JP5259457B2 - Electronic image observation device - Google Patents

Description

  The present invention is used in, for example, a surgical operation, and images an operation part such as an organ composed of a fine tissue such as a brain, and displays an image of the operation part on a display device to perform an operation. The present invention relates to an image observation apparatus.

  For example, in a surgical operation for operating an organ composed of a fine tissue such as a brain, an electronic image for imaging an operation part of the organ performing the operation and displaying the image of the operation part on a display device to perform the operation. An observation device is used. This electronic image observation apparatus displays an image of an operation site as a stereoscopic image.

Conventionally, it is known to obtain a stereoscopic image by observing and fusing a binocular image with parallax using the principle of binocular parallax. Such a stereoscopic viewing device generally includes an imaging device that captures an image with parallax and an image display device that displays an image stereoscopically.
The technique of the imaging device is disclosed in Patent Document 1, for example. Paragraph No. [0034] of Patent Document 1 generally includes a left-eye imaging optical system and a right-eye imaging optical system, and adjusts the focus positions of the left-eye and right-eye optical systems to the observation target, It is disclosed that a video with parallax is captured.
Various techniques for displaying a stereoscopic image are known, for example, as in Patent Document 2. Among them, Patent Document 2 projects left and right images on the panel surface by the left and right projection optical systems, condenses the images at the positions of the left and right eyes of the observer, and observes the right and left images with the parallax that has been condensed. Disclosed is a display device for performing stereoscopic observation by fusing.

  A technique for arranging the imaging device and the display device is disclosed in Patent Document 3, for example. Patent Document 3 discloses a medical unit including a mirror unit having an objective optical system and an imaging optical system, a display unit that displays an image captured by the mirror unit, and a support unit that supports the mirror unit. An observation device, wherein the support means has an elevation mechanism for raising and lowering the mirror body portion, and the mirror body portion has a shape in which both ends of rotation of the mirror body portion are distributed so that the rotation center of the elevation mechanism is located between It is disclosed that it was formed. Specifically, in Patent Document 3, for example, as shown in FIG. 29, the operator 200 places the mirror part 200 above the subject to be treated such as a patient and the monitor 201 faces the operator Q. Provide. The mirror unit 200 includes an objective optical system 202 and an imaging unit 203. The imaging unit 203 images the surgical part of the subject through the objective optical system 202. The image signal output from the imaging means 203 is subjected to image processing and sent to the monitor 201 as a stereoscopic image. The monitor 201 displays a stereoscopic image of the surgical site. The surgeon Q advances the operation while observing a stereoscopic image of the surgical part displayed on the monitor 201.

  For example, there is Patent Literature 4 as a surgical microscope system that can reduce the burden on the surgeon and assistant. This Patent Document 4 includes X-direction conversion that inverts an image in the X direction and Y-direction conversion that inverts an image in the Y direction, and an image displayed on the sub CRT display is displayed on the main CRT display. Image processing is performed so that the displayed reference image is reversed in the X direction (left and right direction) and Y direction (up and down direction), and the reversed image is displayed on the sub CRT display. Both of them disclose a technique in which surgery can be performed while viewing a stereoscopic image displayed on a CRT display.

JP 2006-14825 A JP 2003-233031 A JP 2006-14825 A JP 2002-272760 A

  Depending on the technique for the operation on the surgical part of the subject, the operator Q may rotate the mirror part 200 and place the optical axis of the objective optical system 202 close to the horizontal direction, for example, as shown in FIG. . When the mirror unit 200 is rotated in this way, the mirror unit 200 itself stands up in the vertical direction, and the mirror unit 200 enters the line of sight between the operator Q and the monitor 201. . For this reason, when the image of the surgical site displayed on the monitor 201 is observed by the surgeon Q, the image of the surgical site displayed on the monitor 201 is blocked by the mirror unit 200. Therefore, the operator Q does not enter the line of sight between the operator Q and the monitor 201 by further rotating the mirror part 200 and reversing the vertical direction as shown in FIG. Are arranged as follows.

  However, when the vertical direction of the mirror unit 200 is reversed, the stereoscopic image of the surgical part displayed on the monitor 201 is displayed by being rotated 180 ° with respect to the stereoscopic image before the mirror unit 200 is inverted. That is, when the mirror part 200 is inverted, the positional relationship between the left eye and the right eye in the mirror part 200 is reversed left and right, and the vertical direction is reversed.

  As shown in FIG. 32, before the mirror unit 200 is inverted, an image captured by the left eye of the mirror unit 200 is displayed as a left eye image, and an image captured by the right eye of the mirror unit 200 is displayed as a right eye image. Is displayed. If the left-eye captured image is, for example, “white F”, the left-eye captured image “white F” is displayed as the left eye as it is. If the captured image of the right eye is “colored F”, for example, the captured image of the right eye “colored F” is displayed as it is as the right eye.

  On the other hand, when the mirror unit 200 is inverted, the captured image of the left eye becomes “colored F”, and furthermore, the captured image of “colored F” rotated 180 ° and reversed up and down. Similarly, the captured image of the right eye is “white F”, and is a “white F” captured image that is rotated 180 ° and reversed up and down. That is, the left and right eyes in the mirror unit 200 are replaced when viewed from the operator Q. Therefore, the image corresponding to the left eye of the operator Q is displayed corresponding to the right eye in the display, and the image corresponding to the right eye is displayed corresponding to the left eye in the display.

  The surgeon Q is a stereoscopic image of the surgical part in an image in the same direction as the left and right and up and down directions of the image before the mirror part 200 is reversed when performing surgery even when the mirror part 200 is inverted. Is required to have no sense shift between the visual sensation when viewing the surgical site and the visual sensation when viewing the image of the surgical site displayed on the monitor 201.

  Patent Document 4 obtains an inverted image that is inverted in the X direction (left-right direction) and the Y direction (up-down direction), but is not a technique that corresponds to when the captured images of the left and right eyes are interchanged. For this reason, as shown in FIG. 31, when the mirror part 200 is inverted, when the patent document 4 is applied, the images displayed on the sub CRT display on the assistant side are aligned. Since each of the captured images is not replaced, the uneven direction of the uneven shape of the surgical part displayed in the stereoscopic image is reversed.

  An object of the present invention is to provide an electronic image observation apparatus capable of acquiring a stereoscopic image in an appropriate direction without depending on the orientation of the imaging device even if the orientation of the imaging device having a pair of left and right imaging elements is arbitrarily changed. There is.

An electronic image observation apparatus according to a main aspect of the present invention includes an imaging apparatus having an observation optical system including a pair of left and right imaging elements, a joint mechanism in which a distal end is rotatably provided and the imaging apparatus is provided at the distal end, Rotation angle output means provided at the distal end of the joint mechanism and outputting a signal corresponding to the rotation angle of the distal end of the joint mechanism, and the distal end of the joint mechanism is predetermined based on the reference angle based on the output signal of the rotation angle output means Each of a pair of left and right image signals acquired from the image sensor in the imaging device in response to the switching control signal sent from the control signal output unit an image switching means for switching the and are replaced by each of the pair of left and right image signals by the image switching means, changes the vertical direction by rotating each of the pair of left and right image signals Comprises an image rotation means, and a display unit for displaying an image switching means and a pair of left and right image signals output through the image rotating means.

  ADVANTAGE OF THE INVENTION According to this invention, even if it changes direction of the imaging device which has a left-right paired image sensor arbitrarily, the electronic image observation apparatus which can acquire the stereo image of an appropriate direction irrespective of the direction of an imaging device can be provided. .

1 is an overall configuration diagram showing a first embodiment of an electronic image observation apparatus according to the present invention. The specific block diagram which shows the imaging device in the apparatus. The block diagram which shows the electric system which has switched the image of the normal time in the same apparatus to a through state. The block diagram which shows the electric system which has switched to the state which reverses the image in the apparatus. The figure which shows arrangement | positioning of the normal upright state of the apparatus. The figure which shows the arrangement | positioning in the state which reversed the up-down direction, without changing arrangement | positioning of the image pick-up element of a right-and-left eye compared with the arrangement | positioning of a normal imaging device. The figure which shows arrangement | positioning of the state which reversed right and left direction and the up-down direction with respect to the image sensor of the right and left eyes of the apparatus at the normal time. The figure which shows arrangement | positioning of the state which reversed right and left direction and the up-down direction with respect to the image sensor of the right and left eyes of the apparatus at the normal time. The block diagram which shows the support apparatus in 2nd Embodiment of the electronic image observation apparatus which concerns on this invention. The block diagram which shows the electric system which has switched the image of the normal time in the same apparatus to a through state. The block diagram which shows the electric system which has switched to the state which reverses the image in the apparatus. The figure which has arrange | positioned the imaging device in the same apparatus in the normal upright state. The figure which has arrange | positioned the imaging device in the same apparatus in the state rotated more than the angle +/- 90 degrees around the axis | shaft e. The switching determination flowchart in the same apparatus. The block diagram which shows the modification of the imaging support apparatus in the apparatus. The block diagram which shows the support apparatus in 3rd Embodiment of the electronic image observation apparatus which concerns on this invention. The figure which shows the initial imaging direction of the imaging device in the apparatus. The block diagram which shows the electric system which has switched the image of the normal time in the same apparatus to a through state. The block diagram which shows the electric system which has switched to the state which reverses the image in the apparatus. The switching determination flowchart in the same apparatus. The block diagram which shows the support apparatus in 4th Embodiment of the electronic image observation apparatus which concerns on this invention. The block diagram which shows the control signal output part in the same apparatus. The switching determination flowchart in the same apparatus. The block diagram which shows the electric system which has switched the normal image in the through state in 5th Embodiment of the electronic image observation apparatus which concerns on this invention. The block diagram which shows the electric system which has switched to the state which reverses the image in the apparatus. FIG. 6 is a schematic diagram showing writing / reading operations in a recording circuit for the left and right eyes in a normal state in the apparatus. FIG. 6 is a schematic diagram showing write / read operations in the left and right eye recording circuits when switching to the inversion state in the apparatus. The block diagram which shows the electric system switched to the state which reverses the image in the 1st display system in the 6th Embodiment of the electronic image observation apparatus which concerns on this invention. The block diagram which shows the electric system which switched the image of the normal time to the through state in the 1st display system in the same apparatus. The figure which shows an example of arrangement | positioning with the stereoscopic display apparatus of the 1st display system | strain in this apparatus, and the stereoscopic display apparatus of a 2nd display system | strain. The block diagram which shows the electric system which switched the normal image to the through state in the 1st display system in the 7th Embodiment of the electronic image observation apparatus which concerns on this invention. The block diagram which shows the electric system switched to the state which reverses an image in the 1st display system | strain in the same apparatus. The figure which shows the arrangement | positioning relationship between the mirror part operated by the operator in the conventional medical observation apparatus, and a monitor. The figure which shows the arrangement | positioning which rotated the mirror part in the apparatus and made the optical axis of the objective optical system close to the horizontal direction. The figure which shows the arrangement | positioning which reversed the up-down direction of the mirror part in the same apparatus so that the said mirror part might not enter between an operator and a monitor. FIG. 4 is a schematic diagram showing a stereoscopic image on a monitor in which the positional relationship between the left eye and the right eye is reversed left and right and the up and down direction is reversed when the vertical direction of the mirror body portion in the apparatus is reversed.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an overall configuration diagram of an electronic image observation apparatus provided in an operating room. On the bed 1, a subject R that is a subject of treatment such as a patient is placed. The subject R requires surgery for the head such as the brain, for example, and the head is the surgical part 2. The surgeon Q is present on the head side of the subject R on the extension along the longitudinal direction of the bed 1 and performs a procedure such as surgery on the surgical section 2.

  On one side of the bed 1, a support device (hereinafter abbreviated as an imaging support device) 3 of an image pickup device composed of an articulated robot is provided as a joint mechanism. The imaging support device 3 supports the imaging device 4. The imaging support device 3 includes a multi-joint arm 6 provided on a support column 5. An imaging device 4 is provided at the tip of the articulated arm 6. The multi-joint arm 6 is formed by connecting a plurality of arms with each joint, and the imaging direction of the imaging device 4 can be changed by moving each arm through each joint.

  A holding arm 7 is provided on the other side surface of the bed 1, and a stereoscopic display device 8 is provided on the holding arm 7. The stereoscopic display device 8 is provided with the panel surface of the display panel 8a facing the operator Q. The stereoscopic display device 8 may be any type of display device. For example, the stereoscopic display device 8 only needs to have a distinction between left and right eyes even if the methods such as HMD, field sequential, and X / pol are different.

The image control unit 10 is connected to the output terminal of the imaging device 4 via a left-eye communication control unit (hereinafter referred to as L-side CCU) 9L and a right-eye communication control unit (hereinafter referred to as R-side CCU) 9R. Has been.
The image control unit 10 images the left eye image signal (first image signal) of the imaging device 4 from the L side CCU 9L and the right eye image signal (second image signal) of the imaging device 4 from the R side CCU 9R. Processing is performed to create stereoscopic image data, and this stereoscopic image data is displayed on the stereoscopic display device 8.

  FIG. 2 shows a specific configuration diagram of the imaging apparatus 4. The imaging apparatus 4 includes an objective optical system 21, a deflection element 22, a variable magnification optical system 23, an imaging optical system 24, and a pair of left and right imaging elements 25L (first imaging) in an imaging apparatus main body 20. Element) and 25R (second imaging element). The objective optical system 21, the variable magnification optical system 23, and the imaging optical system 24 each have a pair of left and right optical systems. In addition, the deflection | deviation element 22 passes each optical path of a right-and-left eye by one element, for example. Each of the image sensors 25L and 25R is composed of, for example, a fixed image sensor (CCD).

  The imaging device 4 captures a light image from a subject including the surgical part 2 through the objective optical system 21 and enters the light image from the subject through the deflecting element 22 and the variable power optical system 23 into the imaging optical system 24. The imaging optical system 24 forms an image on a pair of left and right imaging elements 25L and 25R. These imaging elements 25L and 25R each output digital image signals of left and right eyes for creating a stereoscopic image of the subject.

  In the imaging apparatus 4, an image changeover switch 26 is provided in the imaging apparatus body 20. The image changeover switch 26 is provided for instructing the left / right switching of the left and right image signals output from the imaging device 4 and the up / down inversion. The image changeover switch 26 is provided in the imaging device body 20, but is not limited thereto, and may be provided in the imaging support device 3 having the bed 1, the articulated arm 6, the support column 5, the stereoscopic display device 8, and the like. Good. Note that the image changeover switch 26 may instruct one of left / right switching of the left and right image signals output from the imaging device 4 and up / down inversion. For example, the image changeover switch 26 is a switch for switching the left and right image signals output from the imaging device 4 to the left and right, a switch for reversing the vertical direction, a left-right switching of the image signals, and a vertical direction switch. A switch for performing inversion may be provided.

  With such a configuration, the pair of left and right imaging elements 25L and 25R of the imaging device 4 captures the surgical part 2 of the subject R and outputs a pair of left and right image signals. Among these, the left-eye image signal is sent to the image control unit 10 through the L-side CCU 9L, and the right-eye image signal is sent to the image control unit 10 through the R-side CCU 9R.

  The image control unit 10 performs image processing on the left-eye image signal from the L-side CCU 9L and the right-eye image signal from the R-side CCU 9R to create stereoscopic image data, and displays the stereoscopic image data on the stereoscopic display device 8 To do. The surgeon Q advances the operation of the surgical section 2 while observing a stereoscopic image of the surgical section 2 displayed on the display panel 9a.

  FIG. 3 shows a configuration diagram of the electrical system of the present apparatus. The pair of left and right eye imaging elements 25L and 25R of the imaging device 4 are connected to the image control unit 10 through the L-side CCU 9L and the R-side CCU 9R, respectively. The image control unit 10 includes an image switching unit 30, a left eye image rotation unit 31L, and a right eye image rotation unit 31R. Among these, a control signal output unit 32 is connected to the image switching unit 30.

  The control signal output unit 32 includes an image changeover switch 26. When the control signal output unit 32 receives a manual operation on the image switching switch 26, the control signal output unit 32 instructs to switch left and right image signals of the left and right eyes output from the imaging device 4 and to invert in the vertical direction. H is sent to the image switching unit 30. Note that the control signal output unit 32 sends a switching control signal H for instructing either or both of left and right switching of the left and right image signals of the imaging device 4 and vertical inversion. It may be a thing.

  When the image switching unit 30 receives the switching control signal H from the control signal output unit 32, the image switching unit 30 switches the left and right image signals of the left and right eyes output from the imaging device 4. Specifically, the image switching unit 30 includes an L-side switching end 33, a through terminal 34, and a switching terminal 35, and an R-side switching end 36, a through terminal 37, and a switching terminal 38.

  The switching end 33 on the L side is normally connected to the through terminal 34 and switches to the switching terminal 35 when receiving the switching control signal H. The switching end 36 on the R side is normally connected to the through terminal 37 and switches to the switching terminal 38 when receiving the switching control signal H. FIG. 3 shows a normal state in which an L-side switching end 33 and an R-side switching end 36 are connected to the through terminals 34 and 37, respectively. FIG. 4 shows a state in which the switching end 33 on the L side and the switching end 36 on the R side are switched to the switching terminals 35 and 38, respectively.

A through terminal 34 and a switching terminal 38 are connected to the left eye image rotation unit 31L. When the left eye image rotation unit 31L receives an image signal of the left eye of the imaging device 4 from the through terminal 34, the left eye image rotation unit 31L transmits the image signal to the stereoscopic display device 8 without rotating the image signal.
On the other hand, when the left eye image rotation unit 31L receives the right eye image signal of the imaging device 4 from the switching terminal 38, the left eye image rotation unit 31L rotates the right eye image signal by 180 degrees to change the vertical direction. Send to 8.

A through terminal 37 and a switching terminal 35 are connected to the right eye image rotation unit 31R. When the right eye image signal of the imaging device 4 is input from the through terminal 37, the right eye image rotation unit 31 </ b> R passes through the right eye image signal without rotation and sends the image signal to the stereoscopic display device 8.
On the other hand, when the image signal of the left eye of the imaging device 4 is input from the switching terminal 35, the right-eye image rotation unit 31R rotates the left-eye image signal by 180 degrees to change the vertical direction and thereby the stereoscopic display device. Send to 8.

Next, the operation of the apparatus configured as described above will be described.
Normally, the operator Q is in a state in which the imaging device 4 is upright as shown in FIG. 5A, that is, the imaging element 20L of the left eye in the imaging device 4 as viewed from the operator Q is the same as shown in FIG. The imaging device 4 is set in a posture in which the left and right eye imaging devices 20R are arranged on the right side. The posture of the imaging device 4 is set by moving each arm of the articulated arm 6 of the imaging support device 3.

  In this state, the imaging device 4 takes in a light image from a subject including the surgical section 2 through the objective optical system 21, and takes the light image from the subject into the imaging optical system 24 through the deflecting element 22 and the variable power optical system 23. Incident light is imaged by the imaging optical system 24 on a pair of left and right imaging elements 25L and 25R. These image pickup devices 25L and 25R respectively output left and right eye image signals for creating a stereoscopic image of the subject. The left and right eye image signals output from the imaging elements 25L and 25R are sent to the image switching unit 30 of the image control unit 10 through the L-side CCU 9L and the R-side CCU 9R, respectively.

  At this time, if the operator Q has not pushed the image switching switch 26, the image switching unit 30 is in a normal state in which the left and right image signals of the left and right eyes output from the imaging device 4 are not switched. . That is, the image switching unit 30 connects the L-side switching end 33 to the through terminal 34 and the R-side switching end 36 to the through terminal 37 as shown in FIG. As a result, the image signal output from the left-eye image sensor 20L is sent to the left-eye image rotation unit 31L through the L-side CCU 9L, the L-side switching end 33, and the through terminal 34. At the same time, the image signal output from the right-eye image sensor 20R is sent to the right-eye image rotation unit 31R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

However, when the left eye image rotation unit 31L receives the left eye image signal of the imaging device 4 from the through terminal 34, the left eye image rotation unit 31L passes through the left eye image signal without rotating. At the same time, when the right eye image signal of the imaging device 4 is input from the through terminal 37, the right eye image rotation unit 31R passes through the right eye image signal without rotating. Then, the image control unit 10 processes the left-eye image signal from the L-side CCU 9L and the right-eye image signal from the R-side CCU 9R to create stereoscopic image data, and this stereoscopic image data is stored in the stereoscopic display device 8. send.
As a result, a stereoscopic image of the subject including the operation part 2 is displayed on the stereoscopic display device 8. The surgeon Q advances the operation while observing a stereoscopic image of the subject including the surgical unit 2 displayed on the stereoscopic display device 8. The stereoscopic image of the subject including the surgical section 2 displayed on the stereoscopic display device 8 is the same vertical / horizontal stereoscopic image as the vertical / horizontal direction of the surgical section 2 on which the operator Q is performing surgery. ing.

  On the other hand, depending on the technique for the surgical part 2, the operator Q may rotate the imaging device 4 and place it in a state close to horizontal, as shown in FIGS. 5B to 5D, for example. 5B is moved from the posture of the imaging device 4 at the normal time, and the left eye imaging element 25L and the right eye imaging element 25R in the imaging device 4 are arranged on the left side and the right side with respect to the surgical part 2. Note that the vertical direction of the left-eye imaging element 25L and the right-eye imaging element 25R in the imaging device 4 is not inverted compared to the normal arrangement of the imaging device 4. Thus, when the imaging device 4 is rotated and disposed in a nearly horizontal state, the operator Q blocks his visual field when performing the operation on the surgical site 2 by the imaging device 4.

  FIG. 5C shows a state in which the imaging device 4 is moved and the arrangement direction of the objective optical system 21 is rotated from the normal arrangement by an angle of 180 °. In this state, the imaging device 4 has the left-eye imaging device 20L on the right side, the right-eye imaging device 20R on the left side, and the left-eye imaging device 25L and the right-eye imaging device 25R. The up and down direction is arranged in the opposite direction. That is, the arrangement of the imaging elements 25L and 25R for the left and right eyes is interchanged as compared with the arrangement of the normal imaging device 4, and the vertical direction is also reversed.

  FIG. 5D shows a state in which the imaging device 4 is moved and the imaging direction is rotated in the same direction as the direction in which the operator Q observes the surgical site 2, that is, rotated from the normal posture by 180 degrees on the horizontal plane. In this state, the imaging device 4 arranges the left-eye imaging device 25L on the right side and the right-eye imaging device 25R on the left side with respect to the surgical part 2, that is, the normal left-right imaging devices 25L and 25R. On the other hand, the left and right eye image pickup devices 25L and 25R are arranged opposite to each other in the left-right direction, and the vertical direction of the left eye image pickup device 25L and the right eye image pickup device 25R is also reversed.

As described above, when the left and right imaging elements 25L and 25R are switched left and right or the vertical direction is reversed compared to the arrangement of the imaging elements 25L and 25R of the normal imaging apparatus 4, the image is displayed on the stereoscopic display device 8. The stereo image data of the surgical unit 2 is an image in which the left and right are interchanged or the vertical direction is reversed.
In particular, as shown in FIGS. 5C and 5D, the left and right eye image pickup devices 25L and 25R are arranged opposite to the left and right eye image pickup devices 25L and 25R, and the left eye image pickup device 25L and the right eye The vertical direction with respect to the imaging element 25R is also reversed.

  In such a state, the operator Q pushes and operates the image changeover switch 26. As a result, the control signal output unit 32 receives a manual operation on the image changeover switch 26 and switches the left and right eye image signals output from the imaging device 4 to instruct the left and right switching and the vertical reversal. The signal H is sent to the image switching unit 30.

  Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

By this switching, the left eye image rotation unit 31L inputs the image signal of the right eye of the imaging device 4 from the switching terminal 38. Thereby, the left eye image rotation unit 31L rotates the image signal of the right eye by 180 degrees, changes the vertical direction, and sends the image signal to the stereoscopic display device 8.
At the same time, when the left-eye image rotation unit 31R inputs the left-eye image signal of the imaging device 4 from the switching terminal 35, the left-eye image rotation unit 31R rotates the right-eye image signal by 180 degrees and changes the vertical direction to the stereoscopic display device 8. send. Then, the image control unit 10 processes the left-eye image signal from the L-side CCU 9L and the right-eye image signal from the R-side CCU 9R to create stereoscopic image data, and this stereoscopic image data is stored in the stereoscopic display device 8. send.

  As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery. That is, the concavo-convex direction of the concavo-convex shape of the surgical part 2 where the surgeon Q is actually performing surgery and the concavo-convex direction of the concavo-convex shape of the surgical part in the stereoscopic image displayed on the stereoscopic display device 8 are the same direction. become. The surgeon Q advances the operation while observing a stereoscopic image of the subject including the surgical unit 2 displayed on the stereoscopic display device 8.

  As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery. The surgeon Q advances the operation while observing a stereoscopic image of the subject including the surgical unit 2 displayed on the stereoscopic display device 8.

  As described above, according to the first embodiment, the image switching unit 30 that interchanges the left and right image signals output from the imaging device 4 and the right-eye image signal are rotated 180 degrees to move up and down. Left eye image rotation unit 31L and a right eye image rotation unit 31R that changes the vertical direction by rotating the image signal of the left eye 180 degrees. As a result, the left and right eye image sensors 20L and 20R are arranged opposite to the left and right with respect to the normal left and right eye image sensors 20L and 20R, for example, as shown in FIGS. 5C and 5D. Even if the vertical direction of the left eye imaging device 20L and the right eye imaging device 20R is reversed, the stereoscopic display device 8 has the concavo-convex shape of the surgical part 2 on which the operator Q is actually performing surgery. It is possible to display a stereoscopic image in which the uneven direction and the uneven direction of the uneven shape of the surgical part in the stereoscopic image displayed on the stereoscopic display device 8 are the same direction. Therefore, the surgeon Q operates while observing the stereoscopic image of the subject including the surgical unit 2 displayed on the stereoscopic display device 8 even if the imaging device 4 is arranged as shown in FIGS. 5C and 5D, for example. Can proceed.

Next, a second embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 3 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 6 is a configuration diagram of the imaging support device 3 in the electronic image observation device. Specifically, the multi-joint arm 6 of the imaging support device 3 is provided on the support column 5 so that the first rotation shaft 40 can rotate around the axis a. The axis a is in the same direction as the Z axis. On the 1st rotating shaft 40, the 1st arm 42 is provided through the 2nd rotating shaft 41 so that rotation is possible centering on the axis | shaft b. The axis b is orthogonal to the axis a.

A second arm 44 is connected to one end of the first arm 42 via a third rotating shaft 43. The third rotating shaft 43 can rotate around the axis c. The axis c is orthogonal to the axis b. A third arm 46 is connected to the second arm 44 via a fourth rotation shaft 45. The fourth rotation shaft 45 can rotate around an axis d in the same direction as the axial direction of the second arm 44.
The imaging device 4 is connected to the tip of the third arm 46 via a fourth rotating shaft 47. The fourth rotation shaft 47 can rotate around the axis e. The axis e is orthogonal to the axis d. However, the imaging device 4 can rotate around the axis e. The imaging device 4 can rotate around the axis f of the imaging device. The axis f is the longitudinal direction of the imaging device and is orthogonal to the axis e.

  The articulated arm 6 of the imaging support device 3 is not limited to the above configuration, and may have any configuration as long as it can be tilted in the three-axis directions in the XYZ directions or in the three-axis directions. The articulated arm 6 of the imaging support device 3 is balanced by a counterweight α. The multi-joint arm 6 of the imaging support device 3 may be configured by a spring balanced or partially bellows.

  An encoder 48 is provided on the fourth rotation shaft 47 of the imaging support device 3. The encoder 48 outputs a pulse signal corresponding to the rotation angle of the fourth rotating shaft 47 that rotates about the axis e. The pulse signal output from the encoder 48 takes a positive or negative value depending on the rotation direction of the fourth rotating shaft 47.

7 and 8 show the configuration of the electrical system of this apparatus, FIG. 7 shows the configuration of switching the normal image to the through state, and FIG. 8 shows the configuration of switching the image to the inverted state. . 3 and FIG. 4 are denoted by the same reference numerals, and detailed description thereof is omitted.
The control signal output unit 32 includes an encoder 48 and a control signal calculation unit 49. The control signal calculation unit 49 counts positive or negative pulse signals output from the encoder 48, and this count value is a preset count value, for example, the imaging device 4 has an angle ± around the reference angle around the axis e. A switching control signal H is sent out when the corresponding count value is obtained when the rotation is greater than the range of 90 °. Note that a reference angle is set in order to determine that the imaging device 4 has rotated about the reference angle around the axis e by an angle of ± 90 ° or more. For this reference angle, for example, as shown in FIG. 5A, the rotation angle 0 ° of the fourth rotation shaft 47 when the imaging device 4 is arranged in an upright state is set as the reference angle.

The control signal calculation unit 49 counts positive or negative pulse signals output from the encoder 48, and this count value is a preset count value, for example, the imaging device 4 is centered around a reference angle around the axis e. When the angle returns to within the range of ± 90 °, transmission of the switching control signal H is stopped.
The control signal output unit 32 sends the switching control signal H when the imaging device 4 rotates about the reference angle around the axis e by a range of angle ± 90 ° or more, but the range of angle ± 90 °. For example, it is necessary to replace the arrangement of the imaging elements 20L and 20R for the left and right eyes and to reverse the vertical direction as compared with the arrangement of the normal imaging device 4 according to the judgment of the operator Q. The angle range may be set.

Next, the operation of the apparatus configured as described above will be described.
When the imaging device 4 is arranged in an upright state as shown in FIG. 5A, the image switching unit 30 is output from the imaging device 4 as shown in FIG. 7, as in the first embodiment. The left and right image signals are in a normal state in which the left and right images are not interchanged, and the image signal output from the left eye image pickup device 20L is transmitted to the left The image is sent to the image rotation unit 31L. At the same time, the image signal output from the right-eye image sensor 20R is sent to the right-eye image rotation unit 31R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

  However, the left-eye image rotation unit 31L passes through the image signal of the left eye of the imaging device 4 from the through terminal 34 without rotating. At the same time, the right eye image rotation unit 31R passes through the through terminal 37 without rotating the right eye image signal of the imaging device 4. Then, the image control unit 10 processes the left-eye image signal from the L-side CCU 9L and the right-eye image signal from the R-side CCU 9R to create stereoscopic image data, and this stereoscopic image data is stored in the stereoscopic display device 8. send. As a result, a stereoscopic image of the subject including the operation part 2 is displayed on the stereoscopic display device 8. The stereoscopic image of the subject including the surgical section 2 displayed on the stereoscopic display device 8 is the same vertical / horizontal stereoscopic image as the vertical / horizontal direction of the surgical section 2 on which the operator Q is performing surgery. ing.

  The operator Q changes the arrangement of the imaging device 4 according to the technique for the operation on the operation part 2. The imaging device 4 rotates around the axis e by changing the arrangement of the imaging device 4. At this time, the encoder 48 outputs a pulse signal corresponding to the rotation angle of the fourth rotation shaft 47 that rotates about the axis e. This pulse signal takes a positive or negative value according to the rotation direction of the fourth rotation shaft 47.

  The control signal calculation unit 49 counts positive pulse signals and negative pulse signals output from the encoder 48, and the imaging device 4 has an angle ± 90 around the reference angle around the axis e according to the switching determination flowchart shown in FIG. Judge whether it has rotated more than °. That is, in step # 1, the control signal calculation unit 49 counts the pulse signal as a preset count value, for example, when the imaging device 4 rotates about the reference angle around the axis e by a range of an angle ± 90 ° or more. It is determined whether or not the count value corresponding to.

  If the count of the pulse signal does not reach a preset count value as a result of this determination, the control signal calculation unit 49 does not send the switching control signal H. Accordingly, the image switching unit 30 is in a normal state in which the left and right image signals of the left and right eyes output from the imaging device 4 are not switched as shown in FIG.

  On the other hand, depending on the procedure for the surgical site 2, the operator Q, for example, moves the imaging device 4 shown in FIG. 9A from the normal upright arrangement to an angle ± 90 around the reference angle around the axis e as shown in FIG. 9B. May be rotated beyond the range of °. As described above, when the imaging device 4 is rotated about the reference angle around the axis e by an angle of ± 90 ° or more, the arrangement of the imaging elements 20L and 20R for the left and right eyes is compared with the arrangement of the normal imaging device 4. It is switched and the vertical direction is also reversed.

  In such a case, in step # 1, the control signal calculation unit 49 sets the count of the pulse signal to a preset count value, for example, the imaging device 4 is not less than the range of angle ± 90 ° around the reference angle around the axis e. It is determined that the count value corresponding to the rotation has been reached, and in step # 2, a switching control signal for instructing left / right switching and up / down inversion of the left and right image signals output from the imaging device 4 H is sent to the image switching unit 30.

  Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

As a result, the left-eye image rotation unit 31L inputs the right-eye image signal of the imaging device 4 from the switching terminal 38, rotates the right-eye image signal by 180 degrees, and changes the vertical direction to change the stereoscopic display device 8. Send to. At the same time, the right-eye image rotation unit 31R inputs the left-eye image signal of the imaging device 4 from the switching terminal 35, rotates the left-eye image signal by 180 degrees, and changes the vertical direction so as to change the stereoscopic display device 8. Send to.
As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  When the imaging device 4 is again placed in the upright state as shown in FIG. 5A, the control signal calculation unit 49 counts the positive or negative pulse signal output from the encoder 48, and this count value is calculated in advance. The set count value, for example, the imaging device 4 returns to the angle ± 90 ° around the reference angle around the axis e. As a result, the control signal calculation unit 49 stops sending the switching control signal H. As a result, the image switching unit 30 switches the L-side switching end 33 to the through terminal 34 and the R-side switching end 36 to the through terminal 37 as in the normal state shown in FIG.

  As described above, according to the second embodiment, the encoder 48 is provided on the fourth rotating shaft 47 that supports the imaging device 4, and the imaging device 4 is connected to the axis e based on the pulse signal output from the encoder 48. It is determined whether or not the image pickup apparatus 4 has rotated around the reference angle around the reference angle by an angle of ± 90 ° or more. Since the left and right of the output left and right eye image signals are interchanged and the right eye image signal is rotated 180 degrees to change the vertical direction, the left eye image signal is rotated 180 degrees and the vertical direction is changed. The same effects as those of the first embodiment can be obtained, and the image pickup device 4 is automatically rotated around the axis e by a reference angle or more within a range of angle ± 90 ° to obtain a normal image pickup device. Each of the left and right eyes compared to 4 It is determined that the arrangement of the image elements 20L and 20R is switched and the vertical direction is also reversed, and the surgeon Q is displayed on the stereoscopic display device 8 and the concave / convex direction of the concave / convex shape of the surgical part 2 where the operation is actually performed. The stereoscopic display device 8 can display a stereoscopic image having the same direction as the concave and convex direction of the concavo-convex shape of the surgical part in the stereoscopic image being displayed.

The second embodiment may be modified as follows.
For example, the encoder 48 is provided on the fourth rotating shaft 47 that supports the imaging device 4, but is not limited thereto, and may be provided on the shaft f of the imaging device. As a result, when the imaging device 4 rotates about the reference angle around the axis f by an angle of ± 90 ° or more, the control signal calculation unit 49 outputs the left and right image signals of the left and right eyes output from the imaging device 4. A switching control signal H for instructing switching and up / down inversion is sent to the image switching unit 30.

  Although the imaging support device 3 is configured to have the articulated arm 6 as shown in FIG. 6, the imaging support device 3 is not limited thereto, and may be configured as shown in FIG. 11, for example. The imaging support device 3 includes a base 50 and a moving end 51 is provided on the base 50. The moving end 51 is formed in a line shape, for example. The moving end 51 is provided with a moving member 52, and a fourth rotating shaft 47 is provided on the moving member 52 via a bellows member 53. The moving member 52 can move in a line along the moving end 51. The imaging device 4 is connected to the fourth rotating shaft 47 and an encoder 48 is provided. As described above, the imaging device 4 can rotate about the axis e and can rotate about the axis f.

  The bellows member 53 is formed of, for example, a flexible holding member. As a result, the bellows member 53 is bent and held by the flexible holding member of the bellows member 53, so that the imaging direction of the imaging device 4 is set to a direction in which the operator Q wants to image the surgical part 2, for example. Is possible.

Next, a third embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 3 and 6 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 12 shows a configuration diagram of the imaging support apparatus 3 in the electronic image observation apparatus. The imaging device 4 is provided with a memory switch (memory SW) 60. This memory switch 60 is provided, for example, for storing the initial direction of the imaging direction of the imaging device 4 before the start of surgery. Even if the arrangement position of the imaging device 4 is the same depending on the surgical environment, surgical technique, etc. of the operator Q, the positional relationship of the imaging device 4 with respect to the articulated arm 6 differs depending on the style (angle) of the articulated arm 6. For example, as shown in FIG. 13, the imaging directions F1, F2,..., F6, etc., that is, the angles around the axis e of the imaging device 4 are different.

  However, before starting the operation, the present apparatus stores initial angle data such as the imaging directions F1, F2,..., F6 as the initial direction of the imaging apparatus 4, that is, data of angles around the axis e of the imaging apparatus 4. When the imaging device 4 is stored by an operation on the switch 60 and the imaging device 4 rotates about the initial angle within a range of angle ± 90 °, the left and right eyes output from the imaging device 4 to the image switching unit 30 from the control signal calculation unit 49 A switching control signal H for instructing the left / right switching and the up / down inversion of each image signal is sent out.

14 and 15 show the configuration diagram of the electrical system of this apparatus, FIG. 14 shows the configuration diagram in which the normal image is switched to the through state, and FIG. 15 shows the configuration diagram in which the image is switched to the inverted state. . 3 and FIG. 4 are denoted by the same reference numerals, and detailed description thereof is omitted.
The control signal output unit 32 includes an encoder 48, a control signal calculation unit 49, a memory switch 60, and a memory 61. The memory 61 stores data on the angle around the axis e of the imaging device 4 when the memory switch 60 is pushed.

  The control signal calculation unit 49 counts the pulse signal from the encoder 48, obtains the rotation angle of the imaging device 4 around the axis e from the counted value, and the imaging device 4 is centered on the initial angle stored in the memory 61. It is determined whether or not the angle has been rotated by a range of ± 90 ° or more. When the imaging device 4 is rotated by an angle of ± 90 ° or more around the initial angle, the left and right image signals of the left and right eyes output from the imaging device 4 are A switching control signal H for instructing the switching and the vertical reversal is sent to the image switching unit 30.

Next, the operation of the apparatus configured as described above will be described with reference to the switching determination flowchart shown in FIG.
In step # 10, the control signal output unit 32 determines whether or not the memory switch 60 is pushed and turned on. If the memory switch 60 is not pushed, the control signal output unit 32 waits for the memory switch 60 to be pushed.

  Before starting the operation, the operator Q pushes the memory switch 60 to operate. As a result, the control signal output unit 32 determines that the memory switch 60 has been pressed and turned on (ON), and proceeds to step # 11. When the memory switch 60 is pressed, the pulse signal from the encoder 48 is detected. And the rotation angle around the axis e of the articulated arm 6 is obtained from the counted value, and this rotation angle is stored in the memory 61 as initial angle data around the axis e of the articulated arm 6. Since the count value of the pulse signal from the encoder 48 and the rotation angle around the axis e of the articulated arm 6 are in a corresponding relationship, the rotation angle around the axis e of the articulated arm 6 is calculated from the count value of the pulse signal. It is possible to ask.

  The operator Q changes the imaging direction of the imaging device 4 according to the technique for the surgical operation 2. The imaging device 4 rotates around the axis e by changing the imaging direction of the imaging device 4. At this time, the encoder 48 outputs a pulse signal corresponding to the rotation angle of the fourth rotation shaft 47 that rotates about the axis e. This pulse signal takes a positive or negative value according to the rotation direction of the fourth rotation shaft 47.

  In step # 12, the control signal calculation unit 49 counts positive or negative pulse signals output from the encoder 48, reads the initial angle data stored in the memory 61, and the imaging device 4 moves around the axis e. It is determined whether or not the angle is rotated by ± 90 ° or more around the initial angle.

  As a result of this determination, if the imaging device 4 does not rotate about the initial angle around the axis e by an angle of ± 90 ° or more, the image switching unit 30 is shown in FIG. 14 as in the first embodiment. Thus, the left and right eye image signals output from the imaging device 4 are in a normal state in which the left and right are not interchanged, and the image signal output from the left eye image sensor 20L is the L-side CCU 9L, the L-side switching end. 33, and sent to the left eye image rotation unit 31L through the through terminal 34. At the same time, the image signal output from the right-eye image sensor 20R is sent to the right-eye image rotation unit 31R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

  However, the left-eye image rotating unit 31L passes through the through-terminal 34 without rotating the image signal of the left eye of the imaging device 4, and the right-eye image rotating unit 31 </ b> R is connected to the imaging device 4 from the through terminal 37. Through without rotating the image signal of the right eye. As a result, a stereoscopic image of the subject including the operation part 2 is displayed on the stereoscopic display device 8.

  On the other hand, depending on the technique for the surgical site 2, the operator Q may rotate the imaging device 4 around the axis e around the initial angle by a range of angle ± 90 ° or more. Thus, when the imaging device 4 is rotated about the reference angle around the axis e by an angle of ± 90 ° or more, the arrangement of the imaging elements 20L and 20R for the left and right eyes compared to the imaging direction of the initial imaging device 4 Are switched and the vertical direction is also reversed.

  In such a case, the control signal calculation unit 49 determines in step # 12 that the imaging device 4 has rotated about the initial angle around the axis e by an angle of ± 90 ° or more. As a result of this determination, the control signal calculation unit 49 moves to step # 13, and the switching control signal H for instructing the left / right switching of the left and right eye image signals output from the imaging device 4 and the up / down inversion. Is sent to the image switching unit 30.

  Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

  The left-eye image rotation unit 31L rotates the right-eye image signal input from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. At the same time, the right-eye image rotation unit 31R rotates the left-eye image signal input from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  When the imaging device 4 returns again within the range of angle ± 90 ° around the initial angle around the axis e, the control signal calculation unit 49 stops sending the switching control signal H. As a result, the image switching unit 30 switches the L-side switching end 33 to the through terminal 34 and the R-side switching end 36 to the through terminal 37 as shown in FIG.

  As described above, according to the third embodiment, the data of the initial angle around the axis e of the imaging device 4 is stored in the memory 61, and the imaging device 4 is in the range of the angle ± 90 ° or more around the initial angle. When rotated, the control signal calculation unit 49 sends a switching control signal H for instructing the left and right switching of the left and right image signals output from the imaging device 4 to the image switching unit 30 and the inversion in the vertical direction. To do.

  As a result, the same effects as those of the first embodiment can be obtained, and the imaging device 4 can be arranged at the same placement position even if the placement position is the same depending on the surgical environment or the surgical procedure of the operator Q. For example, as shown in FIG. 13, the angle around the axis e is the approach direction of the imaging device 4 by the articulated arm 6 such as the imaging directions F1, F2,..., F6, and the style (angle) of the articulated arm 6 Depends on etc. As described above, even when the angle around the axis e of the imaging device 4 is different at the time of starting surgery or the like, the left and right switching of the left and right image signals output from the imaging device 4 with reference to this initial angle and the up / down inversion are performed. On the stereoscopic display device 8, a stereoscopic image in the same vertical and horizontal directions as the vertical and horizontal directions of the surgical part 2 on which the operator Q is performing surgery is displayed.

Next, a fourth embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 3 and 6 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 17 is a configuration diagram of the imaging support device 3 in the electronic image observation device. In addition to providing the encoder 48 on the fourth rotary shaft 47 that supports the imaging device 4, the imaging support device 3 includes encoders 70 to 73 around the other rotary shafts a to d and f. Yes.

The first encoder 70 is provided on the first rotating shaft 40 and outputs a pulse signal corresponding to the rotation angle of the first rotating shaft 40 that rotates about the axis a. The pulse signal output from the first encoder 70 has a positive or negative value depending on the rotation direction of the first rotating shaft 40.
The second encoder 71 is provided on the second rotating shaft 41 and outputs a pulse signal corresponding to the rotation angle of the second rotating shaft 41 rotating around the axis b. The pulse signal output from the second encoder 71 has a positive or negative value depending on the rotation direction of the second rotating shaft 41.

The third encoder 72 is provided on the third rotating shaft 43 and outputs a pulse signal corresponding to the rotation angle of the third rotating shaft 43 that rotates about the axis c. The pulse signal output from the third encoder 72 has a positive or negative value depending on the rotation direction of the third rotation shaft 43.
The fourth encoder 73 is provided on the second arm 44 and outputs a pulse signal corresponding to the rotation angle of the second arm 44 that rotates about the axis d. The pulse signal output from the fourth encoder 73 has a positive or negative value depending on the rotation direction of the second arm 44.

The encoder 48 is a fifth encoder 48.
The sixth encoder 74 is provided on the axis f of the imaging apparatus body, and outputs a pulse signal corresponding to the rotation angle of the imaging apparatus body that rotates about the axis f. The pulse signal output from the sixth encoder 74 has a positive or negative value depending on the rotation direction of the imaging apparatus main body.

FIG. 18 shows a specific configuration diagram of the control signal output unit 32. The control signal output unit 32 includes first to sixth encoders 70 to 73, 48 and 74, a control signal calculation unit 49, a memory switch 60, and a memory 61. The memory 61 stores data of initial angles around the axes a, b,..., F of the multi-joint arm 6 when the memory switch 60 is pushed.
The control signal calculation unit 49 3 of the initial imaging device 4 at the start of surgery or the like based on the data of the initial angles around the axes a, b,..., F of the articulated arm 6 stored in the memory 61. The dimension imaging direction is obtained.
The control signal calculation unit 49 counts each pulse signal from the first to sixth encoders 70 to 73, 48, and 74 during the operation, and each of the circumferences of the axes a, b,. The rotation angle is obtained, and the three-dimensional imaging direction of the imaging device 4 is obtained based on the rotation angles around these axes a, b,.
The control signal calculation unit 49 compares the three-dimensional imaging direction of the initial imaging device 4 at the start of surgery or the like with the three-dimensional imaging direction of the imaging device 4 during surgery, and 3 of the imaging device 4 during surgery. The amount of change in the three-dimensional space from the initial time such as the start of surgery in the three-dimensional imaging direction is obtained, and the three-dimensional imaging direction of the imaging device 4 is rotated by an angle of ± 90 ° or more around the initial imaging direction Then, a switching control signal H for instructing left / right switching and up / down inversion of the image signals of the left and right eyes output from the imaging device 4 is sent to the image switching unit 30.

Next, the operation of the apparatus configured as described above will be described according to the switching determination flowchart shown in FIG.
In step # 20, the control signal output unit 32 determines whether or not the memory switch 60 is pressed and turned on. If the memory switch 60 is not pushed, the control signal output unit 32 waits for the memory switch 60 to be pushed.

  Before starting the operation, the operator Q pushes the memory switch 60 to operate. As a result, the control signal output unit 32 determines that the memory switch 60 is pushed and turned on (ON), moves to step # 21, and when the memory switch 60 is pushed, The pulse signals from the encoders 70 to 73, 48, and 74 are counted, and the rotation angles around the axes a, b,..., F of the articulated arm 6 are obtained from the counted values. Stored in the memory 61 as initial angle data around the axes a, b,..., F of the joint arm 6.

  The operator Q changes the imaging direction of the imaging device 4 according to the technique for the surgical operation 2. By changing the imaging direction of the imaging device 4, the imaging device 4 rotates around the axes a, b,. At this time, the first encoder 70 outputs a positive or negative pulse signal corresponding to the rotation angle of the first rotating shaft 40 that rotates about the axis a. The second encoder 71 outputs a positive or negative pulse signal corresponding to the rotation angle of the second rotating shaft 41 that rotates about the axis b. The third encoder 72 outputs a positive or negative pulse signal corresponding to the rotation angle of the third rotating shaft 43 that rotates about the axis c. The fourth encoder 73 outputs a positive or negative pulse signal corresponding to the rotation angle of the second arm 44 that rotates about the axis d. The fifth encoder 48 outputs a positive or negative pulse signal corresponding to the rotation angle of the fourth rotation shaft 47 that rotates about the axis e. The sixth encoder 74 outputs a positive or negative pulse signal corresponding to the rotation angle of the imaging apparatus main body that rotates about the axis f.

  The control signal calculation unit 49 counts each positive or negative pulse signal output from each of the first to sixth encoders 70 to 73, 48, and 74 in step # 22, and stores it in the memory 61. Each initial angle data is read out, and it is determined whether or not the imaging device 4 has rotated about the initial angle around each axis a, b,.

  If the result of this determination is that the imaging device 4 has not rotated about the initial angle around the axes a, b,... F by ± 90 ° or more, as in the first embodiment, the image switching unit For example, as shown in FIG. 14, the left and right eye image signals output from the imaging device 4 are in a normal state where the left and right images are not interchanged, and the image signal output from the left eye image sensor 20L is L The image is sent to the left-eye image rotation unit 31L through the side CCU 9L, the L-side switching end 33, and the through terminal 34. At the same time, the image signal output from the right-eye image sensor 20R is sent to the right-eye image rotation unit 31R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

  However, the left-eye image rotating unit 31L passes through the through-terminal 34 without rotating the image signal of the left eye of the imaging device 4, and the right-eye image rotating unit 31 </ b> R is connected to the imaging device 4 from the through terminal 37. Through without rotating the image signal of the right eye. As a result, a stereoscopic image of the subject including the operation part 2 is displayed on the stereoscopic display device 8.

  On the other hand, depending on the technique for the operation on the surgical site 2, the operator Q may rotate the imaging device 4 around the axes a, b,. As described above, when the imaging device 4 is rotated about the reference angle around the axes a, b,..., F by an angle of ± 90 ° or more, each of the left and right eyes is compared with the imaging direction of the initial imaging device 4. The arrangement of the image sensors 20L and 20R is switched, and the vertical direction is also reversed.

  In such a case, the control signal calculation unit 49 determines in step # 22 that the imaging device 4 has rotated about the initial angle around each axis a, b,. As a result of this determination, the control signal calculation unit 49 proceeds to step # 23, and the switching control signal H for instructing the left and right switching of the left and right eye image signals output from the imaging device 4 and the up / down inversion. Is sent to the image switching unit 30.

  Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The normal through terminal 37 is switched to the switching terminal 38.

  The left-eye image rotation unit 31L rotates the right-eye image signal input from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. At the same time, the left-eye image rotation unit 31L rotates the right-eye image signal input from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  When the imaging device 4 returns again within the range of angle ± 90 ° around the initial angle around the axis e, the control signal calculation unit 49 stops sending the switching control signal H. As a result, the image switching unit 30 switches the L-side switching end 33 to the through terminal 34 and the R-side switching end 36 to the through terminal 37 as shown in FIG.

  As described above, according to the fourth embodiment, the initial angle data around the axes a, b,..., F of the articulated arm 6 are stored in the memory 61, and based on the initial angle data. The three-dimensional imaging direction of the initial imaging device 4 at the start of surgery is obtained, and each axis a, from each count value of each pulse signal from the first to sixth encoders 70 to 73, 48, 74 during surgery. Based on the rotation angles around b,..., f, the three-dimensional imaging direction of the imaging device 4 is obtained, the initial three-dimensional imaging direction of the imaging device 4 at the start of surgery, and the imaging device 4 during surgery. The three-dimensional imaging direction is compared with the three-dimensional imaging direction, the amount of change in the three-dimensional space from the initial stage of the imaging device 4 during the operation, such as when surgery is started, is obtained. Rotate more than the range of angle ± 90 ° around the initial imaging direction Then, the switching control signal H for instructing the left / right switching and the up / down inversion of the left and right image signals output from the imaging device 4 is sent to the image switching unit 30.

  As a result, the same effects as those of the first embodiment can be obtained, and the three-dimensional imaging direction of the imaging device 4 is rotated by an angle of ± 90 ° or more around the initial imaging direction. Even if the arrangement of the imaging elements 20L and 20R for the left and right eyes is interchanged and the vertical direction is reversed as compared with the arrangement of the imaging apparatus 4, the operator Q is performing an operation on the stereoscopic display apparatus 8. The same three-dimensional image in the vertical and horizontal directions as the vertical and horizontal directions of the surgical unit 2 is displayed.

Next, a fifth embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 3 and 6 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 20 shows a configuration diagram of an electrical system in which the normal image in the apparatus is switched to the through state, and FIG. 21 shows a configuration diagram of the electrical system in the apparatus in which the image is inverted.
The image control unit 10 includes a left eye recording circuit 80L and a right eye recording circuit 80R instead of the left and right image rotating units 31L and 31R.

  A through terminal 34 and a switching terminal 38 are connected to the left eye recording circuit 80L. When the left eye image signal is input from the through terminal 34 to the left eye recording circuit 80L, the left eye image signal is transmitted through the left eye image signal to the stereoscopic display device 8 without being rotated. Also, when the left eye recording circuit 80L receives the right eye image signal of the imaging device 4 from the switching terminal 38, the right eye image signal is rotated 180 degrees to change the vertical direction and send it to the stereoscopic display device 8. . Even if the right eye image signal of the imaging device 4 is input from the switching terminal 38, the left eye recording circuit 80L passes through the right eye image signal without rotation and sends it to the stereoscopic display device 8. It may be.

  Specifically, when the left eye recording circuit 80L does not receive the switching control signal H from the control signal output unit 32, the image signal of the left eye of the imaging device 4 from the through terminal 34 is shown in FIG. Are written in the order of “1”, “2”, “3”... “N” for each frame, and the left eye image signal in the same order as that for writing is “1”, “2”, “3” for each frame. ... Read out in the order of “n” and send to the stereoscopic display device 8. Thereby, the left eye recording circuit 80L passes through the image signal of the left eye of the imaging device 4 from the through terminal 34 without rotating it and sends it to the stereoscopic display device 8.

  When the switching control signal H is input from the control signal output unit 32, the left eye recording circuit 80L outputs the image signal of the right eye of the imaging device 4 from the switching terminal 38 for each frame as shown in FIG. “1” “2” “3”... “N” is recorded in the order of “n”, and the right eye image signal in the reverse order of writing is “n”... “3” “2” “1” for each frame. ”In the order of“ and sent to the stereoscopic display device 8. Thereby, the left eye recording circuit 80L rotates the image signal of the right eye of the imaging device 4 by 180 degrees and sends it to the stereoscopic display device 8.

  When the switching control signal H is not input from the control signal output unit 32, the right eye recording circuit 80R outputs the right eye image signal of the imaging device 4 from the through terminal 37 in the same manner as shown in FIG. Write in the order of “1”, “2”, “3”... “N” for each frame, and the same order as that at the time of writing, that is, “1”, “2”, “3” for the right eye image signal for each frame. ... Read out in the order of “n” and send to the stereoscopic display device 8. Thereby, the right eye recording circuit 80R passes through the image signal of the right eye of the imaging device 4 from the through terminal 37 without rotating it and sends it to the stereoscopic display device 8.

  When the switching control signal H is input from the control signal output unit 32, the right-eye recording circuit 80R outputs the image signal of the left eye of the imaging device 4 from the switching terminal 35 at the time of writing, as shown in FIG. Recording is performed in the order of “1”, “2”, “3”... “N” for each frame, and the image signal of the left eye which is in the reverse order of writing is “n” to “3” “ 2 ”and“ 1 ”are read out and sent to the stereoscopic display device 8. As a result, the right eye recording circuit 80R rotates the image signal of the left eye of the imaging device 4 by 180 degrees and sends it to the stereoscopic display device 8.

Next, the operation of the apparatus configured as described above will be described.
When the imaging device 4 is arranged in an upright state as shown in FIG. 5A, the image switching unit 30 outputs each of the left and right eyes output from the imaging device 4 as in the first embodiment. The image signal is in a normal state in which the left and right of the image signal are not interchanged, and the image signal output from the left eye image pickup device 20L is sent to the left eye recording circuit 80L through the L side CCU 9L, the L side switching end 33, and the through terminal 34. It is done. At the same time, the image signal output from the right-eye image sensor 20R is sent to the right-eye image rotation unit 80R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

  However, when the switching control signal H is not input from the control signal output unit 32, the left eye recording circuit 80L outputs the image signal of the left eye of the imaging device 4 from the through terminal 37 as shown in FIG. “1” “2” “3”... “N” is written in the order of each frame, and the right eye image signal in the same order as that at the time of writing is “1” “2” “3”. n ”in the order of“ n ”and sent to the stereoscopic display device 8. As a result, the left eye recording circuit 80L passes through the image signal of the left eye of the imaging device 4 from the through terminal 34 without rotating it, and sends it to the stereoscopic display device 8.

At the same time, when the switching control signal H is not input from the control signal output unit 32, the right eye recording circuit 80R shows the right eye image signal of the imaging device 4 from the through terminal 37 at the time of writing as shown in FIG. Similarly to the above, writing is performed in the order of “1”, “2”, “3”... “N” for each frame, and the same order as that at the time of writing, that is, the right eye image signal is “1” “2” for each frame. The data are read out in the order of “3”... “N” and sent to the stereoscopic display device 8. As a result, the right eye recording circuit 80R passes through the image signal of the right eye of the imaging device 4 from the through terminal 37 without rotating it and sends it to the stereoscopic display device 8.
As a result, the stereoscopic display device 8 displays a stereoscopic image of the subject including the vertical / horizontal direction of the surgical unit 2 that is the same as the vertical / horizontal direction of the surgical unit 2 on which the operator Q is performing surgery.

On the other hand, when the operator Q pushes the image switching switch 26, the control signal output unit 32 instructs to switch left and right image signals of the left and right eyes output from the imaging device 4 and to invert in the vertical direction. A switching control signal H is sent to the image switching unit 30.
Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

  When the switching control signal H is input from the control signal output unit 32, the left eye recording circuit 80L outputs the image signal of the right eye of the imaging device 4 from the switching terminal 38 for each frame as shown in FIG. “1”, “2”, “3”... “N” are recorded in this order, and at the same time, the right-eye image signal in the reverse order to that at the time of writing is “n” to “3” “2” for each frame. The data are read out in the order of “1” and sent to the stereoscopic display device 8. Thereby, the left eye recording circuit 80L rotates the image signal of the right eye of the imaging device 4 by 180 degrees and sends it to the stereoscopic display device 8.

At the same time, when the switching control signal H is input from the control signal output unit 32, the right eye recording circuit 80R shows the image signal of the left eye of the imaging device 4 from the switching terminal 35 at the time of writing as shown in FIG. Similarly, “1”, “2”, “3”... “N” are recorded for each frame, and at the same time, the image signal of the left eye, which is in the reverse order of writing, is “n” for each frame. ... Read out in the order of “3”, “2”, and “1” and send them to the stereoscopic display device 8. Thereby, the right eye recording circuit 80R rotates the image signal of the left eye of the imaging device 4 by 180 degrees and sends it to the stereoscopic display device 8.
As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  When the imaging device 4 is again placed in the upright state as shown in FIG. 5A, the control signal calculation unit 49 stops sending the switching control signal H. As a result, the image switching unit 30 switches the L-side switching end 33 to the through terminal 34 and the R-side switching end 36 to the through terminal 37 as in the normal state shown in FIG.

  As described above, according to the fifth embodiment, when the switching control signal H is input from the control signal output unit 32, the left and right eye recording circuits 80L and 80R respectively write the left and right eyes of the imaging device 4 at the time of writing. Are recorded in the order of “1”, “2”, “3”,..., “N” for each frame, and the image signals of the left and right eyes, which are in the reverse order of writing, are “n” for each frame. ... “3”, “2”, and “1” in this order and sent to the stereoscopic display device 8.

As a result, the left and right eye image sensors 20L and 20R are arranged opposite to the left and right with respect to the normal left and right eye image sensors 20L and 20R, for example, as shown in FIGS. 5C and 5D. Even if the up and down directions of the left eye image sensor 20L and the right eye image sensor 20R are reversed, the operator Q has the same effect as the first embodiment, that is, the stereoscopic display device 8. Display a 3D image in which the uneven direction of the uneven shape of the surgical part 2 actually performing surgery and the uneven direction of the uneven shape of the surgical part in the stereoscopic image displayed on the stereoscopic display device 8 are the same direction. it can.
Note that the left-eye image rotation unit 31L and the right-eye image rotation unit 31R in the second to fourth embodiments may be replaced by the left and right eye recording circuits 80L and 80R, respectively.

Next, a sixth embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
24 and 25 are configuration diagrams showing the electrical system of the electronic image observation apparatus. FIG. 24 is switched to a state in which an image is inverted in the first display system, and FIG. 25 is a normal state in the first display system. The block diagram of the electric system which switched the image to the through state is shown.
The pair of left and right imaging elements 20L and 20R of the imaging device 4 are connected to the image control unit 10 through the L-side CCU 9L and the R-side CCU 9R, respectively, and the stereoscopic display device 8 is connected to the image control unit 10. The imaging device 4, the L-side CCU 9L, the R-side CCU 9R, the image control unit 10, and the stereoscopic display device 8 are set as a first display system.
A second display system is connected in parallel to the first display system. The second display system includes an image control unit 90 connected to the imaging device 4 through the L-side CCU 9L and the R-side CCU 9R, and a stereoscopic display device 91 connected to the image control unit 10.

The image control unit 90 includes an image switching unit 92, a left eye image rotation unit 93L, and a right eye image rotation unit 93R. Among these, a control signal output unit 94 is connected to the image switching unit 92. The control signal output unit 94 includes an image changeover switch 95.
When the control signal output unit 94 receives a manual operation on the image switching switch 95, the switching control signal H for instructing the left / right switching of the left and right image signals output from the imaging device 4 and the up / down inversion. Is sent to the image switching unit 92. Note that the control signal output unit 94 sends a switching control signal H for instructing either or both of left / right switching and up / down inversion of the left and right image signals of the imaging device 4. It may be a thing.

When the image switching unit 92 receives the switching control signal H from the control signal output unit 94, the image switching unit 92 swaps the left and right image signals of the left and right eyes output from the imaging device 4. Specifically, the image switching unit 92 includes an L-side switching end 96, a through terminal 97, and a switching terminal 98, and an R-side switching end 99, a through terminal 100, and a switching terminal 101.
The switching end 96 on the L side is normally connected to the through terminal 92 and switches to the switching terminal 98 when receiving the switching control signal H. The switching end 99 on the R side is normally connected to the through terminal 100 and switches to the switching terminal 101 when receiving the switching control signal H.

A through terminal 97 and a switching terminal 101 are connected to the left eye image rotation unit 93L. When the left eye image rotation unit 93 </ b> L receives the image signal of the left eye of the imaging device 4 from the through terminal 97, the image signal of the left eye is passed through without being rotated and sent to the stereoscopic display device 91.
Also, when the left eye image rotation unit 93L receives the right eye image signal of the imaging device 4 from the switching terminal 101, the left eye image rotation unit 93L rotates the right eye image signal by 180 degrees and changes the vertical direction to the stereoscopic display device 8. send. Even if the left-eye image rotation unit 93L receives the right-eye image signal of the imaging device 4 from the switching terminal 101, the left-eye image rotation unit 93L passes through the right-eye image signal without rotation and sends it to the stereoscopic display device 8. It may be.

A through terminal 100 and a switching terminal 101 are connected to the right eye image rotation unit 93R. When the right eye image signal of the imaging device 4 is input from the through terminal 100, the right eye image rotation unit 93 </ b> R passes through the right eye image signal without rotation and sends the image signal to the stereoscopic display device 91.
In addition, when the left eye image signal of the imaging device 4 is input from the switching terminal 101, the right eye image rotation unit 93 </ b> R rotates the left eye image signal by 180 degrees to change the vertical direction to the stereoscopic display device 8. send. Even if the right-eye image rotation unit 93R receives the left-eye image signal of the imaging device 4 from the switching terminal 101, the right-eye image rotation unit 93R passes through the left-eye image signal without rotation and sends it to the stereoscopic display device 91. It may be.

Next, the operation of the apparatus configured as described above will be described.
In the initial setting of the image switching unit 92, for example, as shown in FIG. 26, the operator Q and the observer G other than the operator Q face each other through the subject R on the bed 1, and the first display There are cases where the stereoscopic display device 8 of the system is provided facing the operator Q and the stereoscopic display device 91 of the second display system is provided facing the observer G.

  If the operator Q does not press and operate the image switching switch 26, the image switching unit 30 of the first display system is in a normal state in which the left and right image signals of the left and right eyes output from the imaging device 4 are not switched. is there. In this normal state, the image switching unit 30 transmits the image signal output from the left-eye image sensor 20L through the L-side CCU 9L, the L-side switching end 33, and the through terminal 34 as shown in FIG. The image is sent to the right eye image rotation unit 31R. At the same time, the image switching unit 30 sends the image signal output from the right-eye image sensor 20R to the right-eye image rotation unit 31R through the R-side CCU 9R, the R-side switching end 36, and the through terminal 37.

The left eye image rotation unit 31L passes through the left eye image signal without rotating it. At the same time, the right eye image rotation unit 31R passes through the right eye image signal without rotating it.
The image control unit 10 performs image processing on the left-eye image signal from the L-side CCU 9 </ b> L and the right-eye image signal from the R-side CCU 9 </ b> R to create stereoscopic image data, and sends this stereoscopic image data to the stereoscopic display device 8. As a result, a stereoscopic image of the subject including the operation part 2 is displayed on the stereoscopic display device 8.

  On the other hand, the second display system operates independently of the first display system. The imaging elements 25L and 25R of the imaging device 4 output left and right eye image signals for creating a stereoscopic image of the subject. The left and right eye image signals output from the imaging elements 25L and 25R are sent to the image switching unit 30 of the image control unit 10 of the first display system through the L-side CCU 9L and the R-side CCU 9R, respectively, and the second Also sent to the image switching unit 92 of the image control unit 90 of the display system.

  If the observer G does not press and operate the image switching switch 95, the image switching unit 92 of the second display system connects the L-side switching end 96 to the switching terminal 98 as shown in FIG. Are connected to the switching terminal 101. Accordingly, the left-eye image rotation unit 93L inputs the right-eye image signal of the imaging device 4 from the switching terminal 101, rotates the right-eye image signal by 180 degrees, and changes the vertical direction to change the stereoscopic display device 91. Send to. At the same time, the left-eye image rotation unit 93R inputs the right-eye image signal of the imaging device 4 from the switching terminal 98, rotates the right-eye image signal by 180 degrees, and changes the vertical direction to change the stereoscopic display device 91. Send to.

  The image control unit 10 performs image processing on the image signals of the left and right eyes rotated 180 degrees to create stereoscopic image data, and sends the stereoscopic image data to the stereoscopic display device 91. As a result, the stereoscopic display device 91 displays the same vertical and horizontal stereoscopic images as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  As shown in FIG. 26, the operator Q and the observer G are opposed to each other through the subject R, and the stereoscopic display device 8 and the stereoscopic display device 91 are both arranged opposite to the operator Q and the observer G. Therefore, the stereoscopic image data displayed on the stereoscopic display device 91 is obtained by changing the vertical direction by horizontally reversing the left and right eye image signals and rotating them 180 degrees.

On the other hand, when the operator Q pushes the image switching switch 26, the control signal output unit 32 instructs to switch left and right image signals of the left and right eyes output from the imaging device 4 and to invert in the vertical direction. A switching control signal H is sent to the image switching unit 30.
Upon receiving the switching control signal H, the image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

  By this switching, the left eye image rotation unit 31L rotates the right eye image signal of the imaging device 4 from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. At the same time, the left-eye image rotation unit 31L rotates the right-eye image signal of the imaging device 4 from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

When the observer R presses the image switching switch 26, the control signal output unit 94 performs switching control for instructing left / right switching and vertical reversal of the left and right image signals output from the imaging device 4. The signal H is sent to the image switching unit 92.
Upon receiving the switching control signal H, the image switching unit 92 switches the L-side switching end 96 from the switching terminal 98 to the normal through terminal 97 and the R-side switching end 99 as shown in FIG. 101 is switched to the normal through terminal 100.

  By this switching, the left eye image rotation unit 93L sends the image signal of the left eye of the imaging device 4 from the through terminal 97 to the stereoscopic display device 91 without rotating as it is. At the same time, the right eye image rotation unit 93R sends the image signal of the right eye of the imaging device 4 from the through terminal 100 to the stereoscopic display device 91 without rotating. As a result, the stereoscopic display device 91 displays a stereoscopic image in the same vertical and horizontal directions as the vertical and horizontal directions in which the observer R is observing the surgical part 2 performing the operation.

  As described above, according to the sixth embodiment, the first and second display systems are provided independently, and the second display system is also output from the imaging device 4 as in the first display system. The left and right image signals of the left and right eyes are switched by the image switching unit 90, the right eye image signal is rotated 180 degrees by the left eye image rotating unit 93L, and the left eye image signal is rotated by the right eye image rotating unit 93R. Rotate degrees. Thereby, the operator Q observes the stereoscopic image of the subject including the surgical unit 2 displayed on the stereoscopic display device 8 of the first display system, and is displayed on the stereoscopic display device 91 of the second display system together with this. An observer other than the operator Q can observe a stereoscopic image of the subject including the operation part 2.

  Since the first and second display systems are independent, the left and right switching and 180 degree rotation of the left and right image signals output from the imaging device 4 are separately performed for the first and second display systems. The operator Q and an observer other than the operator Q, for example, an observer such as an assistant, independently operate the image switching switches 26 and 95, so that the operator Q and an observer other than the operator Q can move to the operating room. Even if the arrangement position of the patient on the bed 1 with respect to the subject R is different, the surgeon Q and the observer other than the surgeon Q are each in the concave and convex direction of the concave and convex shape of the surgical part 2 that is actually performing the surgery. The three-dimensional images displayed on the three-dimensional display devices 8 and 91 can be observed with the unevenness in the same direction.

  In the sixth embodiment, the two systems of the first and second display systems are provided independently. However, the present invention is not limited to this, and two or more systems may be provided. Thereby, it is possible to observe a stereoscopic image of the surgical part 2 on which surgery is performed by a plurality of observers including the operator Q and observers other than the operator Q.

Next, a seventh embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 24 and 25 are denoted by the same reference numerals, and detailed description thereof is omitted.
27 and 28 are configuration diagrams showing the electrical system of the electronic image observation apparatus. FIG. 27 is a configuration diagram of the electrical system in which the normal image is switched to the through state in the first display system. Shows a configuration diagram of the electrical system in which the image is reversed in the first display system.
This apparatus has one control signal output unit 32 as compared with the sixth embodiment. When the control signal output unit 32 receives a manual operation on the image switching switch 26, the control signal output unit 32 instructs to switch left and right image signals of the left and right eyes output from the imaging device 4 and to invert in the vertical direction. H is sent to the two image switching units 30 and 92, respectively.

Next, the operation of the apparatus configured as described above will be described.
When the operator Q pushes the image switching switch 26, the control signal output unit 32 performs switching control for instructing left / right switching and vertical reversal of the left and right image signals output from the imaging device 4. The signal H is sent to the two image switching units 30 and 92, respectively.
Upon receiving the switching control signal H, one image switching unit 30 switches the L-side switching end 33 from the normal through terminal 34 to the switching terminal 35 and the R-side switching end 36 as shown in FIG. The through terminal 37 is switched to the switching terminal 38.

  By this switching, the left eye image rotation unit 31L rotates the right eye image signal of the imaging device 4 from the switching terminal 38 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. At the same time, the right eye image rotation unit 31R rotates the image signal of the left eye of the imaging device 4 from the switching terminal 35 by 180 degrees, changes the vertical direction, and sends it to the stereoscopic display device 8. As a result, the stereoscopic display device 8 displays a stereoscopic image in the vertical and horizontal directions that is the same as the vertical and horizontal directions of the surgical unit 2 on which the operator Q is performing surgery.

  At the same time, when receiving the switching control signal H, the other image switching unit 92 switches the L-side switching terminal 96 from the normal through terminal 97 to the switching terminal 98 and switches the R-side as shown in FIG. The end 99 is switched from the normal through terminal 100 to the switching terminal 101.

  By this switching, the left eye image rotation unit 93L sends the image signal of the right eye of the imaging device 4 from the switching terminal 101 to the stereoscopic display device 91 without rotating as it is. At the same time, the right eye image rotation unit 93R sends the image signal of the right eye of the imaging device 4 from the through terminal 100 to the stereoscopic display device 91 without rotating. As a result, the stereoscopic display device 91 displays a stereoscopic image in the same vertical and horizontal directions as the vertical and horizontal directions in which the observer R is observing the surgical part 2 performing the operation.

  As described above, according to the seventh embodiment, the first and second display systems are provided independently, and the control signal output unit 32 is provided as one unit. When a manual operation is received, a switching control signal H for instructing left / right switching and up / down inversion of the left and right image signals output from the imaging device 4 is sent to the two image switching units 30 and 92, respectively. Send it out. Thereby, the switching control signal H can be sent simultaneously to the first and second display systems, and the left and right and up and down directions of the stereoscopic images displayed on the two stereoscopic display devices 8 and 91 can be switched simultaneously. Can do.

Hereinafter, other features of the present invention will be described.
[Additional Item 1]
An imaging apparatus having an observation optical system including a pair of left and right imaging elements;
Display means for displaying a pair of images obtained by the imaging device;
In an electronic image observation apparatus comprising:
Image switching means for switching each of a pair of left and right images acquired from the imaging device based on the arrangement of the imaging device;
Image rotating means for rotating and outputting each image up and down with respect to a pair of left and right images acquired from the image sensor based on the arrangement of the imaging device;
An electronic image observation apparatus comprising:

[Additional Item 2]
The electronic image observation apparatus according to claim 1, further comprising a control signal output unit that outputs a signal for simultaneously operating the image switching unit and the image rotation unit.

[Additional Item 3]
The imaging device further includes a joint mechanism that holds the imaging device,
The control signal output unit outputs a control signal according to an angle of the joint mechanism;
Item 3. The electronic image observation apparatus according to Item 2, wherein

[Additional Item 4]
The joint mechanism has detection means for detecting an angle of the joint mechanism,
The control signal output unit outputs a control signal based on a detection result of the detection means;
Item 3. The electronic image observation apparatus according to Item 3, wherein

[Additional Item 5]
The joint mechanism comprises a multi-joint arm,
Detection means for detecting an angle in a joint is provided in at least two of the multi-joint arms.
Item 5. The electronic image observation apparatus according to Item 4, wherein

[Additional Item 6]
The detection means has a recording unit for recording a detection result,
The control signal output unit outputs a control signal based on the detection result recorded in the recording unit;
Item 6. The electronic image observation apparatus according to item 4 or 5, characterized by this.

[Additional Item 7]
The electronic image observation apparatus according to any one of additional items 1 to 6, wherein the imaging apparatus includes a polarization unit that bends an optical axis of the observation optical system in the observation optical system.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  Q: surgeon, R: subject, 1: bed, 2: surgical part, 3: imaging support device, 4: imaging device, 5: support column, 6: articulated arm, 7: holding arm, 8: solid Display device, 8a: display panel, 9L: left eye side communication control unit (L side CCU), 9R: right eye side communication control unit (R side CCU), 10: image control unit, 20: main body of imaging device, 21: objective Optical system, 22: deflection element, 23: variable magnification optical system, 24: imaging optical system, 25L, 25R: pair of left and right eye imaging elements, 26: image changeover switch, 30: image changeover unit, 31L: left eye image Rotating unit, 31R: Right eye image rotating unit, 32: Control signal output unit, 33: L side switching end, 34: Through terminal, 35: Switching terminal, 36: R side switching end, 37: Through terminal, 38 : Switching terminal, 40: first rotating shaft, 41: second Rotation shaft, 42: first arm, 43: third rotation shaft, 44: second arm, 45: fourth rotation shaft, 46: third arm, 47: fourth rotation shaft, 48: Encoder, 49: control signal calculation unit, 50: base, 51: moving end, 52: moving member, 53: bellows member, 60: memory switch (memory SW), 61: memory, 70: first encoder, 71: second encoder, 72: third encoder, 73: fourth encoder, 74: sixth encoder, 80L: left eye recording circuit, 80R: right eye recording circuit, 90: image control unit, 91: 3D display device, 92: image switching unit, 93L: left eye image rotating unit, 93R: right eye image rotating unit, 94: control signal output unit, 95: image switching switch, 96: L side switching end, 97: through Terminal 98: Switching Child, 99: the R-side switching terminal, 100: through-pin, 101: switch terminal.

Claims (9)

An imaging apparatus having an observation optical system including a pair of left and right imaging elements;
A joint mechanism in which a tip is rotatably provided and the imaging device is provided at the tip;
A rotation angle output means provided at the tip of the joint mechanism, for outputting a signal corresponding to the rotation angle of the tip of the joint mechanism;
A control signal output unit for sending a switching control signal when the distal end of the joint mechanism rotates more than a predetermined angle range around a reference angle based on an output signal of the rotation angle output means;
Image switching means for receiving the switching control signal sent from the control signal output unit and replacing each of a pair of left and right image signals acquired from the imaging element in the imaging device;
When each of the pair of left and right image signals is exchanged by the image switching unit, an image rotation unit that rotates each of the pair of left and right image signals to change the vertical direction;
A display device for displaying the pair of left and right image signals output through the image switching means and the image rotation means;
An electronic image observation apparatus comprising: The joint mechanism is composed of a multi-joint arm having a plurality of rotation axes,
The rotation angle output means is provided on each of the other rotation shafts in addition to the rotation shaft at the tip of the joint mechanism,
The image switching means and the image rotation means are controlled based on the rotation angle of each rotation axis of the articulated arm based on the output signal of the rotation angle output means, respectively.
The electronic image observation apparatus according to claim 1. Wherein the image switching means, and an electronic image viewing apparatus according to claim 1, wherein the input means for controlling the image rotation unit provided on the imaging device. The image rotation means has a through terminal and a switching terminal, and when the pair of left and right image signals are input from the through terminal, the pair of left and right image signals are passed through without rotating, and from the switching terminal 2. The electronic image observation apparatus according to claim 1, wherein when the pair of left and right image signals are input, the pair of left and right image signals are rotated 180 degrees to change the vertical direction . The control signal output unit stops sending the switching control signal when the tip of the joint mechanism returns within a predetermined angle range around a reference angle based on an output signal of the rotation angle output means. The electronic image observation apparatus according to claim 1 . The predetermined angular range, electronic image observation apparatus according to claim 1 or 5, wherein the an angle ± 90 °. The stereoscopic display device includes at least two or more.
At least one of the three-dimensional display devices displays the pair of left and right image signals output through the image switching unit and the image rotation unit based on the arrangement of the imaging device.
The electronic image observation apparatus according to claim 1. The stereoscopic display device includes at least two or more.
All of these stereoscopic display devices display the pair of left and right image signals output through the image switching unit and the image rotation unit based on the arrangement of the imaging device.
The electronic image observation apparatus according to claim 1. The electronic image observation apparatus according to claim 1, wherein the rotation angle output means is an encoder.

Images