JP2007000250A - Optical or radiographic image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical or radiographic image display device capable of recognizing pixels in the periphery. <P>SOLUTION: The display device visualizes and outputs the pixel value in an arbitrarily selected area 13B of an X-ray image 13A obtained by radiography as a plurality of numeric value data arranged in matrices corresponding to respective coordinates of the area 13B. For example, when the numeric value data are visualized and output/displayed in a monitor 13, the visualized data are displayed in a frame 13C separate from the X-ray image 13A. Accordingly, if the periphery of a target pixel including the target pixel is the area 13B to be selected, the pixel values in the periphery are visualized and output as a plurality of value data arranged in matrices, so that the pixels in the periphery can be recognized based on the result of the output. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a light or radiation image display device used in the medical field, the industrial field, and further the nuclear field.

  An X-ray image display device that displays an image obtained by X-ray imaging will be described as an example. An X-ray image display device is used for an X-ray imaging device, and the X-ray imaging device uses, in addition to the X-ray image display device, an X-ray tube that irradiates X-rays and X-rays that are irradiated and transmitted through the subject. An X-ray detector for detection is provided. Data detected by the X-ray detector is converted from an analog value to a digital value. After obtaining an X-ray image based on the digitized data, the image is output and displayed on the monitor of the X-ray image display device.

When an X-ray imaging apparatus is used for medical diagnosis or the like, there is a case where it is desired to grasp the pixel value of a specific pixel region as numerical data such as a tumor. In such a case, in the video image field, for example, when the graphic cursor is moved to the position of the target pixel, the pixel value of the pixel pointed to by the cursor is displayed as numerical data on a monitor in a separate frame from the X-ray image. (See, for example, Patent Document 1).
Japanese Patent Laid-Open No. 6-351048 (pages 2, 3 and 2)

  However, in such a case, only one area is indicated by the cursor, and only one point of numerical data is displayed in a separate frame. Therefore, in the case of medical diagnosis, it is inconvenient to know the state of the upper, lower, left and right peripheral pixels in the X-ray image.

  This invention is made | formed in view of such a situation, Comprising: It aims at grasping | ascertaining a surrounding pixel and providing a light or a radiographic image display apparatus.

In order to achieve such an object, the present invention has the following configuration.
That is, the invention described in claim 1 is a light or radiation image display device that displays an image obtained by light or radiation imaging, and the pixel value of an arbitrarily selected region of the image Output means for visualizing and outputting as a plurality of numerical data arranged in a matrix corresponding to each coordinate is provided.

  [Operation / Effect] According to the first aspect of the present invention, the output means, for an image obtained by light or radiation imaging, calculates a pixel value of an arbitrarily selected area of the image, and coordinates of the area. Are visualized and output as a plurality of numerical data arranged in a matrix. Therefore, when the area around the pixel to be selected including the pixel of interest is selected, the surrounding pixel values are visualized and output as a plurality of numerical data arranged in a matrix. Based on this, peripheral pixels can be grasped.

  In the above-described invention, it is preferable that the image forming apparatus includes an area designating unit that designates a predetermined area from the image, and the output unit visualizes and outputs only the pixel value of the area designated by the area designating unit as numerical data (claim). Item 2). By providing such an area designating means, an arbitrary area in the image can be designated as a predetermined area, and the pixels in the area can be grasped.

  Moreover, any of binary, octal, decimal, and hexadecimal numbers is used as numerical data (the invention according to claim 3). By using such a decimal number, versatility is enhanced in the visualization of numerical data.

  In these inventions described above, it is preferable to provide switching display means capable of switching the numerical data to any one of binary display, octal display, decimal display, and hexadecimal display. Invention). By providing such a switching display means, it is possible to switch to a desired decimal number for display.

  Moreover, in these inventions described above, it is preferable to include transfer means capable of transferring numerical data to an external device while maintaining the matrix shape described above (the invention according to claim 5). By providing such a transfer means, it is possible to transfer numerical data to an external device and cause the external device to perform processing relating to numerical data.

  Further, in these inventions described above, it is preferable to include editing means that can edit numerical data, and image display updating means that updates the corresponding image display in conjunction with editing the numerical data from the editing means (claims). Item 6). By providing such editing means and image display updating means, the edited result can be reflected in the entire image.

  An example of the invention (invention according to claim 6) including an editing means and an image updating means includes an input means for inputting data, and the numerical data is edited by the editing means by input to the input means. (Invention of claim 7) Therefore, the numerical data can be easily edited by the editing means using the input means.

  Furthermore, in the invention provided with the editing means and the image updating means (the invention according to claim 6), the transfer means capable of transferring the numerical data edited by the editing means to the external device while maintaining the matrix shape. (The invention according to claim 8). By providing such a transfer means, the edited numerical data can be transferred to an external device, and the external device can perform processing related to the numerical data.

  Further, in the invention comprising the editing means and the image updating means (the invention described in claim 6), it is preferable that the editing of the numerical data by the editing means is performed by spreadsheet software associated with the cells of the matrix. 9). You can easily start editing spreadsheet data and edit numerical data.

  According to the light or radiation image display device according to the present invention, the output means, for an image obtained by light or radiation imaging, outputs the pixel value of an arbitrarily selected region of the image to each coordinate of the region. Correspondingly, since it is visualized and outputted as a plurality of numerical data arranged in a matrix, peripheral pixels can be grasped.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram of an X-ray fluoroscopic apparatus according to an embodiment. FIG. 2 is an equivalent circuit of a flat panel X-ray detector used in the X-ray fluoroscopic apparatus as viewed from the side. 3 is an equivalent circuit of a flat panel X-ray detector in plan view, and FIG. 4 is a block diagram of an X-ray image display device used in the X-ray fluoroscopic apparatus. An explanation will be given by taking an X-ray fluoroscopic imaging apparatus as an example of the imaging apparatus.

  As shown in FIG. 1, the X-ray fluoroscopic apparatus according to the present embodiment includes a top plate 1 on which a subject M is placed, an X-ray tube 2 that irradiates X-rays toward the subject M, a subject A flat panel X-ray detector (hereinafter appropriately referred to as “FPD”) 3 that detects X-rays transmitted through the specimen M is provided.

  In addition, the X-ray fluoroscopic apparatus includes a top panel control unit 4 that controls the elevation and horizontal movement of the top panel 1, an FPD control unit 5 that controls scanning of the FPD 3, and the tube voltage and tube current of the X-ray tube 2. Are output from an X-ray tube control unit 7 having a high voltage generation unit 6 that generates a signal, an A / D converter 8 that digitizes and extracts an X-ray detection signal that is a charge signal from the FPD 3, and an A / D converter 8. An image processing unit 9 that performs various processes based on the detected X-ray detection signal, a controller 10 that controls these components, a memory unit 11 that stores processed images, and an operator perform input settings. An input unit 12, a monitor 13 for outputting and displaying processed images, and a printer 14 for outputting and printing processed images are provided. The controller 10, the memory unit 11, the input unit 12, the monitor 13, and the printer 14 constitute an X-ray image display device 15. The X-ray image display device 15 corresponds to the light or radiation image display device in the present invention.

  The top board control unit 4 horizontally moves the top board 1 to accommodate the subject M up to the imaging position, moves the top and bottom, rotates and horizontally moves the subject M to a desired position, or horizontally moves the subject M. Then, the image is picked up, or the image is moved horizontally after the image pickup is finished, and the control is performed to retract from the image pickup position. The FPD control unit 5 performs control related to scanning by moving the FPD 3 horizontally or rotating around the body axis of the subject M. The high voltage generation unit 6 generates a tube voltage and a tube current for irradiating X-rays and applies them to the X-ray tube 2. The X-ray tube control unit 7 moves the X-ray tube 2 horizontally, Control relating to scanning by rotating around the axis of the body axis of M, control of the setting of the irradiation field of the collimator (not shown) on the X-ray tube 3 side, and the like are performed. When scanning the X-ray tube 2 or the FPD 3, the X-ray tube 2 and the FPD 3 move while facing each other so that the FPD 3 can detect the X-rays emitted from the X-ray tube 2.

  The controller 10 is configured by a central processing unit (CPU) and the like, and the memory unit 11 is configured by a storage medium represented by ROM (Read-only Memory), RAM (Random-Access Memory), and the like. Yes. The input unit 12 includes a pointing device represented by a mouse, a keyboard, a joystick, a trackball, a touch panel, and the like. In the fluoroscopic imaging apparatus, the FPD 3 detects X-rays transmitted through the subject M, and the image processing unit 9 performs image processing based on the detected X-rays, thereby imaging the subject M.

  As shown in FIG. 2, the FPD 3 includes a radiation-sensitive semiconductor thick film 31 in which carriers are generated when radiation such as X-rays enters, and a voltage application electrode 32 provided on the surface of the semiconductor thick film 31. The carrier collecting electrode 33 provided on the back surface opposite to the radiation incident side of the semiconductor thick film 31, the charge storage capacitor Ca for collecting the collected carriers to the carrier collecting electrode 33, and the capacitor Ca. It includes a thin film transistor (TFT) Tr, which is a switch element for taking out charges that is normally OFF (blocked) for taking out charges. In this embodiment, the semiconductor thick film 31 is formed of a radiation sensitive material, for example, amorphous selenium in which carriers are generated by the incidence of radiation, but is a photosensitive material in which carriers are generated by the incidence of light. There may be.

  In addition, in this embodiment, a data line 34 connected to the source of the thin film transistor Tr and a gate line 35 connected to the gate of the thin film transistor Tr are provided, and the voltage application electrode 32 and the semiconductor thick film 31 are provided. , A carrier collecting electrode 33, a capacitor Ca, a thin film transistor Tr, a data line 34, and a gate line 35 are stacked on an insulating substrate 36.

  As shown in FIGS. 2 and 3, for each of the carrier collection electrodes 33 formed in a large number (for example, 1024 × 1024 or 4096 × 4096) in a vertical / horizontal two-dimensional matrix arrangement, The capacitor Ca and the thin film transistor Tr are connected to each other, and the carrier collecting electrode 33, the capacitor Ca, and the thin film transistor Tr are separately formed as each detection element DU. Further, the voltage application electrode 32 is formed over the entire surface as a common electrode of all the detection elements DU. Further, as shown in FIG. 3, the data lines 34 described above are arranged in parallel in the horizontal (X) direction, and the gate lines 35 described above are arranged in the vertical (Y) direction as shown in FIG. The data lines 34 and the gate lines 35 are connected to the detection elements DU. The data line 34 is connected to the amplifier array circuit 37, and the gate line 35 is connected to the gate driver circuit 38. The number of detector elements DU arranged is not limited to the above-mentioned 1024 × 1024 or 4096 × 4096, and the number of detector elements DU can be changed according to the embodiment. Therefore, the form with only one detection element DU may be sufficient.

  The detection elements DU are patterned on the insulating substrate 36 in a two-dimensional matrix arrangement, and the insulating substrate 36 on which the detection elements DU are patterned is also called an “active matrix substrate”.

  When the periphery of the detection element DU of the FPD 3 is created, the data line 34 and the gate line 35 are formed on the surface of the insulating substrate 36 by using a thin film forming technique by various vacuum deposition methods or a pattern technique by photolithography. A thin film transistor Tr, a capacitor Ca, a carrier collection electrode 33, a semiconductor thick film 31, a voltage application electrode 32, and the like are sequentially stacked. The semiconductor for forming the semiconductor thick film 31 can be appropriately selected according to the application, withstand voltage, etc., as exemplified by an amorphous semiconductor and a polycrystalline semiconductor.

Subsequently, operations of the X-ray fluoroscopic apparatus and the flat panel X-ray detector (FPD) according to the present embodiment will be described. In a state where a bias voltage V _A of a high voltage (for example, about several hundred V to several tens kV) is applied to the voltage application electrode 32, radiation to be detected is incident. The application of the bias voltage V _A is also controlled from the FPD controller 5.

  Carriers are generated by the incidence of radiation, and the carriers are stored in the charge storage capacitor Ca as charge information. The gate line 35 is selected by the scanning signal for extracting signals from the gate driver circuit 38 (that is, the gate drive signal), and the detection element DU connected to the selected gate line 35 is selected and designated. The electric charge accumulated in the capacitor Ca of the designated detection element DU is read out to the data line 34 via the thin film transistor Tr that has been turned on by the signal of the selected gate line 35.

  The address (address) of each detection element DU is specified by a scanning signal for extracting signals from the data line 34 and the gate line 35 (a gate drive signal in the case of the gate line 35 and an amplifier drive signal in the case of the data line 34). ). When a scanning signal for signal extraction is sent to the amplifier array circuit 37 and the gate driver circuit 38, each detection element DU is selected from the gate driver circuit 38 in accordance with the scanning signal (gate driving signal) in the longitudinal (Y) direction. Then, the amplifier array circuit 37 is switched in accordance with the scanning signal (amplifier driving signal) in the horizontal (X) direction, whereby the charge accumulated in the capacitor Ca of the selected detection element DU is amplified via the data line 34. It is sent to the circuit 37. Then, the signal is amplified by the amplifier array circuit 37, output from the amplifier array circuit 37 as an X-ray detection signal, and sent to the A / D converter 8.

  For example, when the FPD 3 according to the present embodiment is used for detecting a fluoroscopic X-ray image of the X-ray fluoroscopic apparatus, the charge information (X-ray detection signal) read out to the outside through the data line 34 by the above-described operation. Is converted into image information and output as an X-ray fluoroscopic image (X-ray image).

  The image information is digitized by the A / D converter 8 and stored in the memory unit 11 in the form of numerical data. When outputting to the monitor 13 or the printer 14, shades are added according to the numerical data, and the imaging area of the subject M is associated with each pixel. An image in which each pixel is shaded is output as an X-ray image.

  A specific configuration of the X-ray image display apparatus 15 according to the present embodiment is as shown in FIG. That is, the controller 10 described above updates the function that can edit numeric data and the image display on the monitor 13 corresponding to the numeric data edited (see the X-ray image 13A in FIGS. 5 to 7). It has the function to do. The controller 10 corresponds to editing means and image display updating means in the present invention.

  The memory unit 11 described above is divided into areas of a ROM 11A and a RAM 11B. A program is stored in the ROM 11A in advance, and an image is temporarily stored in the RAM 11B as numerical data. A program is read from the ROM 11A, and the controller 10 executes the program. In this embodiment, the spreadsheet software 11a is stored in the ROM 11A in advance, and numerical data can be edited by reading the program of the spreadsheet software 11a and executing the program by the controller 10. The spreadsheet software 11a is not particularly limited as long as it is a program associated with a matrix cell (see row 18A and column 18B in FIG. 8). For example, MICROSOFT EXCEL (registered trademark) (Microsoft) or Lotus 1-2-3 (registered trademark) (IBM).

  The input unit 12 has a function of designating a predetermined region (see reference numeral 13B in FIGS. 6 and 7) from the X-ray image, and a function of editing the numerical data described above by input to the input unit 12. It has. Only the pixel value of the region 13B designated from the input unit 12 is visualized and output as numerical data by the monitor 13 and the printer 14. When output and displayed on the monitor 13, it is displayed in a separate frame (see reference numeral 13C in FIGS. 6 and 7). The input unit 12 corresponds to the area specifying unit and the input unit in the present invention.

  The monitor 13 outputs and displays the above-described X-ray image obtained by X-ray imaging as shown in FIGS. 5 to 7 (see reference numeral 13A). Then, only the pixel value of the region 13B designated from the input unit 12 is visualized and displayed as a plurality of numerical data arranged in a matrix corresponding to each coordinate of the region 13B. In this embodiment, when the numerical data is visualized and output and displayed on the monitor 13, it is displayed in the separate frame 13C as shown in FIGS.

  The printer 14 outputs and prints the above-described X-ray image obtained by X-ray imaging. Then, only the pixel values in the region 13B designated from the input unit 12 are visualized and printed as a plurality of numerical data as in the monitor 13. Thus, the monitor 13 and the printer 14 constitute output means in the present invention (refer to the output unit 17 in FIG. 4 in this embodiment).

  The numerical data is one of binary, octal, decimal, and hexadecimal, and the monitor 13 displays each of binary display, octal display, decimal display, and hexadecimal display. It has a switchable function. In this embodiment, examples of switching between decimal number display and hexadecimal number display are shown in FIGS. FIG. 6 shows the case where the separate frame 13C is displayed in decimal, and FIG. 7 shows the case where the separate frame is displayed in hexadecimal. The monitor 13 corresponds to the switching display means in this invention.

  In the present embodiment, the numerical data can be transferred to an external device for the X-ray image display device 15 while maintaining the matrix shape in the separate frame 13C. In the present embodiment, for example, the controller 10 in the X-ray image display device 15 and an external device are electrically connected by a communication line 16 typified by a LAN (Local Area Network) cable or a RS-232C standard cable, for example. By transferring via the communication line 16 via the controller 10, it is transferred to the external device. Further, in this embodiment, the edited numerical data can be transferred to the external device. The communication line 16 corresponds to the transfer means in this invention. Note that the transfer means is not limited to the communication line 16 such as a LAN cable or RS-232C standard cable, and is a means for transferring via an electromagnetic wave such as infrared rays or light, such as a wireless LAN. Also good.

  Next, specific display modes of numerical data will be described with reference to FIGS. As shown in FIG. 5, an X-ray image 13 </ b> A obtained by X-ray imaging is output and displayed on the monitor 13. Unlike the numerical data, the X-ray image 13A is shaded according to the numerical data, and the imaging area of the subject M is associated with each pixel.

  Next, as shown in FIG. 6, a predetermined region 13B is designated from the X-ray image 13A using the input unit 12 (see FIGS. 1 and 4). In the case of designating the area 13B, for example, a rectangular area surrounded by the left, right, top, and bottom is specified by dragging with the mouse of the input unit 12 between the left, right, top, and bottom, or the coordinates serving as the reference of the region are specified. There is no particular limitation as long as it is an area designation input method that is normally used, such as designating an area based on coordinates input by inputting into the keyboard.

  Only the pixel values of the designated area 13B are arranged in a matrix corresponding to the coordinates of the area 13B. For example, when the designated area 13B is composed of 256 pixels in the row direction and 256 pixels in the column direction, 256 pixels in the row direction correspond to the coordinates of the pixels, respectively. Cells and 256 cells in the column direction are prepared. Then, numerical data corresponding to a pixel value at a coordinate (pixel) corresponding to the cell is output to each cell, and visualized and output as a plurality of numerical data arranged in a matrix. As for the output form, a plurality of numerical data arranged in a matrix may be printed out to the printer 14, or a plurality of numerical data arranged in a matrix may be displayed in separate frames as shown in FIGS. You may display on 13C.

  In this embodiment, a decimal number display switching box 13D is displayed in the separate frame 13C as shown in FIGS. In this embodiment, the hex number display switching box 13D is provided with two check boxes. When the mouse is moved to one of the check boxes and clicked to be “active”, the other check box is displayed as “in”. Become active.

  For example, when decimal display is to be performed, the check box relating to decimal display (“DEC” in FIGS. 6 and 7) in the decimal display switching box 13D is moved to the “active” by clicking with the mouse. At this time, the check box (“HEX” in FIGS. 6 and 7) regarding the hexadecimal number display becomes “inactive”. Then, as shown in FIG. 6, the numerical data becomes a decimal number and is switched to the decimal number display.

  On the contrary, when the hexadecimal display is to be performed, the mouse is placed on the check box relating to the hexadecimal display in the hexadecimal display switching box 13D and clicked to make it “active”. At this time, the check box regarding decimal number display becomes “inactive”. Then, as shown in FIG. 7, the numerical data becomes a hexadecimal number and is switched to the hexadecimal number display.

  In the present embodiment, when editing numerical data, first, the program of the spreadsheet software 11a stored in advance in the ROM 11A (see FIG. 4) is read, and the controller 10 (see FIGS. 1 and 4). Run the program. A display mode after the program is started is shown in FIG. FIG. 8 shows a display mode related to a matrix cell composed of a plurality of rows 18A and a plurality of columns 18B (see the sheet 18 in FIG. 8), and numerical data in each cell of the sheet 18 in FIG. The numerical data in each cell of the separate frame 13C in FIG. That is, after the program is started, the numerical data of each cell in the separate frame 13C is read to the sheet 18, and the numerical data is output to each cell of the sheet 18 so as to correspond to FIG.

  Next, actual editing is performed by input to the input unit 12 (see FIGS. 1 and 4). When editing, for example, click on the cell in which the numerical data to be updated / changed is output with the mouse of the input unit 12, or move to the cell with the numeric keypad of the keyboard of the input unit 12, and then use the keyboard. There is no particular limitation as long as it is an input method for editing that is normally used, such as editing numerical data by inputting numerical data to be updated and changed.

  Thus, when numerical data is edited on the sheet 18 in FIG. 8, the corresponding X-ray image 13A is also updated in conjunction with it. For example, in the sheet 18 in FIG. 8, when the numerical data of the cell (hereinafter, this cell is referred to as “A1 cell”) where the first row 18A and the first column 18B intersect is edited, The editing result of the numerical data is reflected in the cell of another frame 13C in FIG. 7 corresponding to the A1 cell, and the region 13B in FIGS. 6 and 7 further corresponding to the cell of the other frame 13C corresponding to the A1 cell. The editing result is also reflected in the pixel value of each coordinate. For example, when the value of the numerical data is increased, the pixel value of each coordinate in the area 13B in FIGS. 6 and 7 increases, and as a result, a part of the area 13B of the X-ray image 13A becomes white. Conversely, when the value of the numerical data is lowered, the pixel value of each coordinate in the region 13B in FIGS. 6 and 7 is lowered, and as a result, a part of the region 13B of the X-ray image 13A becomes black.

  Of course, in the sheet 18 in FIG. 8, when the numerical data is edited in the entire third column (hereinafter, this column is referred to as “C column”), the separate frame 13C in FIG. The editing result of the numerical data is also reflected in the cell column, and the editing result is also obtained in the pixel value of each coordinate in the region 13B in FIGS. 6 and 7 further corresponding to the cell column of the separate frame 13C corresponding to the C column. Is reflected. For example, when the value of the numerical data is increased, the pixel value of each coordinate in the area 13B in FIGS. 6 and 7 is increased, and as a result, a part of the area 13B of the X-ray image 13A becomes white in a column shape. . On the other hand, when the value of the numerical data is lowered, the pixel value of each coordinate in the area 13B in FIGS. 6 and 7 is lowered, and as a result, a part of the area 13B of the X-ray image 13A becomes black in a column shape. Become.

  According to the X-ray image display device 15 used in the above-described X-ray fluoroscopic apparatus according to the present embodiment, the output unit 17 including the monitor 13 and the printer 14 has the following about the X-ray image 13A obtained by X-ray imaging. The pixel values of an arbitrarily selected region 13B of the X-ray image 13A are visualized and output as a plurality of numerical data arranged in a matrix corresponding to each coordinate of the region 13B. Accordingly, when the area around the pixel including the pixel to be noticed is selected as the region 13B to be selected, the surrounding pixel values are visualized and output as a plurality of numerical data arranged in a matrix. The surrounding pixels can be grasped based on the above.

  In the present embodiment, the input unit 12 has a function of designating a predetermined region 13B from the X-ray image 13A. The output unit 13 visualizes and outputs only the pixel values of the designated region 13B as numerical data. By providing such a function, an arbitrary region 13B in the image can be designated as the predetermined region 13B, and the pixels in the region 13B can be grasped.

  In the present embodiment, description has been made by taking decimal numbers and hexadecimal numbers as numerical data, but any of binary numbers, octal numbers, decimal numbers, and hexadecimal numbers is used as the numerical data. By using such a decimal number, versatility is enhanced in the visualization of numerical data.

  In this embodiment, the monitor 13 is provided with a function capable of switching between numeric data and decimal display or hexadecimal display. By providing such a function, the display can be switched to a desired decimal number. Even in this case, it is only necessary to switch to any one of binary display, octal display, decimal display, and hexadecimal display.

  In this embodiment, the communication line 16 is provided that can transfer numerical data to an external device while maintaining the matrix state. Furthermore, in this embodiment, the edited numerical data can be transferred via the communication line 16. By providing such a communication line 16, it is possible to transfer numerical data or edited numerical data to an external device and cause the external device to perform processing related to each numerical data.

  Further, in this embodiment, the controller 10 has a function that can edit numerical data and a function that updates the corresponding image display when the numerical data is edited. By providing such a function, the edited result can be reflected in the entire image.

  In the present embodiment, the input unit 12 has a function of editing numerical data by input to the input unit 12. Therefore, numerical data can be easily edited using the input unit 12.

  In this embodiment, numerical data is edited by the spreadsheet software 11a associated with the cells of the matrix. The spreadsheet software 11a can be activated to easily edit numerical data.

  The present invention is not limited to the above-described embodiment, and can be modified as follows.

  (1) In the above-described embodiment, the X-ray image display device 15 is used in the X-ray fluoroscopic imaging apparatus as shown in FIG. 1, but the present invention is, for example, an X-ray fluoroscope disposed on a C-type arm. You may apply to an imaging device. The present invention may also be applied to an X-ray CT apparatus. Moreover, it is not limited to an imaging device, You may use for a nondestructive inspection apparatus.

  (2) In the above-described embodiment, the flat panel X-ray detector for detecting X-rays has been described as an example. However, an X-ray detector represented by an image intensifier may be used. The invention relates to radiation that detects radiation, as exemplified by a γ-ray detector that detects γ-rays emitted from a subject administered with a radioisotope (RI), such as an ECT (Emission Computed Tomography) apparatus. If it is a detector, it will not specifically limit. Similarly, the present invention is not particularly limited as long as it is a radiographic image display device used for an apparatus that detects and captures radiation, as exemplified by the ECT apparatus described above.

  (3) In the above-described embodiments, the radiation detectors typified by X-rays and the like have been described as examples in each of the above-described embodiments. However, the present invention can also be applied to a photodetector that detects light. . Therefore, there is no particular limitation as long as it is an optical image display device used in an apparatus that detects light and performs imaging.

  (4) In the embodiment described above, the input unit 12 has a function of designating a predetermined region 13B from the X-ray image 13A, and the output unit 13 visualizes only the pixel value of the designated region 13B as numerical data. However, the external device may have the function of the input unit 12, and the output unit 13 may visualize and output the pixel value of an area arbitrarily selected by the external device as numerical data.

  (5) In the embodiment described above, the monitor 13 has a function capable of switching numerical data to either decimal display or hexadecimal display. However, the monitor 13 has a function capable of switching to other display. You may prepare. For example, a function capable of switching to any one of binary number display and octal number display may be provided, or a function capable of switching to any one of binary number display, octal number display, and decimal number display. You may prepare. Further, the monitor 13 may be configured so that only one decimal number is displayed and the display is not switched to another true number display. In the case of binary display or hexadecimal display, it is particularly effective when the device is debugged (inspection or repair).

  (6) In the above-described embodiment, the communication line 16 that can transfer numerical data or edited numerical data to an external device in a state in which the matrix shape is maintained is provided. Further, the edited numerical data may not be transferred to the external device, but only the numerical data before being edited may be transferred to the external device.

  (7) In the above-described embodiment, the controller 10 has a function that can edit numerical data and a function that updates the corresponding image display when the numerical data is edited, but it is not always necessary. Such numerical data may be transferred to an external device, and the numerical data may be edited in the external device.

  (8) In the above-described embodiment, the input unit 12 has a function of editing numerical data by input to the input unit 12, but it is not always necessary to have such a function. The edited numerical data may be incorporated in the program in advance, and the program may be read out at the time of editing to be edited into the numerical value incorporated in the program.

  (9) In the embodiment described above, the numerical data is edited by the spreadsheet software 11a associated with the matrix cell, but is not limited to the spreadsheet software 11a. For example, numerical data may be pasted into a text editor, editing may be performed on the text editor, and editing may be performed by rewriting the numerical data. In addition, editing may be performed by directly writing in each cell of another frame 13C in FIGS. 6 and 7 may be incorporated by linking the sheet of the separate frame 13C to the spreadsheet software 11a, and writing directly to each cell of the separate frame 13C while being linked to the spreadsheet software 13a. Good. In addition, the numerical data of each cell in the separate frame 13C in FIGS. 6 and 7 may be copied, the sheet activated by the spreadsheet software 11a may be designated as the copy destination, and pasted and edited. . In addition, a calculation formula (for example, function fx in the case of MICROSOFT EXCEL) is embedded in each cell of the spreadsheet software 11a, and numerical data is input to a sheet activated by the spreadsheet software 11a, based on the calculation formula. You may make it output to a cell.

  (10) The present invention may be applied to a monochrome image as in the above-described embodiment, or may be applied to a color image such as RGB. In the case of RGB, numerical data may be output separately for each RGB.

1 is a block diagram of an X-ray fluoroscopic apparatus according to an embodiment. 2 is an equivalent circuit of a flat panel X-ray detector as viewed from the side, which is used in an X-ray fluoroscopic apparatus. 2 is an equivalent circuit of a flat panel X-ray detector in plan view. It is a block diagram of the X-ray image display apparatus used for a X-ray fluoroscopic apparatus. It is a figure which shows an example of the display mode regarding only an X-ray image. It is a display mode regarding an X-ray image and another frame, and is a diagram showing an example of a mode when the other frame is displayed in decimal. It is a display mode regarding an X-ray image and another frame, and is a diagram illustrating an example of a mode when the other frame is displayed in hexadecimal. It is a figure which shows an example of the display mode regarding the cell of the matrix which consists of several rows and several columns.

Explanation of symbols

10 ... Controller 11A ... ROM
DESCRIPTION OF SYMBOLS 11a ... Spreadsheet software 12 ... Input part 13 ... Monitor 13A ... X-ray image 13B ... Area | region 13C ... Separate frame 14 ... Printer 15 ... X-ray image display apparatus 16 ... Communication line 17 ... Output part

Claims (9)

  A light or radiation image display device for displaying an image obtained by light or radiation imaging, wherein pixel values of an arbitrarily selected region of the image are arranged in a matrix corresponding to each coordinate of the region A light or radiation image display device comprising output means for visualizing and outputting as a plurality of numerical data.   The light or radiation image display device according to claim 1, further comprising: a region designating unit that designates a predetermined region from the image, wherein the output unit outputs only the pixel value of the region designated by the region designating unit. A light or radiation image display device characterized by being visualized and output as data.   3. The light or radiation image display device according to claim 1, wherein the numerical data is any one of a binary number, an octal number, a decimal number, and a hexadecimal number. .   4. The light or radiation image display device according to claim 1, wherein the numerical data can be switched to any one of binary display, octal display, decimal display, and hexadecimal display. A light or radiation image display device comprising a switching display means.   5. The light or radiation image display device according to claim 1, further comprising transfer means capable of transferring the numerical data to an external device while maintaining the matrix shape. Or a radiation image display device.   6. The light or radiation image display device according to claim 1, wherein an editing unit capable of editing the numerical data and the corresponding image display when the numerical data is edited from the editing unit. A light or radiation image display device comprising: an image display update unit for updating.   The light or radiation image display device according to claim 6, further comprising an input unit for inputting data, wherein the numerical data is edited by the editing unit by input to the input unit. Display device.   8. The light or radiation image display device according to claim 6, further comprising a transfer unit capable of transferring the numerical data edited by the editing unit to an external device while maintaining the matrix shape. Characteristic light or radiation image display device. The light or radiation image display device according to any one of claims 6 to 8, wherein the editing of the numerical data by the editing means is performed by spreadsheet software associated with the cells of the matrix. Light or radiation image display device.

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