JPS6141568B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an endoscopic photographing device in which mechanical electrical contacts between a camera, an endoscope, and a light source device in an automatic exposure signal circuit or the like are eliminated.

Generally, in an endoscope photography device, a camera and a light source of an endoscope are electrically coupled. This combination is used to synchronize the flash light for photography.
and automatic exposure control. This coupling is typically achieved through a plurality of mechanical and electrical contacts provided in the endoscope eyepiece and connector. All of these contacts are exposed on the outer surface. Therefore, poor contact was likely to occur due to dirt, oxidation, corrosion, etc. In order to avoid this drawback, the contacts may have a waterproof structure. However, waterproof electrical contacts have a complicated structure and do not solve the essential problem.

As a technique for solving the above problem, there is a technique disclosed, for example, in Japanese Patent Application Laid-Open No. 53-38322. Here, the camera is provided with a light emitting element, and the light source section is provided with a light receiving element. Light emitted from the light emitting element is transmitted to the light receiving element via a signal light guide within the endoscope. In the device disclosed herein, light emitted from a light emitting element is used as a synchronization signal for the flash light. Therefore, mechanical electrical contacts for the synchronization are not required. However, this device cannot be applied when automatic exposure control is performed on the light source side.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an endoscopic photographing device that can combine a camera and an endoscope light source so as to perform automatic exposure control without using mechanical electrical contacts. purpose.

FIG. 1 is a block diagram showing an embodiment of an endoscopic photographing apparatus according to the present invention. The endoscope 10 includes an image guide fiber 12 for propagating an optical image.
and a light guide fiber 14. A lamp 20 is connected to the light receiving end ₁₄₁ of the fiber 14 via a shutter 16 and a condensing lens 18.
light is given. A reflecting mirror 22 is disposed behind the lamp 20 to improve illumination efficiency. The shutter 16, the condensing lens 18, the lamp 20, and the reflecting mirror 22 constitute a light source section 23 . Light receiving end 1
The light given to 4 ₁ passes through the fiber 14,
The light is emitted from the light emitting end 14 ₂ on the tip component 10 ₁ side. An objective lens 24 of an observation optical system is provided within the tip component ₁₀₁ . The optical image of the object 26 captured by the objective lens 24 is directed to the eyepiece 28 of the endoscope 10 via the image guide fiber 12. The optical image passing through the eyepiece 28 is transmitted to the exposure surface of a photographic film 34 via a half prism 30 and a shutter 32 in a camera 29 mounted on the endoscope 10.

A part of the optical image is dispersed to the left side of the figure by the half prism 30. half prism 30
A photodiode 36 is disposed on the left end surface of the photodiode 36 . This photodiode 36 generates a brightness signal containing exposure information of a magnitude corresponding to the brightness of the optical image passing through the half prism 30. This brightness signal is given to the information processing circuit 38. The information processing circuit 38 further includes an oscillator 40.
A carrier signal having a unique frequency ₁ from
A synchronization signal for illumination synchronization is input from the shutter button 41. The information processing circuit 38 processes the brightness signal and the synchro signal based on the carrier signal, and provides the processing results to the transmitter 42. Then, a radio signal having a unique frequency ₁ is output from the transmitter 42 to the antenna 44. That is, the antenna 44 emits a radio signal having a carrier frequency of ₁ and modulated by the brightness signal and the synchro signal.

The radio signal emitted from the antenna 44 is
The light is captured by the antenna 46 on the light source device 45 side. The radio signal captured by antenna 46 is input to receiver 50 including frequency selection circuit 48 . This frequency selection circuit 48 can select one of a plurality of different receiving frequencies. When the frequency selection circuit 48 sets the reception frequency of the receiver 50 to the same frequency as the carrier frequency ₁ , the receiver 50 is coupled to the transmitter 42 using the radio signal as a medium. The receiver 50 demodulates the radio signal and provides the information processing circuit 52 with a signal. Then, the information processing circuit 52 supplies a control signal corresponding to the radio signal to the light source control device (automatic exposure control circuit) 54. This control device 54 is coupled to the light source section 23 and controls the flash timing of the lamp 20 and the amount of light applied to the light receiving end ₁₄₁ of the fiber 14.
That is, the lamp 20 is flashed in response to the synchronization signal, and the amount of light given to the light receiving end ₁₄₁ is controlled in accordance with the brightness signal.

The configuration described above forms an automatic control system that includes the subject 26 in its closed loop. That is, when the subject 26 is dark, the optical image dispersed toward the photodiode 36 is also dark. Then, since the brightness signal output from the photodiode 36 is also low,
The modulation of transmitter 42 is shallow. Then, the signal demodulated by the receiver 50 has a low level. This small level demodulated signal is transmitted to the light source controller 54 via the information processing circuit 52. Then, this control device 54 increases the power supplied to the lamp 20 or increases the number of blinks of the lamp 20,
Alternatively, the opening time of the shutter 16 may be increased.
Then, the amount of light given to the fiber 14 increases, and the subject 26 becomes brighter. Automatic exposure control is performed through such automatic control operations.

The above-mentioned automatic exposure control etc. is performed using the unique frequency ₁ of the radio signal emitted from the camera 29 side,
This is possible only when the selected reception frequency on the light source device 45 side matches. In order to perform this matching, the present invention has the following configuration. That is, the camera 29 is provided with a combination switch 56. Combination switch 56 is connected to oscillator 58. When the switch 56 is turned on, the oscillator 58 generates a unique signal having a frequency corresponding to the unique frequency ₁ . This unique signal is supplied to the light emitter 62 via the light conversion device 60. Then, the luminous body 6
2 emits an optical signal containing unique frequency information ₁₀ corresponding to ^the unique frequency ₁ . ^The components 56 to 62 constitute a unique frequency information transmission means 63 that provides unique frequency information ₁₀ .

The optical signal becomes a beam having appropriate directivity and is incident on a photoreceptor 64 disposed in the light source device 45. The optical signal sensed by the photoreceptor 64 is provided to a frequency identification circuit 68 via a receiving device 66. Then, this frequency identification circuit 68 stores unique frequency information ₁₀ included in ^the optical signal. A frequency identification circuit 68 is coupled to the frequency selection circuit 48. The frequency selection state of the frequency ^selection circuit 48 is determined according to the designation of the frequency ^{identification circuit 68 based on the stored unique frequency information 10} _, and the unique frequency ₁ corresponding to ₁₀ is selected.

When the frequency selection operation of the frequency selection circuit 48 is completed, the pilot lamp 70 connected to the frequency identification circuit 68 is turned on. pilot lamp 7
After 0 lights up, ^the combination switch 56 is turned off and the unique frequency information ₁₀ is erased. The frequency selection state set in this way is determined by the light source device 45.
The unique frequency information ₁ ⁰
It remains as is until the memory of ⁰ is canceled or new and other unique frequency information _o0 is provided to the photoreceptor 64. Components 64 and 66
constitutes a unique frequency information sensing means 67 .

Even if a plurality of endoscopic photographing apparatuses configured as shown in FIG. 1 are used at the same location, malfunctions due to interference will not occur. For example, the first camera 29
Assume that the unique frequency of the _first side is ₁ , and the unique frequency of the second camera ₂₉₂ side is ₂ . Based on ^{the unique frequency information 10} _given from the first camera ₂₉₁ , the receiving frequency of the first light source device ₄₅₁ that is combined with the first camera ₂₉₁ is selected to be ₁ in advance. Similarly, the second
Unique frequency information given from camera 29 _2
20 , the reception frequency on ^the second light source device ₄₅₂ side combined with the second camera ₂₉₂ is selected in advance to be ₂ . Unique frequency ₁ , ₂
is different for each camera. Therefore, each light source device is coupled only to the camera with which it is combined, and malfunctions due to interference can be avoided.

The synchronization timing and automatic exposure control signal transmission method for the lamp 20 described above are as follows:
Amplitude modulation (AM), frequency modulation (FM), pulse width modulation (PWM, PCM), etc. can be used. ^Further , the light used for transmitting the unique frequency information ₁₀ may be not only visible light but also infrared light or ultraviolet light. Furthermore, as a transmission medium for ^the unique frequency information ₁₀ , sound waves, ultrasonic waves, radio waves, magnetic waves, etc. may be used.

In FIG. 1, a combination switch 56 is provided to generate ^the unique frequency information ₁₀ , and ^{the unique frequency information 10} _is deleted when the receiving frequency selection operation is completed. It's summery. However, the combination switch 56 is removed and the endoscope 10 is equipped with a camera 29 and a light source device 45.
unique frequency information automatically when installed
It may be configured so that ₁ ⁰ occurs. Furthermore, when there is no risk that the unique frequency information ₁₀ will be mixed into ^the unique frequency information sensing means 67 of another photographing device,
This unique frequency information ₁₀ may be generated ^all the time.

FIG. 2 is a modification of the device shown in FIG. Here, an information transmission light guide fiber ⁷² is used as a conductor for transmitting the unique frequency information ₁₀ . That is, this fiber 72 is disposed in the light guide protection tube ₁₀₂ of the endoscope 10 together with the light guide fiber 14. Then, the light receiving end 72 ₁ of the fiber 72
A light emitter 62, for example a light emitting diode, is disposed at the light emitting end 722 of the fiber 72, and a light receiver 64, for example a photodiode, is disposed at the light emitting end ₇₂₂ of the fiber 72. In the configuration shown in FIG. 2, the camera 29 and the light source device 45 are attached to the endoscope 10, and at the same time the unique frequency information is
₁₀ can be transmitted from the camera 29 side ^to the light source device 45. Therefore, the operation for selecting the reception frequency becomes easier than in the configuration of FIG. 1. However, in the configuration shown in FIG. 1, only one fiber is disposed in the light guide protection tube ₁₀₂ , so the configuration shown in FIG. ₁ is more advantageous in reducing the diameter of the protection tube 102.

As is clear from the above description, the photographing device according to the present invention has the following advantages.

(1) Since there is no need for electrical contacts exposed on the outer surface of the endoscope, it is not only easier to make the endoscope waterproof, but also prevents poor contact due to dirt, oxidation, corrosion, etc. of the electrical contacts. There will be no electrical shock, and no electric shock will occur.

(2) Since the frequency of the radio signal used for lighting synchronization and automatic exposure control can be selected for each camera used, malfunctions due to interference can be avoided even when multiple photographic devices are used at the same time. .

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of an endoscopic photographing apparatus according to the present invention, and FIG. 2 is a partial diagram showing a modification of FIG. 1. 10...Endoscope, 10 ₁ ...Tip component, 10
₂ ... Light guide protection tube, 12 ... Image guide fiber, 14 ... Light guide fiber, 14 ₁ , 72 ₁ ... Light receiving end, 14 ₂ , 72 ₂
... Light emitting end, 16, 32 ... Shutter, 18 ...
Condenser lens, 20...lamp, 22...reflector,
23 ...Light source section, 24...Objective lens, 26...
Subject, 28...eyepiece, 29...camera,
30... Half prism, 34... Photographic film, 36... Photo diode, 38, 52...
Information processing circuit, 40, 58... Oscillator, 41...
Shutter button, 42... Transmitter, 44, 46...
... Antenna, 45 ... Light source device, 48 ... Frequency selection circuit, 50 ... Receiver, 54 ... Light source section control device, 56 ... Combination switch, 60 ... Light conversion device, 62 ... Light emitter, 63 ...Unique frequency information transmission means, 64...Photoreceptor, 66...Receiving device, 67 ...Unique frequency information sensing means, 68...
Frequency identification circuit, 70...Pilot lamp, 7
2...Light guide fiber for information transmission, ₁
...Individual frequency, ₁ ⁰ ...Individual frequency information.

Claims (1)

[Scope of Claims] 1. An endoscope having an image guide fiber and a light guide fiber; and a transmitter that generates a radio wave signal having a unique frequency used for synchronization of photographic lighting or automatic exposure control; a camera mounted on the optical path of the optical image derived from the guide fiber; a light source unit that provides light to the light guide fiber; and a unit that receives the radio wave signal and selects one of a plurality of reception frequencies. a receiver having a frequency selection circuit for controlling the frequency selection circuit; and a light source control device to which a control signal corresponding to the radio signal is given from the receiver and controlling the light source based on the control signal; a light source device that is separable from each other; unique frequency information transmission in which the camera provides unique frequency information corresponding to the unique frequency and notifies a receiver of the light source device of the unique frequency; means; a unique frequency information sensing means by which the light source device senses the unique frequency information; and a frequency of the frequency selection circuit based on the unique frequency information sensed by the unique frequency information sensing means. An endoscopic photographing device comprising a frequency identification circuit that specifies a selection state and matches the receiving frequency to the unique frequency. 2. In the endoscopic photographing device according to claim 1, the unique frequency information is optically formed, and the unique frequency information transmission means includes a light emitting body that provides the unique frequency information. An endoscopic photographing apparatus, wherein the unique frequency information sensing means has a photoreceptor that captures the unique frequency information. 3. In the endoscopic photographing device according to claim 1, the unique frequency information is formed acoustically, and the unique frequency information transmission means includes a sounding body that provides the unique frequency information. An endoscopic photographing apparatus, wherein the unique frequency information sensing means has a sound receiver that captures the unique frequency information. 4. In the endoscopic photographing device according to claim 1, the unique frequency information is electromagnetically formed, and the unique frequency information transmission means is an electromagnetic wave generator that provides the unique frequency information. An endoscopic photographing apparatus, characterized in that the unique frequency information sensing means includes an electromagnetic wave receiver that captures the unique frequency information. 5. In the endoscopic photographing device according to claim 2, a second light guide is provided as an optical conductor for the unique frequency information inside the endoscope that connects the camera and the light source device. An endoscopic photographing device characterized in that a fiber is provided.