capable of three-dimensional display will be described. FIG. 6 is a diagram showing the display of the monitor 41 capable of three-dimensional display. As shown in FIG. 6, it has the two display screens 47 and 48 adjacent to the up-down direction.

  In the present embodiment, the upper display screen 47 is tilted so that the two display screens 47 and 48 form a predetermined angle, and a detachable half mirror 49 is attached between the two display screens 47 and 48. Then, the display lights on the upper display screen 47 and the lower display screen 48 are polarized perpendicular to each other, the display light on the upper display screen 47 is reflected by the half mirror 49, and the display light on the lower display screen 48 is half. Optically coupled by transmitting through the mirror 49.

  In the present embodiment, when displaying a three-dimensional radiographic image G, the radiographic image G for the right eye is displayed on the upper display screen 47 and the radiographic image G for the left eye is displayed on the lower display screen 48. . The observer wears polarized glasses (not shown) equipped with a polarizing lens on the right side where only the display light of the upper display screen 47 enters, and a lens on the left side where only the display light of the lower display screen 48 enters. Thus, the breast M can be stereoscopically viewed by observing the left-eye and left-eye radiographic images G with the left and right eyes, respectively.

  On the other hand, when displaying the two-dimensional radiographic image G, the same radiographic image G is displayed on both the upper display screen 47 and the lower display screen 48. The observer wears the polarizing glasses described above, so that the radiation image G displayed on the upper display screen 47 is the radiation image G for the right eye and the radiation image G displayed on the lower display screen 48 is for the left eye. The radiation image G is observed in plan view.

  By displaying the same image on the two upper and lower display screens 47 and 48 in this way, the display light of the radiation image G is incident on both sides of the observer even with the polarized glasses attached. The radiographic image G taken two-dimensionally without any sense of incongruity can be observed in a planar view even if an apparatus for observing the image in stereoscopic view is used.

  In the present embodiment, in the input unit 40A, as shown in FIG. 6, the number of display screens is two, and the chest wall MW is positioned at a substantially central position for each of the radiation images G in the two display screens 47 and 48. It is assumed that the setting is horizontal and matches the chest wall MW. The data attribute DP is set to be displayed as a character at the lower right and upper right positions of the two display screens 47 and 48, but the display on the monitor 41 capable of only two-dimensional display. Similarly, the display position and the mark are not limited.

  Also, in the display on the monitor 41 capable of three-dimensional display, the data attribute DP is displayed in a blinking display, a color-coded display, and a color display in the same manner as the display on the monitor 41 capable of only two-dimensional display in order to attract the viewer's attention. It may be displayed with sound. Further, these blinking display, color-coded display, and display with sound may be performed only when the two-dimensional radiographic image G is displayed on the monitor 41 capable of three-dimensional display. Further, upon receiving an instruction confirming that the displayed radiographic image G has been two-dimensionally photographed, the above blinking display is lit, the color-coded display is the same color display, the audio is stopped, or The data attribute DP itself may be hidden.

  In this way, based on the radiographic image G as shown in FIG. 6, whether the radiographic image G being displayed by the observer can be viewed in plan or should be stereoscopically viewed but not stereoscopically viewed. It is difficult to recognize whether the data attribute DP is present, but it can be easily recognized by checking the data attributes DP on the two display screens 47 and 48.

  Accordingly, when the two-dimensional imaging or the three-dimensional radiographic image G is displayed on the monitor 41 capable of three-dimensional display, the three-dimensional radiographic image G is not noticed as being stereoscopically viewable. Can be avoided.

  The operation of the captured image display device 4 will be described. The control unit 42 makes a distribution request for the image file GF to the image server 3 via the network 5 (ST1). The control unit 42 receives the image file GF via the network 5, and the data reading unit 43 reads the captured image data GD and the incidental data FD attached to the captured image data GD stored in the image file GF (ST2). .

  The control unit 42 confirms whether the monitor 41 can display three-dimensionally (ST3). When the monitor 41 is a monitor capable of three-dimensional display, the image processing unit 44 performs image processing so that the chest wall MW of the radiation image G is horizontal and is aligned with the chest wall (ST4). When the monitor 41 can only perform two-dimensional display, the image processing unit 44 performs image processing so that the chest wall MW of the radiographic image G faces upward (ST5). The display control unit 45 displays the data attribute DP based on the radiographic image G subjected to the image processing and the incidental data FD under the conditions set by the input unit 40A (ST6), and ends the processing.

  As described above, according to the captured image display device 4 according to the embodiment of the present invention, the data reading unit 43 reads the captured image data GD and the auxiliary data FD from the image file GF, and the display control unit 45 captures the image. Since the data attribute DP is displayed on the monitor 41 using the radiographic image G of the breast M and the accompanying data FD using the image data GD, is the observer displayed and the radiographic image G is taken two-dimensionally? It can be easily recognized whether the image is taken three-dimensionally. As a result, the observer can easily notice that the three-dimensional radiographic image G can be viewed stereoscopically, and that the two-dimensional radiographic image G is observed in plan view.

  Further, according to the captured image display device 4 according to the embodiment of the present invention, whether the radiation image G displayed more easily by the observer is two-dimensionally captured by displaying the data attribute DP as characters, It can be recognized whether it was taken three-dimensionally.

  In the present embodiment, the captured image display device 4 according to the embodiment of the present invention has been described as displaying the radiation image G of the breast M. However, the present invention is not limited to this, and parts such as the lungs and stomach May be displayed. Further, the subject is not limited to the radiation image G, and a subject photographed by a normal digital camera or the like may be displayed.

DP Data attribute FD Ancillary data GD Image data GF Image file M Breast (subject)
4 Captured Image Display Device 41 Monitor 43 Data Reading Unit

Claims (5)

Captured image data of a subject and the captured image data attached to the captured image data are captured image data obtained by capturing the subject in two dimensions, or captured image data obtained by capturing in three dimensions A data reading unit that reads out the captured image data and the auxiliary data from an image file including auxiliary data indicating whether the data attribute is,
A photographic image display device comprising: a display unit that displays a photographic image of the subject using the photographic image data and displays the data attribute using the auxiliary data.   The photographed image display apparatus according to claim 1, wherein the display unit displays the data attribute as character information.   The photographed image display device according to claim 1, wherein the display unit can perform both two-dimensional display and three-dimensional display of a photographed image of the subject.   The photographed image display device according to claim 1, wherein the photographed image is a radiation photographed image and the subject is a breast. The photographed image data of the subject and data attributes indicating whether the photographed image data is photographed image data obtained by two-dimensionally photographing the subject or photographed image data obtained by three-dimensional photographing. Reading the captured image data and the incidental data from an image file including the incidental data,
A photographed image display method, wherein the photographed image of the subject is displayed using the photographed image data, and the data attributes are displayed using the auxiliary data.

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