JP6242075B2 - Endoscope apparatus and endoscope image recording folder display method - Google Patents

Description

  The present invention relates to an endoscope apparatus and a method for displaying an endoscope image recording folder.

  Conventionally, endoscope apparatuses have been widely used in the industrial field and the medical field. An endoscope apparatus includes an insertion unit that is inserted into an observation object and a main body unit that includes a display unit that displays an endoscopic image that is an observation image obtained by imaging the inside of the object. Is common. In an industrial field, an endoscope apparatus is used for inserting and inserting an elongated insertion portion into a boiler, a turbine, an engine, or the like to observe and inspect internal scratches and corrosion.

  When an endoscopic examination is performed, a plurality of endoscopic images obtained by imaging the inside of the examination object are recorded in a plurality of folders for each examination object, for example, for each examination position. By using such a plurality of folders, the inspector records the endoscopic image obtained by imaging in the corresponding folders of the plurality of folders created in advance according to the inspection position, inspection procedure, etc. I can go. The structure of a plurality of folders and the name of each folder are different for each inspection object.

  For example, Japanese Patent Laid-Open No. 2006-350943 discloses a method for displaying thumbnails of a plurality of files to be printed and a method for selecting a file to be printed across a plurality of folders. .

JP 2006-350943 A

  However, when an endoscopic examination is performed, if examination images are recorded in a plurality of folders, an examination omission in which no examination images are recorded in the folder may occur. The inspector takes the recording medium on which the inspection image is recorded, for example, to a company or the like, checks whether the inspection image is recorded in a plurality of folders, and confirms that there is no inspection omission. At this time, the inspector needs to check whether or not the inspection image is recorded by referring to the inside of each folder, and it is very troublesome if the number of folders is large.

  However, Japanese Patent Application Laid-Open No. 2006-350943 discloses a technique for notifying a folder having no image when an image to be printed across a plurality of folders can be displayed but images are recorded in the plurality of folders. It has not been.

  Therefore, an object of the present invention is to provide an endoscope apparatus capable of notifying whether or not there is an inspection image in a folder for storing an inspection image, and a method for displaying an endoscope image recording folder. To do.

An endoscope apparatus according to an aspect of the present invention includes an imaging unit and a first mode for extracting folder generation information related to generation of a plurality of folders that record a plurality of image data to be examined. Analyzing an image obtained by imaging and extracting the folder generation information, and generating the plurality of folders for the inspection object based on the folder generation information extracted by the analysis unit In the second mode for recording the plurality of image data to be inspected with the folder generation unit, one folder among the plurality of folders generated by the folder generation unit is displayed on the live image. when displaying a folder in which to record a plurality of image data, it confirms the image data in the folder that the display and has the display and follower Based on whether the image data Da is recorded, and a display control unit for changing the display format of the folder name of the display to that folder.

One aspect a method displays an endoscope image recording folder of the present invention, in a first mode for extracting a folder creation information on the generation of a plurality of folders for recording a plurality of image data of the inspection object, the endoscope Analyzing an image captured by an imaging unit of a mirror device to extract the folder generation information, and generating the plurality of folders for the inspection object based on the extracted folder generation information In the second mode for recording the plurality of image data to be inspected, one folder among the plurality of generated folders is a folder for recording the plurality of image data on a live image. when displaying as to confirm the image data in the folder that the display, and the image data in the folder that the display and is recorded Based on whether includes, for changing the display format of the folder name of the folder that the displayed.

  ADVANTAGE OF THE INVENTION According to this invention, the endoscope apparatus which can alert | report whether there exists a test | inspection image in the folder which preserve | saves a test | inspection image, and the display method of the folder for endoscopic image recording can be provided.

1 is an external configuration diagram of an endoscope apparatus 1 according to an embodiment of the present invention. 2 is a block diagram for explaining a circuit configuration inside a main body portion 2 of the endoscope apparatus 1. FIG. It is a figure for demonstrating the case where the two-dimensional code at the time of producing | generating the several folder corresponding to a test object is image | photographed. It is a flowchart which shows the example of the flow of a process when the endoscope apparatus 1 is designated folder generation mode. It is a figure which shows the example of the reading guide displayed on LCD4. It is a figure which shows the example of a display of a confirmation message. It is a figure which shows the example of a display of an error message. It is a figure which shows the other example of a display of an error message. It is a figure for demonstrating the example of the folder which has a hierarchical structure. It is a figure for demonstrating the transition of the screen display at the time of change of a recording destination folder. It is a figure for demonstrating the example of a highlight display. It is a flowchart which shows the example of the flow of a change process of a recording destination folder, and a highlight display process. It is a flowchart which shows the example of the flow of a change process of a recording destination folder, and a highlight display process. It is a flowchart which shows the example of the flow of a change process of a recording destination folder, and a highlight display process. It is a figure which shows the example of a display of a confirmation message. It is a figure which shows the example of a screen in the case of displaying a recording destination folder in the state in which the still image was displayed. It is a figure for demonstrating the example of the screen in the case of displaying the number of image files according to a folder name. It is a figure for demonstrating the example of the screen in the case of displaying the number of image files according to a folder name. It is a figure for demonstrating the example of the screen in the case of displaying the number of image files currently recorded according to the folder name, and the number of required acquisition image files in the form like a fraction. It is a figure for demonstrating the example of the screen in the case of displaying the window which shows that the image file is not recorded in the recording destination folder. It is a figure for demonstrating the example of the screen in the case of displaying the list of folder trees. It is a figure for demonstrating the example of the screen in the case of displaying a folder icon on the list of folder trees. It is a figure for demonstrating the example of the screen in the case of displaying the list of folders without an image file. It is a figure for demonstrating the example of the screen in the case of displaying the list | wrist of an incomplete examination folder.

  Embodiments of the present invention will be described below with reference to the drawings.

(overall structure)
FIG. 1 is an external configuration diagram of an endoscope apparatus 1 according to the present embodiment.

  As shown in FIG. 1, the endoscope apparatus 1 includes a main body 2 that is a main unit and a scope unit 3 connected to the main body 2. The main body 2 has a liquid crystal panel (hereinafter abbreviated as LCD) 4 as a display device on which an endoscopic image, an operation menu, and the like are displayed. The LCD 4 is a display unit that displays an endoscopic image. As will be described later, the LCD 4 may be provided with a touch panel (FIG. 2). The scope unit 3 includes an operation unit 5, a universal cable 6 that connects the operation unit 5 and the main body unit 2, and an insertion unit 7 that includes a flexible insertion tube. The scope unit 3 can be attached to and detached from the main body 2. An imaging unit (FIG. 2) to be described later is built in the distal end portion 8 of the insertion portion 7. The imaging unit includes an imaging element such as a CCD sensor or a CMOS sensor, and an imaging optical system such as a lens arranged on the imaging surface side of the imaging element. A bending portion 9 is provided on the proximal end side of the distal end portion 8. An optical adapter 10 can be attached to the distal end portion 8. The operation unit 5 is provided with various operation buttons such as a freeze button and a recording instruction button (hereinafter referred to as a REC button).

  The user can operate the various operation buttons of the operation unit 5 to perform shooting of an object, recording of a still image, and the like. The user can bend the bending portion 9 in a desired direction by operating the up / down / left / right (U / D / L / R) direction bending button 5a. Furthermore, when changing the recording destination folder of the endoscopic image described later, the user performs an operation of tilting the joystick 5b provided in the operation unit 5 in one of the up, down, left, and right directions. The recording folder can be selected. In the case where the touch panel is provided on the LCD 4, the user can instruct various operations of the endoscope apparatus 1 by operating the touch panel. That is, the touch panel constitutes an instruction unit that instructs the operation content of the endoscope apparatus 1.

  The image data of the endoscopic image obtained by imaging is inspection data to be inspected, and is recorded on the memory card 11 that is a recording medium. The memory card 11 is detachable from the main body 2. The memory card 11 stores a plurality of folders for recording image data of endoscopic images. A plurality of folders corresponding to the inspection target are generated and stored in the memory card 11 as described later.

  In the present embodiment, a plurality of folders and image data are recorded on the memory card 11 as a recording medium detachable from the main body unit 2, but are recorded on a memory built in the main body unit 2. It may be.

  The user brings the distal end portion 8 of the insertion portion 7 close to the inspection site to be inspected and images the inspection site. The LCD 4 displays the captured endoscope image. Further, as will be described later, the user operates the operation unit 5 while confirming the folder in the memory card 11 in which the endoscope image is recorded at the time of examination, and if necessary, the recording destination of the endoscope image. You can change the folder.

(Circuit configuration)
FIG. 2 is a block diagram for explaining an internal circuit configuration of the main body 2 of the endoscope apparatus 1.

  The main body 2 includes a central processing unit (hereinafter referred to as CPU) 21, a ROM 22, and a RAM 23, which are connected to each other via a bus 24. Furthermore, a plurality of various interfaces (hereinafter referred to as I / F) 25 to 31 are connected to the bus 24. The I / F 25 is a driving and receiving circuit for transmitting a driving signal to the imaging unit 41 of the scope 3 and receiving an imaging signal from the imaging unit 41. The I / F 26 is a drive circuit for transmitting a drive signal to the LED 42 as the illumination unit.

  The I / F 27 is a circuit for receiving various operation signals from the operation unit 5. The various operation signals from the operation unit 5 include operation signals for the joystick 5b. In the configuration in which the touch panel 32 is provided on the LCD 4, the I / F 28 is provided as a circuit for receiving a drive signal to the touch panel 32 and an operation signal from the touch panel 32. The I / F 29 is a circuit for supplying an image signal to the LCD 4.

  The I / F 30 is a circuit for writing image signals to the memory card 11 and reading image signals from the memory card 11. The I / F 30 is connected to the memory card 11 via a connector 33 provided in the main body 2. The memory card 11 is detachably attached to the connector 33.

  The I / F 31 is a circuit for connecting a personal computer (hereinafter referred to as a PC) 43, which is an external device, to the main unit 2. The PC 43 is connected to the main body 2 via a connector (not shown), and the main body 2 can exchange data with the PC 43 via the I / F 31 connected to the connector. As indicated by the dotted line, the PC 43 has a CPU 43 a and a monitor 44.

  The main body 2 includes a battery 34 therein, and the battery 34 supplies power to various circuits in the main body 2.

  Each I / F operates under the control of the CPU 21. When the endoscope apparatus 1 is activated, the CPU 21 outputs a drive instruction signal for the LED 42 to the I / F 26. The LED 42 is driven by the output of the I / F 26 to illuminate the subject. Then, the CPU 21 outputs various drive signals to the imaging unit 41 via the I / F 25. The imaging unit 41 outputs an imaging signal to the CPU 21. As a result, a live image is displayed on the LCD 4.

  The operation unit 5 supplies various operation signals indicating the operation contents by the user to the operation unit 5 to the CPU 21. When the user presses a freeze button as will be described later, the CPU 21 generates a still image based on the imaging signal from the imaging unit 41. Further, when the user presses the REC button, the image data of the still image is recorded on the memory card 11. Since the freeze still image is displayed on the LCD 4, the user can once confirm the frozen still image. When the user records the still image, the user presses the REC button.

  Further, various programs corresponding to various modes are stored in the ROM 22. The CPU 21 is configured to be able to read a program corresponding to the instruction from the ROM 22 and execute it in accordance with an instruction of a user who is an inspector. The endoscope apparatus 1 has other modes in addition to the endoscopic examination mode that is a mode for performing a normal endoscopic examination. As another mode, there is a folder generation mode for storing image data of an endoscopic image. As will be described below, the user can automatically generate a plurality of folders corresponding to the inspection target in the memory card 11 by executing the folder generation mode.

(Create folder)
The name and configuration of the inspection object differ depending on the inspection object. For example, the name and configuration of the inspection target are different between the aircraft engine and the piping system, and even the aircraft engine is different depending on the manufacturer, model, and the like.

  In the present embodiment, the endoscope apparatus 1 is configured to be able to generate an inspection image folder suitable for different inspection objects, for example, at an inspection site where the inspection object is inspected.

  In the present embodiment, the plurality of folders for storing the inspection images to be inspected are obtained by imaging the two-dimensional code attached to the inspection target by the imaging unit 41 that is the imaging unit of the endoscope apparatus 1. Generated. FIG. 3 is a diagram for explaining a case where a two-dimensional code is generated when a plurality of folders corresponding to the inspection target is generated.

  The user operates the predetermined button or the like of the operation unit 5 to set the endoscope apparatus 1 in a folder generation mode that is a mode for generating a plurality of folders for the inspection target. When the folder generation mode is set, the endoscope apparatus 1 executes a folder generation process. The user brings the distal end portion 8 of the insertion portion 7 close to the QR code (registered trademark) TDC and images the QR code (registered trademark) TDC. The QR code (registered trademark) TDC is printed on, for example, a sticker, paper, etc., and affixed to the casing OB to be inspected. QR code (registered trademark) is inspection object recognition information and includes folder generation information. As will be described later, based on folder generation information obtained by analyzing a QR code (registered trademark), a plurality of folders for an inspection target are generated.

  Next, folder generation processing will be described. As described above, the folder generation mode is among the plurality of operation modes of the endoscope apparatus 1. The user can execute the endoscope apparatus 1 in a desired operation mode by designating the operation mode. The folder generation process is executed when a folder generation mode is designated by the user. FIG. 4 is a flowchart illustrating an example of a flow of processing when the endoscope apparatus 1 is designated with the folder generation mode. Here, for simplicity of explanation, the folder generation processing will be described by showing a case where there are two modes, a folder generation mode and a normal endoscopic examination mode. A folder generation program for the processing shown in FIG. 4 is stored in the ROM 22.

  When the user inputs an operation mode to the operation unit 5, the CPU 21 executes the process of FIG. First, it is determined whether or not the input operation mode is a folder generation mode (S1).

  When the input operation mode is the folder generation mode (first mode) (S1: YES), the CPU 21 displays a reading guide on the LCD 4 (S2). The reading guide indicates a recommended range for positioning the QR code (registered trademark).

  FIG. 5 is a diagram illustrating an example of a reading guide displayed on the LCD 4. On the screen 4a of the LCD 4, a guide 200 indicating a frame for appropriately capturing a QR code (registered trademark) TDC as inspection object recognition information is displayed. Here, the guide 200 is composed of four L-shaped figures serving as indices at the four corners of a rectangular QR code (registered trademark) TDC. The QR code (registered trademark) TDC is preferably imaged such that the QR code (registered trademark) TDC is positioned within a range indicated by four L-shaped figures.

  The process of S2 constitutes a guide image display unit that displays a guide image for obtaining the folder generation information by the imaging unit on the LCD 4 as the display unit in the folder generation mode.

  In the present embodiment, the QR code (registered trademark) is used as the two-dimensional code. However, other codes may be used. In that case, a guide that matches the shape of the other cords adopted is displayed. For example, the guide may be a cross mark, a square mark, or the like.

  After S2, the CPU 21 determines, for example, whether or not an image has been recorded by pressing the REC button after pressing the freeze button (S3). If no image is recorded (S3: NO), the process returns to S2.

  When an image is recorded (S3: YES), the CPU 21 determines whether or not there is a QR code (registered trademark) TDC that is a two-dimensional code in the guide 200 of the recorded image (S4). In S4, it is determined by image processing whether an QR code (registered trademark) is present in the image portion in the guide 200. The recorded image is stored in the RAM 23. In S3 and S4, the CPU 21 may determine the presence / absence of a QR code (registered trademark) in the live image without requiring the operation of the freeze button and the REC button.

  When a two-dimensional code, that is, a QR code (registered trademark) is included in the recorded image (S4: YES), the CPU 21 is a two-dimensional code for folder generation in which the two-dimensional code is attached to the inspection target. It is determined whether or not (S5). This is because the QR code (registered trademark) included in the recorded image may not be a QR code (registered trademark) for folder generation. In S5, it is determined by image processing whether the QR code (registered trademark) included in the recorded image is a QR code (registered trademark) for folder generation including predetermined information. The QR code (registered trademark) for folder generation includes information for folder generation. The determination of S5 can be performed by determining the presence / absence of information for generating the folder.

  When the QR code (registered trademark) for folder generation is read (S5: YES), the CPU 21 displays a confirmation message indicating target information regarding the inspection target included in the read information on the screen 4a of the LCD 4 Display (S6). As the target information, for example, the name of the highest folder is displayed on the screen of the LCD 4. When the read QR code (registered trademark) is a QR code (registered trademark) for folder generation, the folder generation information included in the QR code (registered trademark) includes the name of the folder. For example, the name of the highest folder includes the name of the inspection target, the model number, or the abbreviation thereof, so the user can confirm the inspection target.

  FIG. 6 is a diagram illustrating a display example of a confirmation message. A predetermined confirmation message is displayed on the screen 4 a of the LCD 4 by the window 201. In FIG. 6, the message 202 “The inspection object is ENGINE1_SN001” is displayed in the window 201.

  Further, the window 201 includes an “OK” button 203 and a “Cancel” button 204. The user can select the “OK” button 203 or the “Cancel” button 204 by performing a predetermined operation on the operation unit 5. In FIG. 6, since the “OK” button 203 is selected as a default, the “OK” button 203 is displayed more emphasized than the “Cancel” button 204.

  The user selects an “OK” button 203 when the inspection target to be inspected matches the inspection target indicated by the information indicated in the confirmation message. However, if the inspection target to be inspected does not match the inspection target indicated by the information indicated in the confirmation message, the user selects the “Cancel” button 204.

  If the scanned image is not a two-dimensional code (S4: NO) or the two-dimensional code is not a QR code (registered trademark) for folder generation (S5: NO), an error message is displayed ( S7), the process returns to S2. Therefore, the user can read the QR code (registered trademark) again.

  FIG. 7 is a diagram illustrating a display example of an error message. A predetermined error message is displayed on the screen 4 a of the LCD 4 through the window 205. In FIG. 7, a message 206 “The inspection object recognition information could not be read” is displayed in the window 205. The error message in FIG. 7 is an example of a case where the read image is displayed when the read image is not a two-dimensional code.

  Further, the window 205 includes an “OK” button 207. The user can select an “OK” button 207 by performing a predetermined operation on the operation unit 5.

  The user confirms that the QR code (registered trademark) that is the inspection object recognition information regarding the inspection object to be inspected cannot be read, and selects the “OK” button 207.

  FIG. 8 is a diagram illustrating another display example of the error message. A predetermined error message is displayed on the screen 4 a of the LCD 4 by a window 208. In FIG. 8, a message 209 “Inspection object recognition information is not correct” is displayed in the window 208. The error message in FIG. 8 is an example of a case where the read QR code (registered trademark) is displayed when the QR code (registered trademark) for folder generation is not.

  Therefore, when the processing of S7 is the folder generation mode and the folder generation information is not included in the image obtained by the imaging unit 41 as the imaging unit, the folder generation information is displayed on the LCD 4 as the display unit. An extraction result display unit for displaying that it is not included is configured.

  The window 208 further includes an “OK” button 210. The user can select an “OK” button 210 by performing a predetermined operation on the operation unit 5.

  After the process of S6, the CPU 21 determines whether or not the “OK” button 203 in FIG. 6 has been selected (S8). If the “OK” button 203 is not selected, that is, if the “Cancel” button 204 is selected (S8: NO), the process returns to S2.

  When the “OK” button 203 is selected (S8: YES), the CPU 21 analyzes the QR code (registered trademark) and extracts folder generation information (S9). In the folder generation mode for extracting folder generation information related to generation of a plurality of folders for recording a plurality of image data to be inspected, the process of S9 captures an image obtained by imaging by the imaging unit 41 that is an imaging unit. An analysis unit that analyzes and extracts folder generation information is configured.

  Then, the CPU 21 creates a plurality of folders in the memory card 11 based on the folder generation information (S10). The process of S10 constitutes a folder generation unit that generates a plurality of folders for the inspection target based on the folder generation information extracted in the process of S9, which is an analysis unit. Subsequently, when the image of the QR code (registered trademark) is stored in the RAM 23, the CPU 41 deletes the image data of the QR code (registered trademark) in the RAM 23 (S11).

  As described above, a folder to be inspected can be generated without fail by reading the two-dimensional code attached to the inspection object casing OB or the like with a seal or the like using the endoscope apparatus.

  When the input operation mode is not the folder generation mode (first mode) (S1: NO), the CPU 21 shifts to processing in the endoscopic examination mode (second mode) (S12).

  In the above example, when the QR code (registered trademark) is read correctly and the QR code (registered trademark) is a QR code (registered trademark) for folder generation, a confirmation message is displayed for user confirmation. The screen is displayed on the screen 4a of the LCD 4. However, a plurality of folders may be generated without user confirmation, that is, without performing the processes of S6 and S8.

(Folder structure)
The folder structure generated by the folder generation process will be described.

  As described above, the user images the QR code (registered trademark) attached to the examination target by the imaging unit 41 of the insertion unit 7 of the endoscope apparatus 1. Then, a plurality of folders having a hierarchical structure with respect to the inspection object are generated in the memory card 11 at the inspection site before the endoscopic inspection. Each generated folder is given a folder name. Thus, the folder generation information includes folder names for a plurality of generated folders.

  As will be described later, in the endoscopic examination mode, the user places the endoscopic image obtained by imaging with the imaging unit 41 of the scope 3 into a desired folder among a plurality of folders having a hierarchical structure. Can be recorded.

  FIG. 9 is a diagram for explaining an example of a folder having a hierarchical structure. FIG. 9 schematically shows each folder and the files included in the folder in order to explain a folder having a hierarchical structure. Here, an example in which the folder has two hierarchies, that is, two levels, is shown. Is shown.

  As illustrated in FIG. 9, a folder “ENGINE1_SN001” is created under “root”, and a plurality of lower folders are included under the folder “ENGINE1_SN001”.

  In FIG. 9, three subfolders “HPC_STAGE1_ZONE1_1”, “HPC_STAGE1_ZONE1_2”, and “HPC_STAGE1_ZONE2_1” are shown.

  “ENGINE1” in “ENGINE1_SN001” is, for example, an engine name, and “SN001” is a serial number or the like. In the present embodiment, “ENGINE1_SN001”, which is a combination of the engine name and the serial number, is the inspection object information.

  The folder “ENGINE1_SN001” and the folder groups “HPC_STAGE1_ZONE1_1”, “HPC_STAGE1_ZONE1_2”, and “HPC_STAGE1_ZONE2_1” have different hierarchies.

  That is, the folder for inspection as shown in FIG. 9 is automatically generated under “root” in the memory card 11 by the folder generation process described above. Then, as will be described later, the user selects an arbitrary folder from among the plurality of folders generated in advance as the endoscope image recording folder. The user can record an endoscopic image in the selected folder.

  In this embodiment, there are two folder hierarchies generated based on the QR code (registered trademark), but there may be three or more folder hierarchies. Further, as indicated by a dotted line in FIG. 9, the number of folders in the same hierarchy may be three or more. Further, it is not always necessary that the folder has two or more hierarchies, and a folder structure having only one hierarchy under “root” may be used.

  As shown in FIG. 9, it is shown that a plurality of endoscope images in JPEG format are recorded in three subfolders “HPC_STAGE1_ZONE1_1”, “HPC_STAGE1_ZONE1_2”, and “HPC_STAGE1_ZONE2_1”.

  The file name included in each folder has a structure in which a file mark and a serial number are added to the folder names of the upper and lower layers. That is, the file name is “upper folder name_lower folder name_file mark_serial number.jpg”.

  For example, the folder name “ENGINE1_SN001” in the upper folder and the folder name “HPC_STAGE1_ZONE1_1” in the lower folder are connected with the symbol “_” (underscore), and the file mark “A” and serial number “001” are added. Thus, a file name “ENGINE1_SN001_HPC_STAGE1_ZONE1_1_A_001.jpg” is generated. The configuration of the file name will be described in detail later.

(Image recording and screen display)
Next, the screen display when changing the recording destination folder of the endoscopic image obtained by imaging when the endoscope apparatus 1 is set to the endoscopic examination mode will be described. FIG. 10 is a diagram for explaining the transition of the screen display when the recording destination folder is changed.

  When the power of the endoscope apparatus 1 is turned on, a live image of a target imaged by the imaging unit 41 is usually displayed on the screen of the LCD 4. The user performs the inspection while viewing the live image of the inspection target (the turbine blade in FIG. 10) displayed on the screen.

  On the screen 4a of the LCD 4, the live image and the recording folder name of the image are displayed. After the power is turned on, “ENGINE1_SN001 ¥” under “root” is displayed on the screen 4a as the recording destination folder.

  In the screen 52 of FIG. 10, information “ENGINE1_SN001 ¥” indicating that the recording destination folder is the folder “ENGINE1_SN001” is displayed on the upper left of the screen 4a. The position of may not be the upper left of the screen, for example, the upper right.

  Furthermore, in the case of FIG. 10, the mark “¥” is added to the folder name of the recording destination folder on the screen 52 as information indicating the recording destination folder, but the mark “¥” may not be present.

  Further, in the case of FIG. 10, the information indicating the recording destination folder is information including the folder name of the recording destination folder, but it is sufficient that the user can recognize and determine the recording destination folder. Therefore, the information indicating the recording destination folder may not include all the folder names of the recording destination folder, and may include, for example, only the folder name of the currently selected hierarchy.

  When the user wants to record a still image in a desired folder generated in advance, the user can select the folder while the live image is displayed on the LCD 4 by operating the joystick 5b. When the joystick 5b is tilted in any of the upper (U), lower (D), left (L), and right (R) directions, a plurality of folders having a hierarchical structure are selected according to the direction. A folder is selected and set as a recording folder.

  FIG. 10 shows transition of a screen when three folders are created under the folder “ENGINE1_SN001” as shown in FIG. 9 and a recording destination folder is selected from these folders. The display order of the recording destination folders in each hierarchy is set in advance so as to be performed in a predetermined order such as the folder creation date and time and the alphabetical order of folder names.

  As shown in FIG. 10, when the joystick 5b is tilted downward (that is, tilted in the D direction) from the state of the screen 52, the screen does not transition because there is no other folder in the same hierarchy.

  Even if the joystick 5b is tilted upward (that is, tilted in the U direction) in the state of the screen 52, the screen does not transition because there is no other folder in the same hierarchy.

  In addition, when the joystick 5b is tilted to the right (that is, tilted in the R direction) in the state of the screen 52, the folder “HPC_STAGE1_ZONE1_1” which is the first folder in the lower hierarchy (the top folder in FIG. 9) is displayed. The screen is changed from the screen 52 to the screen 54.

  Furthermore, when the joystick 5b is tilted to the left (that is, tilted in the L direction) in the state of the screen 54, the folder “ENGINE1_SN001”, which is an upper layer folder, is selected as the recording destination folder, and the screen Transition from 54 to screen 52.

  When the joystick 5b is tilted downward (that is, tilted in the D direction) from the state of the screen 54, the folder “HPC_STAGE1_ZONE1_2”, which is the next folder in the same hierarchy, is selected as the recording destination folder. To the screen 55.

  When the joystick 5b is tilted upward (that is, tilted in the U direction) in the state of the screen 55, the previous folder “HPC_STAGE1_ZONE1_1” in the same hierarchy is selected as the recording destination folder. To the screen 54.

  When the joystick 5b is tilted downward (that is, tilted in the D direction) from the state of the screen 55, the next folder “HPC_STAGE1_ZONE2_1” in the same hierarchy is selected as the recording destination folder. To transition to the screen 56.

  In addition, when the joystick 5b is tilted up in the state of the screen 54 (that is, tilted in the U direction), the folder “HPC_STAGE1_ZONE2_1” which is the last folder in the same hierarchy is selected as the recording destination folder. Transition from screen 54 to screen 56.

  In addition, when the joystick 5b is tilted downward (that is, tilted in the D direction) in the state of the screen 56, the folder “HPC_STAGE1_ZONE1_1” that is the first folder in the same hierarchy is selected as the recording destination folder. The screen transitions from the screen 56 to the screen 54.

  Furthermore, when the joystick 5b is tilted to the left (that is, tilted in the L direction) in the state of the screen 55 or 56, the folder “ENGINE1_SN001” that is the upper hierarchy folder is selected as the recording destination folder, and the screen , Transition from the screen 55 or 56 to the screen 52.

  Therefore, the user can check the recording destination folder while viewing the live image, and can easily change the recording destination folder. As described above, the LCD 4 constitutes a display unit that displays one folder from a plurality of folders in the endoscopic examination mode. The joystick 5b constitutes an operation unit that changes one folder displayed on the LCD 4 as a display unit to another folder in the endoscopic examination mode.

  In the case of FIG. 10, after the transition from the screen 55 or 56 to the screen 52, when the joystick 5b is tilted to the right (that is, tilted in the R direction) in the state of the screen 52, the first folder in the lower hierarchy is used. The screen transitions from the screen 52 to the screen 54 so that a folder “HPC_STAGE1_ZONE1_1” is selected as the recording destination folder. However, after the transition from the screen 55 or 56 to the screen 52, when the joystick 5b is tilted to the right (that is, tilted in the R direction) in the state of the screen 52, as shown by the dotted line DL1 in FIG. 55 or 56 may be displayed. For this purpose, the CPU 21 controls the screen display so that the folder data of the transition screen is stored in the RAM 23 and the previous folder that has transitioned is displayed.

  In the present embodiment, only the folder name of the currently selected hierarchy is displayed on the screen. For example, when the CPU 21 displays the folder name of the lower hierarchy, the folder name of the upper hierarchy of the folder is combined. You may make it display (namely, display a folder path name). At this time, for example, the folder name (folder path name) on the screen 54 is “ENGINE1_SN001 \ HPC_STAGE1_ZONE1_1”.

(Highlighting)
Next, processing for highlighting the folder name when there is no inspection image in the recording destination folder will be described. FIG. 11 is a diagram for explaining an example of highlighting.

  When the power of the endoscope apparatus 1 is turned on, a live image of a target imaged by the imaging unit 41 is usually displayed on the screen 4a of the LCD 4. A recording destination folder display area 60 for displaying a recording destination folder is provided on the screen 4a of the LCD 4, for example, at the upper left of the screen. While the main unit 2 is displaying live images, the folder name is displayed in the recording destination folder display area 60 provided at the upper left of the screen. In the recording destination folder display area 60, the folder path name may be displayed without being limited to the folder name.

  At this time, the CPU 21 checks the files in the folder displayed in the recording destination folder display area 60, and if no image file exists, displays the folder name in a display format different from the normal display. The display format different from the normal display, that is, the highlight display is, for example, a display format in which the folder name is red, bold, italic, underline, blinking, or a combination thereof. The example of FIG. 11 shows a case where no image file exists in the folder “HPC_STAGE1_ZONE1_1”, and the folder name is displayed in italics.

  Thereby, the examiner can recognize that there is no image file in the folder because the display of the folder name is different from the normal display. If the display format can be arbitrarily changed, the inspector can select a display format that is easy to recognize.

(Recording folder change processing and highlight processing)
Next, the recording destination folder changing process and the highlighting process described above will be described. 12, 13, and 14 are flowcharts illustrating an example of the flow of the recording destination folder changing process and the highlighting process.

  First, when the power of the endoscope apparatus 1 is turned on, the CPU 21 sets the “ENGINE1_SN001” folder, which is a higher-level folder, as a recording destination folder after executing various initial processes (S21). The setting data is stored, for example, in a predetermined storage area of the RAM 23 as setting data of a recording destination folder in the image recording process of the endoscope apparatus 1.

  Thereafter, the CPU 21 displays the live image and the recording destination folder name on the screen 4a of the LCD 4 as shown in the screen 52 of FIG. 10 based on the imaging signal from the imaging unit 41 (S22). The processing of S22 constitutes a recording folder information display unit that displays information indicating the recording folder while the endoscopic image is displayed on the display unit.

  Next, the CPU 21 determines whether or not the joystick 5b is tilted in the right (R) direction (S23). When the joystick 5b is tilted in the right (R) direction (S23: YES), the current recording is performed. It is determined whether there is a lower folder in the destination folder (S24).

  If there is no lower folder (S24: NO), the process proceeds to S29. If there is a lower folder (S24: YES), the CPU 21 sets the first folder of the lower folder as the recording destination folder and changes the display of the recording destination folder name on the screen 4a (S25). Since the information of the recording destination folder is stored in the predetermined storage area of the RAM 23 as described above, the data in the predetermined storage area is rewritten with the data of the set folder, that is, the changed folder.

  For example, when the “ENGINE1_SN001” folder is the recording destination folder (screen 52) and the joystick 5b is tilted to the right (R), the “HPC_STAGE1_ZONE1_1” folder, which is the first folder in the lower hierarchy, is recorded. Set as the destination folder. That is, the screen changes from the screen 52 to the screen 54.

  Next, the CPU 21 determines whether there is an image file in the set recording destination folder (S26). If there is an image file in the set recording destination folder (S26: YES), the CPU 21 normally displays the recording destination folder name (S27), and the process proceeds to S29. When there is no image file in the set recording destination folder (S26: NO), the CPU 21 highlights the recording destination folder name (S28), and the process proceeds to S29.

  If NO in S23 or NO in S24, after the processes of S27 and S28, the CPU 21 determines whether or not the joystick 5b is tilted left (L) (S29), and the joystick 5b is left (L ) When tilted in the direction (S29: YES), it is determined whether or not there is an upper folder of the current recording destination folder (S30).

  If there is no upper folder (S30: NO), the process proceeds to S35. If there is an upper folder of the current recording destination folder (S30: YES), the CPU 21 sets the upper folder as the recording destination folder and changes the display of the recording destination folder name on the screen 4a (S31).

  Since there is no upper folder in the “ENGINE1_SN001” folder, the CPU 21 determines that there is no upper folder even if the joystick 5b is tilted left (L) in the state of the screen 52 (S30: NO). Therefore, in this case, the screen 52 does not change.

  Next, the CPU 21 determines whether or not there is an image file in the set recording destination folder (S32). If there is an image file in the set recording destination folder (S32: YES), the CPU 21 normally displays the recording destination folder name (S33), and the process proceeds to S35. When there is no image file in the set recording destination folder (S32: NO), the CPU 21 highlights the recording destination folder name (S34), and the process proceeds to S35.

  If NO in S29 or NO in S30, after the processing of S33 and S34, the CPU 21 determines whether or not the joystick 5b is tilted downward (D) (S35), and the joystick 5b is lowered (D When it is tilted in the direction (S35: YES), it is determined whether there is a folder at the same level as the current recording destination folder (S36).

  If there is no folder at the same level (S36: NO), the process proceeds to S41. If there is a folder at the same level as the current recording destination folder (S36: YES), the CPU 21 sets the next folder at the same level as the recording destination folder and changes the display of the recording destination folder name on the screen 4a. (S37).

  For example, when the joystick 5b is tilted downward (D) in the state of the screen 54 in which the “HPC_STAGE1_ZONE1_1” folder is set as the recording destination folder, the screen displays the “HPC_STAGE1_ZONE1_2” folder from the screen 54. Transition to the screen 55 to be set. further. When the joystick 5b is tilted downward (D) in the state of the screen 55, the screen transits from the screen 55 to the screen 56 for setting the “HPC_STAGE1_ZONE2_1” folder as the recording destination folder. further. When the joystick 5b is tilted downward (D) in the state of the screen 56, since there is no next folder in the same hierarchy, the first folder “HPC_STAGE1_ZONE1_1” in the same hierarchy is set as the recording destination folder. . That is, the screen transitions from the screen 56 to 54.

  Next, the CPU 21 determines whether there is an image file in the set recording destination folder (S38). If there is an image file in the set recording destination folder (S38: YES), the CPU 21 normally displays the recording destination folder name (S39), and the process proceeds to S41. When there is no image file in the set recording destination folder (S38: NO), the CPU 21 highlights the recording destination folder name (S39), and the process proceeds to S41 in FIG.

  If NO in S35 or NO in S36, after the processes of S39 and S40, the CPU 21 determines whether or not the joystick 5b is tilted upward (U) (S41), and the joystick 5b is upward (U When it is tilted in the direction (S41: YES), it is determined whether there is a folder at the same level as the current recording destination folder (S42).

  If there is no folder at the same level (S42: NO), the process proceeds to S51. If there is a folder at the same level as the current recording destination folder (S42: YES), the CPU 21 sets the previous folder at the same level as the recording destination folder and changes the display of the recording destination folder name on the screen 4a. (S43).

  For example, when the joystick 5b is tilted upward (U) in the state of the screen 55 in which the “HPC_STAGE1_ZONE1_2” folder is set as the recording destination folder, the screen displays the “HPC_STAGE1_ZONE1_1” folder from the screen 55. Transition to the screen 54 to be set. further. When the joystick 5b is tilted upward (U) in the state of the screen 54, since there is no previous folder in the same hierarchy, the “HPC_STAGE1_ZONE2_1” folder, which is the last folder in the same hierarchy, is set as the recording destination folder. . That is, the screen transitions from the screen 54 to 56.

  Next, the CPU 21 determines whether or not there is an image file in the set recording destination folder (S44). If there is an image file in the set recording destination folder (S44: YES), the CPU 21 normally displays the recording destination folder name (S45), and the process proceeds to S51. When there is no image file in the set recording destination folder (S44: NO), the CPU 21 highlights the recording destination folder name (S46), and the process proceeds to S51.

  The processes in S23 to S25, S29 to S31, S35 to S37, and S41 to S43 constitute a recording destination folder changing unit that changes the recording destination folder in accordance with the operation of the operation unit 5. Specifically, the processing of S23 to S25, S29 to S31, S35 to S37, and S41 to S43 constitutes a recording destination folder changing unit that changes the recording destination folder while a live image is displayed.

  Further, in the processes of S26 to S28, S32 to S34, S38 to S40, and S44 to S46, one folder among the plurality of generated folders is displayed as a folder for recording a plurality of image data on the live image. At this time, a display control unit is configured to change the display format of the folder name of the displayed folder based on whether or not image data is recorded in the displayed folder.

  Returning to FIG. 13, in the case of NO in S41 and in the case of NO in S42, after the processing of S45 and S46, the CPU 21 determines whether or not the freeze button has been pressed (S51 in FIG. 14).

  When the freeze button is not pressed (S51: NO), the process returns to S22. When the freeze button is pressed (S51: YES), the CPU 21 determines whether or not the REC button is pressed (S52). The REC button is a button for giving an instruction to record a frozen image on a recording medium. When the freeze button is pressed, the CPU 21 generates a still image based on the imaging signal from the imaging unit 41 and displays it on the LCD 4.

  In addition, when the freeze button is pressed in S51, the recording destination folder is changed in the frozen state of the live image, and the display format of the recording destination folder is similar to S23 to S46 in the state where the live image is displayed. It is good also as a structure which can be changed.

  If the REC button is not pressed, the process returns to S51 to determine whether the freeze state continues, in other words, whether the freeze state has not been released. If the freeze state is released (S51: NO), the process returns to S22.

  When the REC button is pressed (S52: YES), the CPU 21 displays a predetermined confirmation message as shown in FIG. 15 on the screen 4a (S53).

  FIG. 15 is a diagram illustrating a display example of a confirmation message. A still image due to freeze is displayed on the screen 4a of the LCD 4, and a predetermined confirmation message is displayed on the screen by a window 61. FIG. 15 is a display example when the REC button is pressed in the display state of the screen 54 and is recorded in ““ HPC_STAGE1_ZONE1_1 ”. Is displayed in the window 61.

  Further, the window 61 includes an “OK” button 63 and a “Cancel” button 64. The user can select the “OK” button 63 or the “Cancel” button 64 by performing a predetermined operation on the operation unit 5. In FIG. 15, since the “OK” button 63 is selected as a default, the “OK” button 63 is displayed more emphasized than the “Cancel” button 64.

  The user selects the “OK” button 63 when recording the still image obtained by freezing in the folder indicated in the confirmation message. On the other hand, the user selects the “Cancel” button 64 when recording the still image obtained by freezing in a folder other than the folder indicated in the confirmation message.

  After S53, the CPU 21 determines whether or not the “OK” button 63 is pressed. If the “OK” button 63 is not pressed, that is, if the “Cancel” button 64 is pressed (S54: NO), the CPU 21 Deletes the window 61 from the screen 4a, and the process proceeds to S55.

  On the screen 4a, a still image due to freezing and a currently set recording destination folder name are displayed. The user can change the recording destination folder by operating the joystick 5b in the screen display state.

  FIG. 16 is a diagram illustrating an example of a screen when a recording destination folder is displayed in a state where a still image is displayed. When the joystick 5b is operated in a state where the still image displayed by freezing is displayed, the recording destination folder is changed according to the operation. In the screen 4a, only the folder name displayed in the recording destination folder display area 60 for displaying the recording destination folder changes according to the operation of the joystick 5b. Therefore, the user can change the recording destination folder by operating the joystick 5b to display the desired recording destination folder name in the recording destination folder display area 60.

  At this time, in the process of S55, as in the processes of S26 to S28, S32 to S34, S38 to S40 and S44 to S46, it is determined whether there is an image file in the changed recording destination folder, and the determination result The display format of the folder name of the recording destination folder changed according to is changed (normal display or highlighted display).

  The process of S55 constitutes a recording destination folder changing unit that changes the recording destination folder according to the operation of the operation unit 5, and information indicating the recording destination folder in a state where the endoscope image is displayed on the LCD 4. Is configured as a recording destination folder information display unit.

  In particular, the process of S55 constitutes a recording destination folder changing unit that can change the recording destination folder while the endoscopic image is displayed on the LCD 4.

  As described above, in the case of NO in S54, the CPU 21 changes the recording destination folder as shown in FIG. 10 according to the tilting operation of the joystick 5b in the up / down / left / right directions, and the user selects the desired recording destination folder. And the display of the recording folder name on the screen 4a is changed (S55).

  The CPU 21 determines whether or not the REC button has been pressed again with the recording destination folder changed (S56). If the REC button is not pressed (S56: NO), the process returns to S55.

  When the REC button is pressed in S56 (S56: YES), the process proceeds to S53, and the CPU 21 displays a predetermined message for confirming the recording destination folder (S53).

  When the recording destination folder is confirmed (S54: YES), a file mark setting process is performed (S57). The file mark is a predetermined mark that functions as an identification symbol added to the recorded file name.

  The file mark is arbitrarily added by the user in order to indicate what kind of image the recorded image is. For example, in order to divide images into the types of “No problem (Accept)”, “Reject”, “Repair”, “Re-Inspect”, A file mark is added. That is, the file mark is examination result information that is given to an endoscopic image by a user who is an examiner looking at the endoscopic image. Furthermore, there is a “no” type. “None” means no file mark (that is, no file mark is attached). Therefore, the addition of the file mark is arbitrary by the user.

  Thereafter, the CPU 21 records an image in the selected or set recording destination folder (S58). In S58, an endoscopic image is recorded in a recording destination folder set as an endoscopic image recording destination from among a plurality of folders created in advance in the memory card 11. In other words, the process of S58 is a folder generation for each image data to be inspected obtained by the imaging unit 41 that is an imaging unit in the endoscopic inspection mode for recording a plurality of image data to be inspected. The inspection image recording unit records in one folder among the plurality of folders generated by the unit.

  Furthermore, in S58, the file mark set in S57 is added to the file name of the endoscopic image, and the endoscopic image is recorded in the recording destination folder.

  Then, the CPU 21 determines whether or not an end instruction has been given (S59). When an end instruction has been given (S59: YES), the process ends, and when no end instruction has been given (S59: NO), the process Shifts to S22.

  In the above-described embodiment, the joystick is an operation unit that can be operated in the first direction in the left-right direction and the second direction in the up-down direction perpendicular to the left-right direction. The recording destination folder is changed by moving up and down the hierarchical structure according to the operation in the horizontal direction, and the recording destination folder is changed by moving within the same hierarchy in the hierarchical structure according to the operation in the vertical direction. Therefore, the user can perform screen transition by operating the joystick corresponding to the image of the hierarchical structure of the folder, so that the operability is good.

  Furthermore, the operation unit for changing the recording destination folder may be a so-called cross key, up / down / left / right key, a button to which a function is assigned when the folder is changed, instead of the joystick. Furthermore, the operation unit may be a cross key generated by software, an up / down / left / right key or the like displayed on the screen.

  In the above-described embodiment, the joystick 5b is a dedicated joystick for changing or selecting the recording folder, but the up / down / left / right (U / D / L / R) direction bending button 5a used for the bending operation. May be used as an operating device for selecting a recording destination folder under mode switching.

  Furthermore, in the above-described embodiment, the information indicating the recording destination folder is displayed when the live image is displayed. However, the information indicating the recording destination folder is displayed only when the freeze button is pressed. You may make it display.

  As shown in FIG. 10, the user can confirm the recording destination folder when recording the endoscopic image, and can easily change the recording destination folder.

  Furthermore, the folder name is displayed on the screen shown in FIG. 10, FIG. 15, FIG. 16, or the like. In this embodiment, the character string for inspection in the folder name is a number, so that the user can You may want to confirm what the numbers mean. Therefore, for example, when the user places the cursor on a character string indicating the purpose of inspection or performs a predetermined operation in the screen display state shown in FIG. 10 or the like, the contents indicated by the numbers are displayed in the window. May be. For example, in FIG. 15, when the cursor is moved to the lowest position “1” of the folder name “HPC_STAGE1_ZONE1_1”, a character string “Cracks” is displayed. Therefore, the user who is an inspector can easily confirm the current inspection purpose or can confirm whether the storage folder is the correct storage folder.

  As described above, according to the present embodiment, an endoscopic image obtained by imaging in an endoscopic examination in accordance with an inspection object from a code such as a QR code (registered trademark) attached to the inspection object. A plurality of appropriate folders for storing the files can be appropriately generated. When a live image is displayed, if no image file is recorded in the generated folder, the display format of the folder name of the folder can be changed.

  Therefore, according to the endoscope apparatus of the present embodiment, it is possible to notify whether or not there is an inspection image in the folder that stores the inspection image.

(Modification 1)
When displaying the folder name of the recording folder in the recording folder display area 60 of the screen 4a, the CPU 21 searches the number of image files recorded in the folder and displays the number of image files together with the folder name. To do.

  17 and 18 are diagrams for explaining an example of a screen when displaying the number of image files according to the folder name.

  When displaying the folder name “HPC_STAGE1_ZONE1_1” in the recording destination folder display area 60, the CPU 21 searches for the number of image files recorded in the folder. If, for example, three image files are recorded in the folder “HPC_STAGE1_ZONE1_1”, the CPU 21 matches the folder name “HPC_STAGE1_ZONE1_1” with the number of recorded image files “(3 images) as shown in FIG. ) ”Is displayed in the recording folder display area 60.

  On the other hand, when the image file is not recorded in the folder “HPC_STAGE1_ZONE1_1”, the CPU 21 matches the folder name “HPC_STAGE1_ZONE1_1” as shown in FIG. None) ”is displayed in the recording folder display area 60. Note that if no image file is recorded, the CPU 21 may display “(0 sheets)” instead of “(no image)”. Thereby, the user can easily recognize that there is no image file in the folder.

  Further, the CPU 21 displays the number of necessary acquired image files in the recording destination folder display area 60, and displays or records the difference information between the number of recorded image files and the number of necessary acquired image files. The number of image files and the number of necessary acquired image files may be displayed in the form of fractions.

  FIG. 19 is a diagram for explaining an example of a screen when displaying the number of image files recorded according to the folder name and the number of necessary acquired image files in a fractional form.

  For example, if the number of necessary acquired image files in the folder “HPC_STAGE1_ZONE1_1” is five and currently three image files are recorded in the folder “HPC_STAGE1_ZONE1_1”, the CPU 21 may have the following as shown in FIG. In accordance with the folder name “HPC_STAGE1_ZONE1_1”, “(3/5)”, which is a fraction of the number of recorded image files and the number of required acquired image files, is displayed in the recording destination folder display area 60. The information on the number of required image files to be acquired is acquired by having each folder or parent folder have an environment file in advance, and the CPU 21 refers to the environment file.

  In this way, by displaying the number of recorded image files and the number of required acquired image files in a fractional form, for example, an inspection omission that only three images are recorded even though five image files are necessary is required. Can be prevented.

  Further, when no image file is recorded in the recording destination folder, the CPU 21 displays a window (pop-up window) indicating that no image file is recorded in the folder.

  FIG. 20 is a diagram for explaining an example of a screen when a window indicating that no image file is recorded in the recording destination folder is displayed.

  For example, if no image file is recorded in the folder “HPC_STAGE1_ZONE1_1”, the CPU 21 displays a window 65 on the screen 4a as shown in FIG. In this window 65, a message indicating that “HPC_STAGE1_ZONE1_1” is an imageless folder is displayed. Thereby, the user can easily recognize that there is no image file in the folder. When no image file is recorded in the lower folder of “HPC_STAGE1_ZONE1_1”, the CPU 21 may display the folder name of the lower folder in which no image file is recorded in the window 65.

(Modification 2)
When the user selects a menu for displaying a list of folder trees using the operation unit 5 or presses a predetermined button (not shown) provided on the operation unit 5, the CPU 21 responds to the user's instruction to display the folder tree. Is displayed on the LCD4 screen.

  FIG. 21 is a diagram for explaining an example of a screen when a list of folder trees is displayed.

  When the user selects, for example, a folder tree list display menu, the CPU 21 displays the folder tree list shown in FIG. 21. When displaying the folder tree list, the folder in which no image file is recorded is displayed. Search for. Then, the CPU 21 displays the folder name of the folder in which no image file is recorded in a display format different from normal. Note that when there are a plurality of folders in which no image file is recorded, the CPU 21 displays all the folder names in a display format different from the normal one. The display format different from the normal display, that is, the highlight display is the same as that of the above-described embodiment. For example, the folder name is displayed in red, bold, italic, underline, blinking, or a combination thereof. .

  FIG. 21 is an example in which no image file is recorded in the folder “HPC_STAGE1_ZONE1_2”, and the folder name “HPC_STAGE1_ZONE1_2” indicated by a dashed dotted line 70 is shown in italics.

  As described above, the CPU 21 displays a list of folder trees in accordance with the user's instruction, so that the user can recognize a folder in which no image file is recorded in the entire structure of the folder tree. It becomes easier to grasp the overall situation, such as whether the position (or part) is being inspected.

  The list display of the folder tree is not limited to being displayed according to the user's instruction, and may be automatically displayed when the main unit 2 is turned on, for example. Thus, the user can recognize how far the previous inspection has been completed, where the inspection is started (restarted), or a folder in which there is an inspection failure (that is, a folder in which no image is stored). .

  The list display of the folder tree may be automatically displayed when the power of the main body 2 is shut off or when the memory card 11 is removed from the main body 2. Thereby, the user can recognize a folder having an omission of inspection (that is, a folder in which no image is stored) before ending the inspection. If the folder tree list display is automatically displayed when the main unit 2 is turned on or off, the folder tree list may not be displayed according to user settings.

  Furthermore, the present invention is not limited to changing the display format of the folder name of a folder in which no image file is recorded. For example, as in the first modification, the number of recorded image files, the difference information between the number of recorded image files and the number of necessary acquired image files, or the number of recorded image files in accordance with the folder name And the necessary number of acquired image files may be displayed in a fractional form. In this case, for example, a folder icon is displayed in the list of the folder tree, and a numerical value such as the number of image files is displayed in the folder icon.

  FIG. 22 is a diagram for explaining an example of a screen when a folder icon is displayed in the folder tree list.

  As illustrated in FIG. 22, the CPU 21 displays folder icons 71a, 71b, 71c, and 71d before the folder names “ENGINE1_SN001”, “HPC_STAGE1_ZONE1_1”, “HPC_STAGE1_ZONE1_2”, and “HPC_STAGE1_ZONE2_1”. Then, the CPU 21 displays numerical values such as the number of image files recorded in each folder on the folder icons 71a to 71d. Although no numerical value is displayed on the folder icon 71a, for example, a numerical value such as the number of image files recorded in a lower folder may be displayed.

  The folder icon 71b is an example in which the number of recorded image files is displayed, and indicates that three image files are recorded in the folder “HPC_STAGE1_ZONE1_1”. The folder icon 71c is an example in which the number of recorded image files and the required number of acquired image files are displayed in the form of fractions. The number of image files recorded in the folder “HPC_STAGE1_ZONE1_2” is This indicates that the number of required image files is five.

  Furthermore, the folder icon 71d is an example in which difference information between the number of recorded image files and the number of necessary acquired image files is displayed. The number of image files recorded in the folder “HPC_STAGE1_ZONE2_1” and the necessary acquired images The difference from the number of files is −2 and the number of necessary image files to be acquired is five. That is, the number of image files recorded in the folder “HPC_STAGE1_ZONE2_1” is 3, and the number of necessary acquired image files is 5.

  Thereby, the user can easily recognize that there is no inspection or no image file in the folder in the entire configuration of the folder tree.

(Modification 3)
When the user selects a menu for displaying a list of folders without image files using the operation unit 5 or presses a predetermined button (not shown) provided on the operation unit 5, the CPU 21 responds to the user's instruction. A list of folders without image files is displayed on the LCD4 screen.

  FIG. 23 is a diagram for explaining an example of a screen when a list of folders without image files is displayed.

  When the user selects, for example, a list display of a folder without an image file by the user, the CPU 21 searches for a folder in which no image file is recorded, and as shown in FIG. 23, a folder in which no image file is recorded (image The folder names of “fileless folder” are listed, and a list of the folder names is displayed in the window 81.

  In addition, a window 81 that displays a list of folder names of folders in which no image file is recorded is provided with a folder selection unit 82 for selecting a folder. The folder selection unit 82 can be moved by operating the operation unit 5. FIG. 23 shows a state where the folder “HPC_STAGE1_ZONE1_2” is selected. When the user presses a button (not shown) of the operation unit 5 in this state, the user can directly move to the selected folder. That is, an image can be recorded in the selected folder.

  Thus, displaying only the folder names of folders in which no image files are recorded in a list by the window 81 is effective when the user wants to check only folders in which no image files are recorded. That is, in the list of folder trees (FIGS. 22 and 23) of the second modification, when the folder tree is complicated and difficult to display, for example, the entire folder tree may not be displayed unless the screen is scrolled. On the other hand, in the third modification, the user can easily recognize only the folder in which no image file is recorded.

  Even when an image file is recorded in the folder, there may be a folder that has not yet been inspected before the required number of acquired image files. Therefore, the CPU 21 may display a list of unfinished folders instead of the list of folders without image files.

  FIG. 24 is a diagram for explaining an example of a screen when a list of incomplete examination folders is displayed.

  When the user selects, for example, a menu for displaying a list of unfinished folders, the CPU 21 searches for unfinished folders whose number of recorded image files has not reached the required number of acquired image files, and is shown in FIG. In this way, the folder names of folders that have not been inspected (inspection incomplete folders) are listed, and a list of the folder names is displayed in the window 83. At this time, the CPU 21 displays the number of recorded image files and the number of necessary acquired image files in the form of fractions in accordance with the unfinished folder. As described above, difference information between the number of recorded image files and the number of necessary acquired image files may be displayed.

  For example, one image file is recorded in the folder “HPC_STAGE1_ZONE3_1”, indicating that the required number of acquired image files is three. The user can directly move to the folder by selecting the folder “HPC_STAGE1_ZONE3_1” in the folder selection unit 82. Then, the user can complete the inspection at the inspection position corresponding to the folder by recording the two image files that are insufficient in the necessary number of acquired image files.

  As in the above-described second modification, when the main unit 2 is turned on or off, the window 81 that is a list of folders without image files or the window 83 that is a list of unfinished folders is automatically displayed on the LCD 4 screen. May be displayed. Thus, the user can recognize how far the previous inspection has been completed, where the inspection is to be started (restarted), or a folder or the like that has an inspection failure before the inspection is ended.

  As described above, according to the embodiment and the modification described above, whether there is an inspection image in the folder in which the inspection image is stored, or whether the number of inspection images has reached the required number of inspection images. It is possible to reliably notify the user of whether or not, and to prevent an inspection omission.

  It should be noted that each step of each procedure in the present embodiment may be executed in a different order for each execution by changing the execution order and executing a plurality of steps at the same time, as long as it does not contradict its nature.

  The present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Endoscope apparatus, 2 ... Main-body part, 3 ... Scope unit, 4 ... LCD, 5 ... Operation part, 5a ... Up / down / left / right (U / D / L / R) direction bending button, 5b ... Joystick, 6 ... Universal Cable, 7 ... Insertion part, 8 ... Tip part, 9 ... Bending part, 10 ... Optical adapter, 11 ... Memory card, 21 ... CPU, 22 ... ROM, 23 ... RAM, 24 ... Bus, 25-31 ... Interface, 34 ... battery, 41 ... imaging unit, 42 ... LED, 43 ... PC, 43a ... CPU, 44 ... monitor.

Claims (8)

An imaging unit;
In the first mode for extracting folder generation information relating to generation of a plurality of folders for recording a plurality of image data to be inspected, the folder generation information is analyzed by analyzing an image captured by the imaging unit An analysis unit for extracting
A folder generation unit that generates the plurality of folders for the inspection target based on the folder generation information extracted in the analysis unit;
In a second mode for recording the plurality of image data to be inspected, one folder among the plurality of folders generated by the folder generation unit is transferred to the plurality of image data on a live image. When displaying as a recording folder, the image data in the displayed folder is confirmed, and the display is performed based on whether the image data is recorded in the displayed folder. A display control unit for changing the display format of the folder name of the folder;
An endoscope apparatus characterized by comprising:   The endoscope according to claim 1, wherein the display control unit highlights a folder name of the displayed folder when the image data is not recorded in the displayed folder. apparatus. The said display control part displays the number of the said image data currently recorded on the said folder displayed according to the folder name of the said folder displayed. endoscopic equipment. The display control unit retrieves the number of the image data recorded in the folder being displayed, and displays the number of the image data together with a folder name of the folder being displayed. The endoscope apparatus according to claim 1. The display control unit displays the difference or fraction between the number of the image data to be recorded in the folder being displayed and the number of the image data recorded in the folder being displayed. The endoscope apparatus according to claim 1, wherein the endoscope apparatus is displayed in accordance with a folder name of the existing folder . The display control unit displays a folder tree of the plurality of folders according to a predetermined operation, and based on whether the image data is recorded in each of the plurality of folders, the folder tree The endoscope apparatus according to claim 1, wherein the display format of the folder names of the plurality of folders displayed in (1) is changed . The endoscope apparatus according to claim 1, wherein the display control unit displays a list of folders in which the image data is not recorded among the plurality of folders according to a predetermined operation. In the first mode for extracting folder generation information relating to generation of a plurality of folders for recording a plurality of image data to be inspected, an image obtained by imaging by the imaging unit of the endoscope apparatus is analyzed, Extracting the folder generation information;
Generating the plurality of folders for the inspection object based on the extracted folder generation information;
In the second mode for recording the plurality of image data to be inspected, one folder among the plurality of generated folders is displayed as a folder for recording the plurality of image data on a live image. When checking, the image data in the displayed folder is confirmed, and the folder name of the displayed folder is determined based on whether the image data is recorded in the displayed folder. Changing the display format,
For displaying an endoscope image recording folder including

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