JP2014109630A - Endoscope device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an endoscope device which is capable of quickly and easily moving an arbitrary position in an endoscope image to the almost center part of a screen.SOLUTION: An endoscope device 1 comprises: a curved part 2b provided in an insertion part 2; a display unit 31 displaying the endoscope image; a touch panel 32; a curved part driving part 37 driving the curved part 2b, to make the curved part 2b into a curved state with an instructed curvature angle; and a CPU 41. The CPU 41 decides the curvature angles in a vertical direction and in a lateral direction of the curved part 2b from touch position information on the screen detected by the touch panel 32, based on first relationship information between a position in the vertical direction on the screen of the display unit 31 and the curvature angle in the vertical direction of the curved part 2b and second relationship information between the position in the lateral direction on the screen and the curvature angle in the lateral direction of the curved part 2b, to control the curved part driving part 37.

Description

  The present invention relates to an endoscope apparatus, and more particularly, to an endoscope apparatus that performs bending of an insertion portion using a touch panel.

  Conventionally, endoscope apparatuses have been widely used in the industrial field and the medical field. The endoscope insertion portion is inserted into the inspection target, and an image of the inspection site obtained at the distal end portion of the insertion portion is displayed on the display device, so that the inspector can perform the inspection within the inspection target.

  A bending portion is provided on the distal end side of the insertion portion, and the inspector operates the bending operation member such as a joystick of the operation portion and directs the distal end of the insertion portion in a desired direction so as to observe the inside of the inspection object in detail. can do.

  For example, when inspecting piping in the industrial field, inspection is performed while looking at the endoscope image while pushing the insertion portion into the piping, but if a corroded portion is found in the piping during the inspection, In order to observe the corroded portion in detail, the person operates the joystick to bend the curved portion so that the corroded portion is largely reflected in the endoscopic image.

  Also, for example, Japanese Patent Application Laid-Open No. 2005-52635 discloses an endoscope apparatus that uses a joystick or a touch panel as a bending operation device for a bending operation. The disclosed touch panel functions as eight direction instruction units, and is configured to indicate the bending direction of the bending unit.

JP 2005-52635 A

  However, in the case of a joystick, the bending portion can be bent in the direction of the observation site by tilting the joystick, but the direction in which the joystick is tilted is the direction in which the examiner pushes with a finger while viewing the endoscopic image Therefore, the direction is a general direction where the part to be observed exists, and it is easy for the operator to tilt the joystick so that the part to be observed moves toward the center of the screen without wasteful movement. is not.

  For example, the inspector may have to correct the direction in which the joystick is tilted if the bending direction deviates from the direction in which he wants to move. Also, since the amount of bending is also based on the sensory factors of the operator, the examiner may have to tilt the joystick in the opposite direction if it is bent too much.

  That is, it is not easy for the inspector to specify the direction and amount of bending of the bending portion by operating the joystick so that the part to be observed moves to approximately the center of the screen.

  Further, in the case of the touch panel disclosed in Japanese Patent Application Laid-Open No. 2005-52635 described above, the area that can be specified on the screen can only specify eight divided areas, and the part to be observed is positioned at the approximate center of the screen. In this case, further fine adjustment may be required, and it is not easy to operate so that an arbitrary site to be observed is quickly positioned at the approximate center of the screen.

  Therefore, an object of the present invention is to provide an endoscope apparatus that can quickly and easily move an arbitrary position in an endoscopic image to a substantially central portion of a screen.

  An endoscope apparatus according to an aspect of the present invention includes an insertion portion, a bending portion provided in the insertion portion, and reflected light from a subject obtained through an objective optical system provided at a distal end portion of the insertion portion. A display unit that displays the generated endoscopic image, a touch panel provided on the display unit, and a bending unit drive that drives the bending unit so that the bending unit is in a bending state with an instructed bending angle. , The first relation information of the position of the display unit in the vertical direction on the screen and the bending angle of the bending unit in the vertical direction, the position in the horizontal direction on the screen and the horizontal direction of the bending unit The bending angle in the up-down direction and the bending angle in the left-right direction of the bending portion are determined from touch position information on the screen detected by the touch panel based on the second relation information with the bending angle at Control for controlling the bending portion drive unit so that the bending angle in the up-down direction and the bending angle in the left-right direction of the bending portion are close to the determined bending angle in the up-down direction and the bending angle in the left-right direction, respectively. Part.

  ADVANTAGE OF THE INVENTION According to this invention, the endoscope apparatus which can move the arbitrary positions in an endoscopic image to the approximate center part of a screen rapidly and easily can be provided.

1 is a configuration diagram of an endoscope apparatus according to an embodiment of the present invention. It is a block diagram which shows the structure of the endoscope apparatus 1 concerning embodiment of this invention. It is a flowchart which shows the example of the flow of the bending operation process using the touch-panel function in the endoscope apparatus 1 which concerns on embodiment of this invention. It is a flowchart which shows the example of the flow of the bending operation process using the touch-panel function in the endoscope apparatus 1 which concerns on embodiment of this invention. It is a figure which shows the example of the coordinate curvature angle table TBLx which concerns on embodiment of this invention. It is a figure which shows the example of the coordinate curvature angle table TBLi which concerns on embodiment of this invention. It is a figure when the optical adapter 5 which concerns on embodiment of this invention is seen from the front end side. It is a figure for demonstrating the position on the screen of the display part 2b which concerns on embodiment of this invention. It is a figure which shows the example of the endoscopic image displayed on the screen of the display part 3b based on embodiment of this invention. It is a figure which shows the example of the endoscopic image displayed on the screen of the display part 3b when the site | part AA comes to the approximate center of the screen EI based on embodiment of this invention. It is a figure for demonstrating the example of the icon displayed when it comes to the maximum bending angle based on embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a configuration diagram of an endoscope apparatus according to the present embodiment. The endoscope apparatus 1 includes an insertion portion 2, an operation portion 3 to which a proximal end portion of the insertion portion 2 is connected, and a main body portion 4.

  The insertion part 2 is an elongated flexible member. The insertion portion 2 includes a distal end hard portion 2a, a bending portion 2b, and a flexible tube portion 2c in order from the distal end side. An observation window and an illumination window are provided at the distal end portion of the distal end hard portion 2a, and an objective optical system and an image sensor are disposed on the rear side of the observation window.

  The insertion portion 2 is configured such that the optical adapter 5 can be attached to the distal end portion thereof. There are a plurality of types of optical adapters 5 according to the angle of view of the endoscopic image, and the inspector can replace the optical adapter 5 so that a desired angle of view can be obtained.

  The operation unit 3 includes an operation unit main body 3a and a display unit 3b extending from the operation unit main body 3a. An endoscope image and an operation menu can be displayed on the display unit 3b. The operation unit body 3a is provided with various operation switch groups 3c and a joystick 3d. The various switch group 3c includes a freeze switch, a recording switch, and the like. The joystick 3d has a function as a bending operation device for bending the bending portion 2b of the insertion portion 2, and a function as a selection operation device for selecting an item in a menu displayed on the screen. The inspector instructs the bending portion 2b provided in the insertion portion 2 to bend by tilting the joystick 3d in a desired direction, and directs the distal end portion of the insertion portion 2 in a desired direction or performs a desired selection operation. However, as will be described later, the bending of the bending portion 2b can be instructed by a touch panel operation.

  The main body 4 is connected to the operation unit 3 by a universal cable 6. The main body unit 4 includes a CPU, an image processing unit, and the like, which will be described later, and generates an endoscopic image by processing a video signal from an image sensor provided at the distal end of the insertion unit 2.

  Further, a light emitting element such as an LED is provided as a light source in the optical adapter 5, and the light source is controlled by the main body 4. From FIG. 7, it is emitted as illumination light.

The generated endoscopic image is displayed on the display unit 3b provided in the operation unit 3, and can be recorded in a storage device (not shown in FIG. 1) provided in the main body unit 4.
The display unit 3b has a touch panel function. The examiner can bend the bending portion 2b by operating the joystick 3d, but can perform the bending operation of the bending portion 2b by the touch panel function of the display portion 3b.

The main body unit 4 includes a display unit 4a, and the examiner can display an endoscopic image on the display unit 4a.
Here, the operation unit 3 and the main body 4 are connected by the universal cable 6, but the operation unit 3 and the main body 4 may be integrated.

The configuration of the endoscope apparatus 1 will be described in further detail using FIG. FIG. 2 is a block diagram showing a configuration of the endoscope apparatus 1.
The optical adapter 5 includes an optical lens unit 11, an ID storage unit 12, and an illumination unit 13. The optical lens unit 11 is an optical system that corrects an angle of view when the subject is imaged. The ID storage unit 12 is a non-volatile memory that stores identification information of the optical adapter 5. The illumination unit 13 as a light source is a light emitting element such as an LED.

  The insertion portion 2 includes an imaging element 21 disposed in the distal end hard portion 2a and a bending mechanism 22 disposed in the bending portion 2b. The image sensor 21 is a CCD image sensor, a CMOS image sensor, or the like. The bending mechanism 22 includes a plurality of connected bending pieces, and the distal ends of four bending wires are fixed to the bending piece on the distal end side. Each bending wire is configured such that it can be pulled by a bending portion drive unit 37 described later in the operation unit 3.

  The operation unit 3 includes a display 31, a touch panel 32, an imaging signal processing unit 33, an imaging element driving unit 34, an optical adapter identification unit 35, an illumination unit driving unit 36, a bending unit driving unit 37, and an input unit 38.

The display unit 3b in FIG. 1 is configured by the display 31 and the touch panel 32. The display 31 is a display panel such as a liquid crystal display device. That is, the display 31 constitutes a display unit that displays an endoscopic image generated from the reflected light from the subject obtained through the objective optical system provided at the distal end of the insertion unit 2.
A touch panel 32 provided on the display 31 generates coordinate information of a position touched by the examiner's finger or the like on the screen of the display 31 and outputs the coordinate information to a CPU 41 described later.

The imaging signal processing unit 33 is a processing circuit that receives an imaging signal from the imaging element 21, generates a live video signal from the imaging signal, and outputs the live video signal to the graphic superimposing unit 42.
The image sensor drive unit 34 is a drive circuit that drives the image sensor 21 under the control of the CPU 41 described later.

  The optical adapter identification unit 35 reads the identification information stored in the ID storage unit 12 of the optical adapter 5 attached to the distal end of the insertion unit 2, identifies the type of the optical adapter 5, and the identification information will be described later. It is a circuit that outputs to the CPU 41.

  The illumination unit drive unit 36 is a drive circuit that drives the illumination unit 13 of the optical adapter 5 attached to the distal end portion of the insertion unit 2 under the control of the CPU 41 described later.

  The bending portion drive unit 37 includes a plurality of motors that drive the bending mechanism 22 provided in the bending portion 2b, and is a unit that is controlled by a CPU 41 described later. Each motor is configured to pull the proximal end of each bending wire by the rotation of each motor. Specifically, the plurality of motors pull the proximal end of the bending wire so that the bending portion 2b is bent in the vertical and horizontal directions.

The bending portion drive unit 37 includes an encoder that outputs bending angle information indicating a bending angle corresponding to the pulling amount of the bending wire in each of two directions, ie, an up-down direction and a left-right direction. The bending portion driving unit 37 outputs the bending angle information to the CPU 41. Therefore, the CPU 1 can determine the current bending angle of the bending portion 2 b in the vertical and horizontal directions based on the bending angle information from the bending portion driving unit 37.
That is, the bending portion drive unit 37 configures a bending portion drive unit that drives the bending mechanism 22 of the bending portion 2b so that the bending portion 2b is in a bending state with a bending angle instructed by the CPU 41.

The input unit 38 is an operation member operated by the examiner, and includes the various operation buttons 3c and the joystick 3d described above.
The main body unit 4 includes a CPU 41 that is a central processing unit, a graphic superimposing unit 42, and a memory unit 43.
The CPU 41 is a control unit that controls the entire endoscope apparatus 1. The CPU 41 controls the image sensor drive unit 34 to output a video signal obtained from the image sensor to the display 31 and also controls the illumination drive unit 36 in accordance with an instruction input to the input unit 38. Illumination light is emitted, and the bending portion drive unit 37 is controlled in accordance with a bending instruction signal from the joystick 3d and the touch panel 32 to bend the bending portion 2b.

The graphic superimposing unit 42 is a circuit for superimposing and displaying a graphic display such as a menu display on the endoscopic image displayed on the display 31. Further, the graphic superimposing unit 42 performs image processing such as color space conversion, interlace / progressive conversion, and gamma correction according to the specifications of the display device 31, and outputs the processed image data to the display device 31.
The memory unit 43 is a storage device that stores various programs including a bending control program, which will be described later, and various data. The CPU 41 reads out the program and data corresponding to the instructor's instruction input from the memory unit 43 and executes them. The memory unit 43 includes a table data unit 43a that stores table data to be described later.
(Operation)
Next, the bending operation of the endoscope apparatus 1 will be described. Here, a bending operation by a bending operation instruction on the touch panel 32 will be described.

3 and 4 are flowcharts showing an example of the flow of the bending operation process using the touch panel function in the endoscope apparatus 1 according to the present embodiment.
The processing of FIGS. 3 and 4 is executed by the CPU 41 when the main body 4 is powered on.

  When the power is turned on, the CPU 41 first determines whether or not the optical adapter 5 is attached (S1). This determination can be made by the CPU 41 based on the output of the optical adapter identification unit 35.

When the optical adapter 5 is attached (S1: YES), the CPU 41 determines the type of the optical adapter 5 based on the identification information (S2).
Since the angle of view of the endoscopic image captured by the image sensor 21 varies depending on the type of the optical adapter 5, the CPU 41 corresponds to the type of the identified optical adapter 5 in the two coordinate curve tables TBLx and TBLY. Data is selected (S3).

  5 and 6 show examples of the coordinate curvature tables TBLx and TBLy, FIG. 5 shows an example of the coordinate curvature angle table TBLx, and FIG. 6 shows an example of the coordinate curvature angle table TBLy. is there.

  5 and 6 are table data showing the relationship between the position on the screen of the display unit 3b and the bending angle in accordance with the type of the optical adapter. FIG. 7 is a diagram when the optical adapter 5 is viewed from the distal end side. FIG. 8 is a diagram for explaining the position of the display unit 2b on the screen.

  FIG. 5 is table data showing the relationship between each divided position and the bending angle in the left-right direction when the screen is divided into 512 in the left-right direction. FIG. 6 is table data showing the relationship between each divided position and the bending angle in the vertical direction when the screen is divided into 512 in the vertical direction. That is, the table data in FIG. 5 is the relationship information between the position in the left-right direction on the screen and the bending angle in the left-right direction of the bending portion 2b, with the center of the screen being the bending angle 0, and the table data in FIG. Is the relationship information between the position of the display unit in the vertical direction on the screen and the bending angle of the curved part 2b in the vertical direction. The two table data shown in FIGS. 5 and 6 are stored in the table data section 43a.

  Therefore, the table data unit 43a is associated with the relationship information in FIG. 5 and the relationship information in FIG. 6 for each type of optical adapter 5 that is attached to the distal end of the insertion unit 2 and has an optical lens that changes the angle of view of the endoscopic image. The relationship information storage unit is stored.

  As shown in FIG. 7, four illumination windows 5a are arranged on the distal end surface of the optical adapter 5, and illumination light is emitted from each illumination window 5a. The screen of the display unit 2b is rectangular as shown in FIG. 8, and the rectangular screen is divided into 512 in the vertical and horizontal directions with respect to the center O of the screen.

  For example, the point P1 on the screen EI in FIG. 8 is 128 positions that are half of the maximum 255 in the right direction and upward from the center O of the screen EI, and half of the maximum 255 in the upward direction from the center O of the screen EI. 128 positions are shown. When the center O of the screen is moved to the position of the point P1, the optical adapter 5 is bent in the + (plus) direction in the X direction and the + (plus) direction in the Y direction in FIG. Is curved.

  5 and 6, the relationship information between the position on the screen and the bending angles in the vertical and horizontal directions is determined in advance by calculation for each type of optical adapter and stored in advance in the memory unit 43 as table data.

  In S3, data corresponding to the type of the identified optical adapter 5 is selected from the data of the two coordinate curve angle tables TBLx and TBLy. Therefore, for example, when the type of the optical adapter 5 is a type having an angle of view of 80 °, data of the bending angle corresponding to the angle of view of 80 ° is selected in each of the two coordinate curve tables TBLx and TBLy.

  When the optical adapter 5 is not attached (S1: YES), the CPU 41 selects the data of the bending angle corresponding to the case without the optical adapter from the data of the two coordinate bending tables TBLx and TBLy. (S4).

  The CPU 41 controls the graphic superimposing unit 42 to display a live endoscopic image obtained by processing by the imaging signal processing unit 33 on the display 31 (S5). As a result, a live endoscopic image obtained by imaging with the imaging element 21 is displayed on the display unit 3b.

The inspector can push the insertion portion 2 into the inspection target to further advance the distal end portion of the insertion portion 2 to the back of the inspection target and perform an inspection by looking at the endoscope image at the back. .
Then, the examiner can bend the bending portion 2b so that the distal end portion of the insertion portion 2 is directed to the site to be observed by touching the touch panel of the display portion 3b during the inspection.

  The CPU 41 monitors the output from the touch panel 32 to determine whether or not there is a bending instruction on the touch panel of the display unit 3b (S6). The presence / absence of a bending instruction is determined by whether or not the screen EI is touched while displaying an endoscopic image. When a touch is made on the screen EI, for example, the position of the center of gravity of the area touched by the finger on the touch panel 32 is determined as the touch position coordinates.

  When there is no bending instruction on the touch panel (S6: NO), the CPU 41 determines whether there is a change in the mounted optical adapter 5 or an unmounted optical adapter 5 is mounted (S7). When the optical adapter 5 attached to the distal end portion of the insertion portion 2 is changed to another type of optical adapter 5 by replacement, or the optical adapter 5 has not been attached to the distal end portion of the insertion portion 2 until then. May be newly installed. These changes or mountings can be determined by the CPU 41 by monitoring the output of the optical adapter identification unit 35.

  If there is no change or new attachment of the optical adapter 5 (S7: NO), the process proceeds to S5. When the optical adapter 5 is changed or newly attached, the process proceeds to S1, and data of the coordinate curve table corresponding to the attached optical adapter 5 is selected (S3, S4).

When there is a bending instruction on the touch panel (S6: YES), the CPU 41 extracts and acquires bending angle information corresponding to the touched position coordinates from the selected data (S8).
FIG. 9 is a diagram illustrating an example of an endoscopic image displayed on the screen of the display unit 3b. FIG. 9 shows an example of an image in the pipe, and an endoscope image in the substantially axial direction of the pipe is displayed on the screen of the display unit 3b by the imaging element 21 of the distal end hard part 3a.

  As shown in FIG. 9, a plurality of instruction buttons are also displayed on the screen EI along with the live endoscope image. On the screen EI, a point recording button 51, a continuous recording start button 52, and a recording mode end button 53 are displayed. When the point recording button 51 is selected and execution is instructed, information on the bending angle in the vertical and horizontal directions at that time and information on the type of the optical adapter 5 are recorded. When the continuous recording start button 52 is selected and execution is instructed, information on the bending operation at that time, that is, information on the bending angle in the vertical and horizontal directions is recorded at a predetermined cycle. Also during continuous recording, information on the type of optical adapter 5 is also recorded.

  When the recording mode end button 53 is selected and execution is instructed, dot recording or continuous recording ends. Information on the bending angle in the vertical and horizontal directions and the information on the type of the optical adapter 5 recorded by dot recording and continuous recording are recorded in the memory unit 43.

  Here, when the inspector finds a place to be observed in more detail in the endoscopic image in the pipe projected on the screen EI of the display unit 2b, the inspector displays on the screen EI of the display unit 3b. Touch the place you want to observe in detail with your finger. If the upper part AA in the endoscopic image of FIG. 9 is a part to be observed in detail, the examiner touches the part AA on the screen EI.

  Since the CPU 41 monitors the coordinate information from the touch panel 32, the bending angle information corresponding to the touched coordinate information is obtained from the two coordinate bending angle tables TBLx and TBLy based on the coordinate information of the touched portion. Extract from the selected data (S8).

For example, if the coordinate information is (x _j , y _k ), the CPU 41 extracts left-right bending angle information Ax _j corresponding to the coordinates (x _j ) from the coordinate bending angle table TBLx, and the coordinate bending angle table The bending angle information Ay _k in the vertical direction corresponding to the coordinate (y _k ) is extracted from TBLy.

Further, the CPU 41 reads the current bending angle (Ax _c , Ay _c ) of the bending portion 2b from the bending portion driving portion 37 (S9).
The CPU 41 obtains the target bending angle by adding the bending angle (Ax _j , Ay _k ) extracted in S8 to the current bending angle (Ax _c , Ay _c ) (S10). If the current bending angle (x _c , y _c ) is (0, 0) and the coordinate information of the bending instruction is (x _j , y _k ), in S10, at the target bending angle obtained by addition, The direction angle is (Ax _j ), and the vertical angle is (Ay _k ). If the current bending angle (Ax _c , Ay _c ) is not (0, 0) and the coordinate information of the bending instruction is (Ax _j , Ay _k ), in S10, the target bending angle obtained by addition is The horizontal angle is (Ax _c + Ax _j ), and the vertical angle is (Ay _c + Ay _k ).

  The CPU 41 outputs a bending instruction to the bending portion driving unit 37 so that the bending angle of the bending portion 2b becomes the target bending angle (S11). As a result, the bending portion drive unit 37 controls the bending portion 2b so that the part AA is at the center of the screen EI. FIG. 10 is a diagram illustrating an example of an endoscopic image displayed on the screen of the display unit 3b when the part AA comes to the approximate center of the screen EI.

Then, the CPU 41 determines whether or not the bending angle of the bending portion 2b has reached the maximum bending angle (S21), and when the bending angle of the bending mechanism 22 has reached the maximum bending angle (S21: YES), the bending is further performed. An icon indicating that it cannot be displayed is displayed on the screen EI (S22). The CPU 41 can determine from the current bending angle information that the maximum bending angle has been reached.
If the bending angle of the bending mechanism 22 does not reach the maximum bending angle (S21: NO), the CPU 41 does not execute the process of S22.

  FIG. 11 is a diagram for explaining an example of an icon displayed when the maximum bending angle is reached. For example, it is assumed that the inspector touches the touch panel 32 and instructs the screen EI to be further curved in the upper right direction in the state of FIG. Although the bending portion 2b is bent, when the maximum bending angle is reached, a predetermined icon IND is displayed on the screen EI as shown in FIG.

The icon IND has a ring shape, and the portion in the direction reaching the maximum curve is displayed thick. In FIG. 11, the portion MR in the range of 90 degrees in the upper right direction of the icon IND is thick, indicating that the maximum bending angle is in both the right direction and the upper direction.
In the icon IND, the color of the portion MR in the direction reaching the maximum curvature may be changed.

With such an icon IND, the inspector can easily recognize in which direction the curve can no longer be made on the screen EI.
Therefore, the process of S22 constitutes a maximum bending angle state display unit that performs predetermined display on the screen when the bending angle of the bending portion 2b reaches the maximum bending angle.

  As described above, the CPU 41 determines the first relationship information between the position of the display unit 3b in the vertical direction on the screen and the bending angle of the curved unit 2b in the vertical direction, and the position of the display unit 3b in the horizontal direction on the screen. Based on the second relationship information with the bending angle in the left-right direction of the bending portion 2b, the bending angle in the up-down direction and the bending angle in the left-right direction of the bending portion 2b are determined from touch position information on the screen detected by the touch panel 32. The bending portion drive unit 37 is controlled so that the bending angle in the vertical direction and the bending angle in the left and right direction of the bending portion 2b are close to the bending angle in the vertical direction and the bending angle in the left and right direction determined as the target bending angle, respectively. A control unit is configured.

  In particular, the CPU 41 that is the control unit determines the type of the optical adapter 5 and detects it by the touch panel 32 based on the relationship information in the vertical direction of the screen and the relationship information in the horizontal direction according to the determined type. The bending angle in the up-down direction and the bending angle in the left-right direction of the bending portion 2b are determined from the touch position information on the screen.

  Further, the CPU 41 adjusts the bending portion driving unit until the bending angle in the vertical direction and the bending angle in the left and right direction of the bending portion 2b substantially coincide with the bending angle in the vertical direction and the bending angle in the left and right direction determined as the target bending angle, respectively. Is driven and when the vertical or horizontal bending angle reaches the maximum bending angle, a predetermined display such as an icon IND is performed.

  Returning to FIG. 4, the CPU 41 determines whether or not a point recording instruction, that is, a point recording mode is instructed (S23). When the point recording button 51 on the screen EI is selected and execution is instructed (S23: YES), the CPU 41 obtains information on the bending angle in each of the vertical and horizontal directions at that time and the type information on the optical adapter 5. Then, it is recorded in the memory unit 43 (S24).

  Therefore, in the process of S24, when a predetermined recording instruction is received, the bending angle information in the vertical direction and the bending angle information in the horizontal direction when the recording instruction is received are recorded in the memory unit 43 that is a storage device. An angle information recording unit is configured.

  If the point recording button 51 on the screen EI is selected and execution is not instructed (S23: NO), the CPU 41 determines whether or not a continuous recording instruction, that is, an instruction of continuous recording mode has been instructed (S25). When the continuous recording button 52 on the screen EI is selected and the execution is instructed (S25: YES), the CPU 41, the information on the bending angle in each of the vertical and horizontal directions at that time and thereafter, and the optical adapter 5 The type information is recorded in the memory unit 43 at predetermined intervals (S26).

  Therefore, when the processing of S26 receives a predetermined recording instruction, the bending angle information in the vertical direction and the bending angle information in the left-right direction are received at a predetermined cycle from when the recording instruction is received until the recording end instruction is received. The bending angle recording unit that records in the memory unit 43 that is a storage device is configured.

  Then, the CPU 41 determines whether or not the recording mode end button 53 is pressed (S27). If the recording mode end button 53 is not pressed (S27: NO), the CPU 41 curves until the recording mode end button 53 is pressed. The angle information is recorded in the memory unit 43 over time. Therefore, the bending angle information and the optical adapter type information stored in S24 and S26 are sequentially recorded in the memory unit 43.

  After S24, it is determined whether or not power-off is instructed (S28). If power-off is not instructed (S28: NO), the process returns to S5. Similarly, when the recording mode end button 53 is pressed (S27: YES), the process proceeds to S28, and the CPU 41 determines whether or not the power off is instructed (S28), and the power off is not instructed. If (S28: NO), the process returns to S5. When the power off is instructed (S28: YES), the process ends.

  As described above, according to the endoscope apparatus of the above-described embodiment, an arbitrary position in the endoscopic image can be quickly and easily moved to the substantially central portion of the screen.

  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 Insertion part, 2a Hard end part, 2b Bending part, 2c Flexible pipe part, 3 Operation part, 3a Operation part main body, 3b Display part, 3c Operation switch group, 3d Joystick, 4 Main body part, 4a display unit, 5 optical adapter, 5a illumination window, 11 optical lens unit, 12 ID storage unit, 13 illumination unit, 21 imaging device, 22 bending mechanism, 31 display, 32 touch panel, 33 imaging signal processing unit, 34 imaging device Drive unit, 35 Optical adapter identification unit, 36 Illumination unit drive unit, 37 Curved unit drive unit, 38 Input unit, 41 CPU, 42 Graphic superimposing unit, 43 Memory unit, 51 Point recording button, 52 Continuous recording start button, 53 recording Mode end button.

Claims (7)

An insertion part;
A bending portion provided in the insertion portion;
A display unit for displaying an endoscopic image generated from reflected light from a subject obtained through an objective optical system provided at the distal end of the insertion unit;
A touch panel provided in the display unit;
A bending portion drive unit that drives the bending portion so that the bending portion is in a bending state at an instructed bending angle;
First relationship information between the position of the display unit in the vertical direction on the screen and the bending angle of the bending unit in the vertical direction, the position in the horizontal direction on the screen and the bending angle of the bending unit in the horizontal direction And determining a bending angle in the vertical direction and a bending angle in the left-right direction of the bending portion from touch position information on the screen detected by the touch panel, and the bending portion in the left-right direction. A controller that controls the bending portion drive unit so that the bending angle in the up-down direction and the bending angle in the left-right direction are close to the determined bending angle in the up-down direction and the bending angle in the left-right direction, respectively.
An endoscope apparatus characterized by comprising:   The control unit drives the bending portion until the bending angle in the vertical direction and the bending angle in the left-right direction of the bending portion substantially match the determined bending angle in the vertical direction and the bending angle in the left-right direction, respectively. An endoscope apparatus that controls to drive a unit. Relation information that stores the first relation information and the second relation information for each type of optical adapter that is attached to the distal end of the insertion section and has an optical lens that changes the angle of view of the endoscopic image. Having a storage unit,
The control unit determines the type of the optical adapter, and on the screen detected by the touch panel based on the first relationship information and the second relationship information according to the determined type. The endoscope apparatus according to claim 1 or 2, wherein a bending angle in the vertical direction and a bending angle in the horizontal direction of the bending portion are determined from the touch position information.   The endoscope apparatus according to claim 3, wherein the relation information storage unit stores the first relation information and the second relation information as table data.   The internal vision according to any one of claims 1 to 4, further comprising: a maximum bending angle state display unit that performs predetermined display on the screen when a bending angle of the bending portion becomes a maximum bending angle. Mirror device.   When receiving the first recording instruction, the first bending angle information recording that records the bending angle information in the up and down direction and the bending angle information in the left and right direction when the first recording instruction is received in a storage device. The endoscope apparatus according to claim 1, further comprising a section.   When the second recording instruction is received, the bending angle information in the vertical direction and the bending angle information in the left-right direction are received at a predetermined cycle from when the second recording instruction is received until the recording end instruction is received. The endoscope apparatus according to any one of claims 1 to 6, further comprising a second bending angle recording unit configured to record in the storage device.

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