JP2004041401A - Electronic endoscopic instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive operation switch part of a good operability while trying to reduce the weight of an electronic scope by reducing the weight of the operation switch part of the electronic scope. <P>SOLUTION: This electronic endoscopic instrument is equipped with the electronic scope equipped with the operation part for operating the electronic endoscopic instrument, and a processor which is electrically connected with the electronic scope. In the electronic endoscopic instrument, the operation part has a plurality of sheet-form switch parts which are provided at specified locations. Each of a plurality of the switch parts has functions for operating the electronic endoscopic instrument. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electronic endoscope apparatus used for observing a lumen such as a body cavity.
[0002]
[Prior art]
In general, a medical electronic endoscope apparatus for observing the inside of a body cavity includes a processor having a light source unit, an image processing unit, and the like, and an imaging device that performs imaging by illuminating the inside of the body cavity with a flexible tube. And an electronic scope at the tip. The electronic scope has a connection portion with a processor, an insertion portion inserted into the body of the subject, a tip portion for imaging the inside of the body cavity of the subject via an objective lens, and And an operation unit for performing operations.
[0003]
In general, the electronic endoscope apparatus configured as described above can execute various functions by operating switches arranged on the front panel of the processor. In recent electronic scopes, a plurality of operation switches corresponding to predetermined functions are provided in the operation unit, and only the operation switch of the operation unit is operated without operating a switch provided in the processor. The function can be executed by an operation. Further, the operator can arbitrarily select and assign a frequently used function to each operation switch unit.
[0004]
FIG. 1 is a diagram showing an example of the configuration of a conventionally used electronic scope 100za. As shown in FIG. 1A, the electronic scope 100za includes a connection unit 20 for connection with a processor, an operation unit 30 that is held by an operator to perform a predetermined operation, and an insertion unit that is inserted into a body cavity of a subject. 40 and a distal end 50 for imaging the inside of the body cavity of the subject via an objective lens.
[0005]
As shown in FIG. 1B, the operation section 30z is roughly composed of an operation means 31z that can operate the electronic endoscope apparatus, a left and right angle knob 35, and an up and down angle knob 36. The operation unit 31z has operation switch units 32za to 32zc as a plurality of operation units. The operation switch section is constituted by a mechanical switch. By the operation of the operation means 31z, operations such as air / water supply, suction, treatment with a treatment tool, and the like can be performed. The insertion portion 40 is a flexible tube. By turning the left and right angle knobs 35 and the up and down angle knobs 36, the insertion portion 40 bends, and the direction of the distal end portion 50 changes. Therefore, the operator can obtain necessary image information by turning each angle knob.
[0006]
FIG. 2 is a diagram illustrating a configuration of the operation switch unit 32z including a mechanical switch. The operation switch unit 32z includes a key top 33za, a spring 33zb, an elastic contact piece 33zc, and a fixed contact piece 33zd. The spring 33zb is pressed against the key top 33za by an outer frame (not shown). The elastic contact piece 33zc and the fixed contact piece 33zd are provided from the base substrate 33ze.
[0007]
When the operator presses the key top 33za, the spring 33zb is compressed. Further, the elastic contact piece 33zc is pressed by the key top 33za and is elastically deformed. When the elastic contact piece 33zc is elastically deformed, the elastic contact piece 33zc comes into contact with the fixed contact piece 33zd, so that the operation switch section 32z is turned on (on). When the operator stops pressing the key top 33za, the key top 33za returns to a state before being pressed by the elastic force of the spring 33zb. Further, the elastic contact piece 33zc returns to the state before being pressed in the same manner as the key top 33za. Since the elastic contact piece 33zc and the fixed contact piece 33zd are not in contact with each other, the operation switch section 32z is in a non-conductive state (off state).
[0008]
As described above, the mechanical switch requires a large number of parts, and thus has disadvantages such as an increase in cost and an increase in weight. The operator always holds the electronic scope during the examination. When the operation switch section of the electronic scope is constituted by a large number of mechanical switches, the weight of the electronic scope is increased, and there is a problem that the burden on the operator increases. Further, in the case of a mechanical switch, the degree of freedom in the number and arrangement of switches that can be arranged is low in an operation unit having a size that can be gripped. Therefore, the operator may feel dissatisfied with the operability depending on the number of switches and the arrangement of the switches.
[0009]
[Problems to be solved by the invention]
In view of the above circumstances, an object of the present invention is to reduce the weight of an electronic scope by reducing the weight of an operation switch section of the electronic scope. Still another object of the present invention is to provide an electronic endoscope apparatus having an electronic scope having an inexpensive and easy-to-operate operation switch unit while achieving weight reduction.
[0010]
[Means for Solving the Invention]
For this reason, the electronic endoscope apparatus according to claim 1 includes an electronic scope including an operation section for operating the electronic endoscope apparatus, and a processor electrically connected to the electronic scope. In the endoscope device, the operation unit has a plurality of sheet-shaped switch units provided at predetermined positions, and a function for operating the electronic endoscope device is set in each of the plurality of switch units. It is characterized by the following. By configuring the operation unit in this manner, the weight of the electronic scope can be reduced. Therefore, the burden on the operator is reduced. Further, cost can be reduced.
[0011]
In the electronic endoscope apparatus according to claim 2, lighting means is provided corresponding to each of the plurality of sheet-like switch sections, and the switch section operated when each of the plurality of sheet-like switch sections is operated. It is characterized in that the corresponding lighting means is configured to light. By configuring the switch unit in this manner, the operation state can be visually confirmed, and thus erroneous operation can be prevented.
[0012]
The electronic endoscope device according to claim 3, comprising: an electronic scope including an operation unit for operating the electronic endoscope device; and a processor electrically connected to the electronic scope. In the device, the operation unit has a switch area at a predetermined position, and in the switch area, any number of switch units can be set to any position. A function for operating the endoscope apparatus is set. By configuring the operation unit in this manner, an arbitrary number of switch units can be set at arbitrary positions, so that an electronic endoscope apparatus with improved operability can be provided.
[0013]
An electronic endoscope apparatus according to a fourth aspect is characterized in that an arbitrary one of a plurality of operation functions can be assigned to each of the switch units. By configuring the electronic endoscope apparatus in this manner, an arbitrary function can be set in each of the switch units, and thus an electronic endoscope apparatus with improved operability can be provided.
[0014]
An electronic endoscope apparatus according to a fifth aspect is characterized in that the same operation function can be assigned to different switch units. By configuring the electronic endoscope apparatus in this manner, a switch having a certain function can be arbitrarily assigned to an area where the operator can easily operate according to the size of the operator's hand or finger. . Therefore, the possibility that the operator makes an operation error is reduced, and an erroneous operation can be prevented.
[0015]
An electronic endoscope apparatus according to a sixth aspect is characterized in that when at least two switch units to which different functions are assigned are operated, none of the different functions is executed. By configuring the electronic endoscope apparatus in this manner, even when the operator operates a plurality of switch units to which different functions are assigned by mistake, none of the functions of the switch units is executed, thereby preventing erroneous operation. can do.
[0016]
An electronic endoscope apparatus according to a seventh aspect is characterized in that the plurality of operation functions have a function of locking the operation of the electronic endoscope. By configuring the electronic endoscope apparatus in this manner, when the function is executed, even if the operator operates the switch unit by mistake, the operated function is locked, so that an erroneous operation is performed. Can be prevented.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 4 is a diagram illustrating a schematic configuration of the electronic endoscope apparatus 100 according to the present embodiment. The electronic endoscope device 100 includes an electronic scope 100a, a processor 100b, a monitor 100c, and a keyboard 100d. The electronic scope 100a has a CCD 160 at the tip. Further, the electronic scope 100a includes a light guide 150, an operation unit 30, a CPU 180 that receives a signal from the operation unit 30, and a memory 181. The processor 100b has a main control unit 120, a light source unit 130, an image processing circuit 140, and a front panel 170. In addition, an external recording device such as a printer can be connected.
[0018]
FIG. 3 is a diagram illustrating a configuration of an electronic scope 100a in which an operation unit 30 includes an operation unit 31 in the electronic endoscope apparatus 100 according to the first embodiment. In the electronic scope 100a, the same components as those of the conventional electronic scope 100za shown in FIG. 1 are denoted by the same reference numerals, and a detailed description thereof will be omitted. The electronic scope 100a has a plurality of operation switches. In the first embodiment, as shown in FIG. 3B, the operation means 31 has three operation switches 32a to 32c. The operation switches 32a to 32c of the first embodiment are configured by sheet switches. As will be described later, the seat switch can have a lightweight configuration, and the number of switches that can be arranged and the degree of freedom of arrangement are higher than those of a mechanical switch. Here, in the operation switches 32a to 32c, the endoscope image displayed on the monitor screen is frozen (frozen), the still image is printed by a video printer, the moving image is video-recorded, and the illumination light amount is adjusted as in the related art. And operations such as color tone adjustment. Signal cables independent of each other extend from the operation switch units 32a to 32c, and each cable is connected to ports P1 to P3 of the CPU 180. (See Fig. 4)
[0019]
The electronic endoscope apparatus 100 has a plurality of functions such as the above-described still image display, printing of a still image, recording of a moving image, adjustment of illumination light amount, and color tone adjustment. All of these functions can be operated on the front panel 170. Before the endoscope observation, the operator uses the external input means such as the keyboard 100d to operate the operation switch units 32a to 32c on any of the above functions (for example, the frequency of use for the operator). High function) can be assigned. This allows the functions assigned to the operation switches 32a to 32c to be operated from the electronic scope 100a, thereby improving the operability of the operator. The functions assigned to the operation switches 32a to 32c are stored in the memory 181 as function data.
[0020]
Since the surgeon can assign any function to the operation switch units 32a to 32c, the same function can be assigned to adjacent operation switch units. In other words, a switch having a certain function can be arbitrarily changed to a region where the operator can easily press, in accordance with the size of the part of the operator who operates the operation switch unit, such as the hand or finger. Therefore, the operability is improved, and the possibility of the operator making an operation error is reduced, so that an erroneous operation can be prevented.
[0021]
Further, the operator can assign a function of locking the operation switch unit to one of the operation switch units 32a to 32c so that the operated function is not executed even if the switch is operated. When this function is executed, even if the operator operates the operation switch unit by mistake, the operated function is not executed, so that an operation error of the operator can be prevented. When this function is off, if the switch to which this function is assigned is pressed twice, or if the switch is kept pressed for a certain period of time, the switch is turned on and the operation by the operation switch unit is not executed. When this function is on, if the same operation as when it is turned on is performed, the switch is turned off, the lock of the operation switch unit is released, and the operation by the operation switch unit can be executed. In addition, by assigning this function to the operation switch unit provided at the end of the operation means 31 such as the operation switch unit 32a or the operation switch unit 32c, it is possible to prevent the operator from making mistakes.
[0022]
The operation unit 30 is configured such that when a plurality of operation switch units to which different functions are assigned are simultaneously turned on, none of the functions of the plurality of turned on operation switch units are executed. In the present embodiment, the CPU 180 determines whether or not one switch has been turned on, and if one switch has been turned on, executes the function of the turned on switch. When the number of turned on switches is not one, that is, when the number of turned on switches is plural, the function is not executed. By configuring the CPU 180 in this manner, when the operator erroneously presses a plurality of operation switches, those functions are not executed, so that erroneous operation can be prevented.
[0023]
When the electronic endoscope apparatus 100 is used, the observation site is imaged as follows. As will be described later, the surgeon operates the operation unit 30 of the electronic scope 100a at hand as needed during observation. The main control unit 120 controls the functions of the entire apparatus corresponding to these operations by the operator.
[0024]
The main control unit 120 controls the light emission of the light source unit 130 to illuminate the observation site. Under the control of the main control unit 120, the light emitted from the light source unit 130 is guided inside the light guide 150, and is emitted into the body cavity from the light guide tip 150a. While the inside of the body cavity is illuminated, the CCD 160 provided at the tip of the electronic scope 100a accumulates electric charges corresponding to the optical image formed on the light receiving surface by the reflected light from the inside of the body cavity, and stores the image in the image processing circuit 140. Output as a signal. The image processing circuit 140 performs a predetermined process on the input image signal, temporarily stores the image signal in an image memory (not shown), reads out the video signal at a predetermined timing, converts the video signal into a video signal, and outputs the video signal to the monitor 100c. The monitor 100c displays an image corresponding to the image signal.
[0025]
FIG. 5 is a diagram illustrating a configuration of the operation switch unit 32 including a sheet switch according to the first embodiment. The operation switch unit 32 includes a top sheet 33a, an upper electrode sheet 33b, a spacer 33c, a lower electrode sheet 33d, and a back adhesive sheet 33e. The operation switch unit 32 is configured by laminating each sheet in the order shown in FIG.
[0026]
When the surgeon presses the top sheet 33a for protecting the surface, the top electrode sheet 33b is also pressed. The upper electrode sheet 33b is a sheet on which a conductive carbon pattern 33f is printed on a film. By being pressed by the surgeon, the carbon pattern 33f comes into contact with the conductive carbon pattern 33g printed on the lower electrode sheet 33d. When the carbon pattern 33f and the carbon pattern 33g come into contact with each other, the operation switch unit 32 is turned on (on). When the surgeon stops pressing the top sheet 33a, the carbon pattern 33f and the carbon pattern 33g come out of contact with each other, so that the operation switch section 32 is turned off (off). The spacer 33c is provided between the upper electrode sheet 33b and the lower electrode sheet 33d, and insulates the pattern of the upper electrode sheet 33b other than the contact portion between the carbon pattern 33f and the carbon pattern 33g from the pattern of the lower electrode sheet 33d. It has such a shape. The back adhesive sheet 33e is an adhesive sheet, and the operation switch unit 32 is attached to a housing forming the operation unit 30.
[0027]
Note that the sheet switch is not limited to the above-described configuration, and switches and sensors having various sheet-like configurations, such as a touch panel, can be used as an alternative.
[0028]
Next, a functional operation of the electronic endoscope apparatus 100 using the operation unit 30 will be described in detail.
[0029]
FIG. 6 is a flowchart of the process when the operation switches 32a to 32c are turned on. When the operation switches 32a to 32c are turned on during the endoscope observation (S1), a predetermined electric signal is transmitted to the CPU 180 via the signal cable of the turned on switch, and among the different ports P1 to P3, Is input to the port corresponding to the switch turned on. In the present embodiment, the electric signal transmitted to each port is a digital signal, and the input electric signal is at either “H” or “L” level. For example, if a certain switch is off, the input electric signal of the port corresponding to the switch becomes "H" level, and if on, it becomes "L" level.
[0030]
The CPU 180 determines which switch of the operation switch units 32a to 32c is turned on based on what electric signal is input to which port (S2). Further, the CPU 180 determines whether or not one switch has been turned on (S3). If there is one switch that has been turned on, the CPU 180 reads out the function data corresponding to the turned on switch from the memory 181 and reads the function data corresponding to the turned on switch. A control signal related to the function assigned to is generated (S4). When the number of turned on switches is not one, for example, when a plurality of switches are pressed, the CPU 180 does not read the function data corresponding to the turned on switches from the memory 181. That is, none of the functions of the turned-on switch is executed (S41). The generated control signal is transmitted to the main control unit 120 of the processor 100b (S5). The generated control signal may be a predetermined code for executing a function assigned to the turned on operation switch unit. Based on the code, the electronic endoscope apparatus performs a predetermined operation such as displaying a still image.
[0031]
FIG. 7 is a diagram illustrating a configuration of an operation switch unit 32w including a sheet switch according to the second embodiment. In the operation switch unit 32w, the same components as those of the operation switch unit 32 of the first embodiment shown in FIG. 5 are denoted by the same reference numerals, and detailed description thereof will be omitted. The operation switch unit 32w includes, in addition to the configuration of the operation switch unit 32, an LED spacer 33h, an LED chip 33i, and an LED sheet 33j. The operation switch unit 32w is configured by laminating each sheet as shown in FIG. Note that at least a portion of the top sheet 33a corresponding to the LED chip 33i is configured to transmit light emitted by the LED chip 33i.
[0032]
In the second embodiment, when the operation switch unit 32w is turned on, the LED chip 33i is turned on and lights up. When the operation switch unit 32w is turned off, the LED chip 33i is turned off and is turned off. The LED sheet 33j is a sheet on which a pattern for turning the LED chips 33i on and off is drawn. The LED spacer 33h is attached so as to insulate the lower electrode sheet 33d and the LED sheet 33j. Further, the LED spacer 33h has a thickness such that the top sheet 33a and the LED chip 33i do not come into contact with each other even when the operation switch section 32w is pressed. With the above configuration, the operation state of the operation switch unit 32w can be visually confirmed based on the lighting state / non-lighting state of the LED chip 33i.
[0033]
FIG. 8A is a diagram illustrating a configuration of an operation unit 30x according to the third embodiment. In the operation unit 30x, the same components as those of the operation unit 30z shown in FIG. 1 are denoted by the same reference numerals, and a detailed description thereof will be omitted. The operation unit 30x has operation means 31x. As shown in FIG. 8B, the operating means 31x includes n switch segments 34x. ₁ ~ 34x _n Having. An arbitrary function can be assigned to the operation unit 31x as in the above embodiment.
[0034]
The surgeon uses the switch segment 34x ₁ ~ 34x _n Any function can be assigned to. In the third embodiment, one operation switch section is formed by assigning the same function to one switch segment at an arbitrary position or a plurality of adjacent switch segments. In the example of FIG. 8C, a plurality of operation switch units 32x are provided on the operation unit 31x. ₁ ~ 32x ₄ Is assigned. Operation switch unit 32x ₁ , 32x ₄ Is composed of one switch segment, and the operation switch unit 32x ₂ , 32x ₃ Is composed of a plurality of switch segments. Thus, the operating means 31x is connected to the switch segment 34x ₁ ~ 34x _n With this configuration, the operator can allocate the operation switches having any functions to the operation means 31x in an arbitrary number, position, and shape. In other words, the operation switch unit having a function frequently used by the operator can be arbitrarily arranged in an area where the operator can easily press, corresponding to the size of the operator's hand or finger. Further, in the operation switch unit including a plurality of switch segments, the assigned function can be performed by turning on at least some of the switch segments. Therefore, the operability is improved, and the possibility of the operator making an operation error is reduced, so that an erroneous operation can be prevented.
[0035]
In addition, the operator can select any switch segment 34x ₁ ~ 34x _n The function of locking the operation switch unit can be assigned to any one of the operation switch units configured by the above so that the operated function is not executed even if the operation switch is operated. When this function is executed, even if the operator operates the operation switch unit by mistake, the operated function is not executed, so that an operation error of the operator can be prevented. When this function is off, if the switch to which this function is assigned is pressed twice, or if the switch is kept pressed for a certain period of time, the switch is turned on and the operation by the operation switch unit is not executed. When this function is on, if the same operation as when it is turned on is performed, the switch is turned off, the lock of the operation switch unit is released, and the operation by the operation switch unit can be executed. In the example of FIG. 8C, the operation switch unit 32x ₁ Or operation switch 32x ₄ By assigning this function to the operation switch unit disposed at the end of the operation means 31x, it is possible to prevent the operator from making mistakes.
[0036]
In the third embodiment, the operation unit 30x is configured such that when a plurality of operation switch units to which different functions are assigned are turned on, none of the functions of the plurality of turned on operation switch units is executed. I have. In the present embodiment, the CPU 180 determines whether or not one switch has been turned on, and if one switch has been turned on, executes the function of the turned on switch. When the number of turned on switches is not one, that is, when the number of turned on switches is plural, the function is not executed. By configuring the CPU 180 in this manner, when the operator presses a plurality of operation switches, those functions are not executed, so that erroneous operations can be prevented. In addition, when a certain operation switch unit is configured by a plurality of switch segments, it is possible to determine that the operation switch unit is operated even if all the switch segments are not pressed. Alternatively, conversely, the configuration may be such that it is determined that the operation switch unit has been operated only when all switch segments constituting the operation switch unit have been pressed. This may be set for each switch in consideration of the function and safety of each switch, or may be set automatically according to the selected function.
[0037]
FIG. 9A is a diagram illustrating a configuration of an operation unit 30y according to the fourth embodiment. In the operation unit 30y, the same components as those of the operation unit 30z shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. The operation unit 30y has operation means 31y. As shown in FIG. 9B, the operating means 31y includes switch segments 34y arranged in an m × n matrix. ₁₁ ~ 34y _mn Having. An arbitrary function can be assigned to the operation unit 31y as in the above embodiment.
[0038]
The operator uses the switch segment 34y ₁₁ ~ 34y _mn Any function can be assigned to. In the fourth embodiment, one operation switch section is formed by assigning the same function to one switch segment at an arbitrary position or a plurality of adjacent switch segments. In the example of FIG. 8C, the operation means 31y includes a plurality of operation switches 32y. ₁ ~ 32y ₅ Is assigned. Each operation switch unit includes a plurality of switch segments. As described above, the operating means 31y is connected to the switch segments 34y arranged in a matrix. ₁₁ ~ 34y _mn With this configuration, the operator can allocate the operation switch unit having an arbitrary function to the operation unit 31y in an arbitrary number, position, and shape. Further, since the operation means 31y of the fourth embodiment forms the operation switch section by arranging the switch segments in a matrix, the operation switches that can be formed can be compared with the operation means 31x of the third embodiment. The degree of freedom of the shape of the part is higher. Therefore, the operability is improved, and the possibility of the operator making an operation error is reduced, so that an erroneous operation can be prevented.
[0039]
Further, the fourth embodiment has a function of locking the operation switch unit as in the third embodiment. In addition, when a plurality of operation switches to which different functions are assigned are pressed, none of the functions of the plurality of pressed operation switches is executed.
[0040]
The above is the embodiment of the present invention. The present invention is not limited to these embodiments, and can be modified in various ranges.
[0041]
The functions described above are all examples. That is, the electronic endoscope apparatus 100 has various functions in addition to the above, and any function can be assigned to each operation switch unit. Further, the operation means may be constituted by a touch panel. In that case, the operability of the operator is improved.
[0042]
In the second embodiment, the color of the light emitted from the LED can be changed for each function assigned to each operation switch unit. By changing the color for each switch in this way, the surgeon can easily visually confirm the selected switch, and thus can prevent erroneous operation.
[0043]
In the above embodiment, the CPU 180 has been described as being configured to determine which switch is turned on by a port to which a predetermined electric signal is input. However, a determination configuration other than this configuration may be used. For example, each operation switch unit and the main control unit 120 are connected by a single cable, and when each operation switch unit is turned on, a signal level (DC voltage level) output from each operation switch unit is set to a different value. Set it. Then, after adding the levels of the signals output from the respective operation switches, the signals are transmitted to the processor 100b through a single signal line. The main control unit 120 may be configured to determine which switch has been turned on by checking the level of the received signal. With such a configuration, it is possible to reduce the diameter of a pipe that connects the operation unit 30 to a portion that houses the CPU 180.
[0044]
If the CPU 180 and the memory 181 are provided on the electronic scope 100a side as in the above-described embodiment, it is possible to use an existing processor that performs a predetermined process according to an instruction from the electronic scope. Here, the CPU 180 and the memory 181 may be provided in the processor 100b. This makes it possible to use existing electronic scopes that directly transmit a predetermined electrical signal corresponding to the turned on switch to the processor.
[0045]
【The invention's effect】
As described above, the present invention can reduce the weight of the electronic scope by configuring the operation switch section of the operation section of the electronic scope with the sheet switch. Therefore, the burden on the operator is reduced. In addition, the degree of freedom of the number and arrangement of the operation switches is high, and the operability of the operator is improved. Further, cost can be reduced.
[Brief description of the drawings]
FIG. 1 is an enlarged view of a conventional electronic scope.
FIG. 2 is a schematic configuration diagram of a mechanical switch used in a conventional electronic scope.
FIG. 3 is an enlarged view of the electronic scope according to the embodiment.
FIG. 4 is a schematic configuration diagram of an electronic endoscope apparatus according to the present embodiment.
FIG. 5 is a schematic configuration diagram of a sheet switch used in the electronic scope according to the first embodiment.
FIG. 6 is a flowchart relating to processing of a CPU according to the first embodiment.
FIG. 7 is a schematic configuration diagram of a sheet switch used in the electronic scope of the second embodiment.
FIG. 8 is a schematic configuration diagram of an operation unit according to a third embodiment.
FIG. 9 is a schematic configuration diagram of an operation unit according to a fourth embodiment.
[Explanation of symbols]
30 Operation unit
32a to 32c operation switch section
100 Electronic endoscope device
100a electronic scope
100b processor
120 Main control unit
130 Light source
140 Image processing circuit
170 Front Panel
180 CPU

Claims (7)

An electronic scope having an operation unit for operating the electronic endoscope device,
A processor electrically connected to the electronic scope, and an electronic endoscope device comprising:
The operation unit has a plurality of sheet-shaped switch units provided at predetermined positions, each of the plurality of switch units, a function for operating the electronic endoscope device is set, An electronic endoscope device characterized by the following. Lighting means is provided corresponding to each of the plurality of sheet-like switch parts, and when each of the plurality of sheet-like switch parts is operated, the lighting means corresponding to the operated switch part is lit. The electronic endoscope apparatus according to claim 1, wherein: An electronic scope having an operation unit for operating the electronic endoscope device,
A processor electrically connected to the electronic scope, and an electronic endoscope device comprising:
The operation unit has a switch area at a predetermined position, and in the switch area, an arbitrary number of switch units can be set at an arbitrary position. An electronic endoscope apparatus, wherein a function for operating the endoscope apparatus is set. The electronic endoscope apparatus according to any one of claims 1 to 3, wherein any one of a plurality of operation functions can be assigned to each of the switch units. The electronic endoscope apparatus according to claim 4, wherein the same operation function can be assigned to different switch units. The electronic endoscope apparatus according to claim 5, wherein when at least two switch units to which different functions are assigned are operated, none of the different functions is executed. 7. The electronic endoscope apparatus according to claim 1, wherein the plurality of operation functions have a function of locking an operation of the electronic endoscope.

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