JP4282281B2 - Electronic endoscope device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic endoscope apparatus, in particular, an electronic endoscope that is a scope connected to a processor apparatus. The power supply is supplied between them, and the configuration of connection lines and signal transmission for transmitting video signals. About.
[0002]
[Prior art]
In an electronic endoscope apparatus, for example, an electronic endoscope (scope) on which a CCD (Charge Coupled Device) that is a solid-state imaging device is mounted is connected to a processor apparatus by a cable and a connector. Through the cable and connector, power is supplied from the processor device to the scope and various control signals are transmitted, and video signals and various control signals are transmitted from the scope to the processor device.
[0003]
That is, the scope is driven by a DC power source supplied from the processor device through the power supply line, while a video signal captured by the CCD of the scope is sent to the processor device via the signal line (transmission line). The subject image is displayed on the monitor by applying various color video processing to the video signal.
[0004]
[Problems to be solved by the invention]
However, in the above electronic endoscope apparatus, the cable connecting the scope and the processor device includes a power supply line and a plurality of signal lines. Since this cable connector has a multi-pin structure, contact with any of the connection pins There is a risk that a defect may occur or a connection pin may be damaged, resulting in an increase in cost.
[0005]
In recent years, it has been demanded that scopes with different application sites and purposes can be connected to a common processor device, and the number of CCDs mounted on the scope has been increased. It is also required that various scopes equipped with CCDs having different numbers of pixels can be connected to a common processor device. Further, the electronic endoscope apparatus uses an electronic shutter function that controls the brightness of the image by variably setting the accumulated charge time of the CCD, and it is also necessary to make this electronic shutter function executable.
[0006]
The present invention has been made in view of the above problems, and an object of the present invention is to share a power supply line and a signal line, connect a scope and a processor device with a minimum number, and different types of scopes. It is an object of the present invention to provide an electronic endoscope apparatus that can execute video processing satisfactorily even when connected to a common processor.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, according to a first aspect of the present invention, an electronic endoscope having an image pickup device is connected to a main body side device including a processor device, and power is supplied from the main body side device to the electronic endoscope. In the electronic endoscope apparatus, the power / signal sharing line for connecting the electronic endoscope and the main body side apparatus, and the main body side apparatus are provided to supply power to the power / signal sharing line. Power supply circuit, electronic endoscope side synchronization signal generating circuit provided in the electronic endoscope and forming an electronic endoscope side reference pulse for video signal processing using a scope side oscillator, and the processor device A processor-side synchronization signal generating circuit for forming a processor-side reference pulse for video signal processing using a processor-side oscillator having an oscillation frequency different from that of the scope-side oscillator, and supply of the power / signal sharing line. It superimposes the video signal obtained by the imaging device on the power supply, and the video signal Either the first field (or the first frame) or the second field (or the second frame) An electronic endoscope side waveform superimposing circuit for superimposing an electronic endoscope side reference pulse in a predetermined blanking period, and a video signal superimposed on a power supply of the power / signal sharing line. The other field (or frame) of the first field (or the first frame) or the second field (or the second frame) where the electronic endoscope side reference pulse is not superimposed. A processor-side waveform superimposing circuit for superimposing a processor-side reference pulse in a predetermined blanking period; a processor-side separating circuit for separating a video signal and an electronic endoscope-side reference pulse superimposed on the power / signal sharing line; An electronic endoscope side separation circuit for separating the processor side reference pulse superimposed on the power / signal sharing line, and the electronic endoscope side synchronization signal generation circuit is obtained from the electronic endoscope side separation circuit. A signal for video signal processing synchronized with the processor side reference pulse is generated, and the processor side synchronization signal generation circuit synchronizes with the electronic endoscope side reference pulse obtained from the processor side separation circuit. Signals for processing are generated, and video signals are processed based on these signals.
[0008]
According to a second aspect of the present invention, there is provided an electronic shutter circuit for controlling a charge accumulation time in the image sensor as an electronic shutter speed. The processor-side waveform superimposing circuit is An electronic shutter control signal is superimposed on a predetermined blanking period of the video signal supplied through the power / signal sharing line. Shi , The electronic endoscope side separation circuit is The electronic shutter control signal superimposed on the power / signal sharing line is separated.
The invention described in claim 3 Up The processor side waveform superimposing circuit In a blanking period other than the blanking period in which the electronic endoscope side reference pulse and the processor side reference pulse are superimposed in the video signal, An electronic shutter control signal is superimposed.
[0009]
According to the configuration of the first aspect, the electronic endoscope and the processor device are connected by, for example, one coaxial cable (or two electric wires including the ground wire), and the coaxial cable serving as the power / signal sharing line. Then, power is supplied from the processor device to the electronic endoscope, and a video signal is transmitted from the electronic endoscope to the processor device in the form of waveform superposition on the power supply (signal level) of the power / signal sharing line. Is done.
[0010]
The video signal includes, for example, an electronic endoscope side reference during the blanking period of the first horizontal line signal in the first first field (generally an odd field, which is a first frame in the case of non-interlaced scanning). A pulse (clock signal) is superimposed and an information signal (for example, 8-bit data) related to the electronic endoscope is superimposed in the blanking period after the second horizontal line. In addition, the processor-side reference pulse is superimposed on the blanking period of the first horizontal line of the second field (or second frame). the above The information signal related to the electronic endoscope includes various types of information such as the type of electronic endoscope, the number of pixels of the image sensor, and processing information of color signals.
[0011]
And In the electronic endoscope, the processor side reference pulse is separated and extracted, In the processor device, the information signal regarding the electronic endoscope side reference pulse and the information signal regarding the electronic endoscope are separated and extracted, a clock signal synchronized with the electronic endoscope side reference pulse is formed, and the information regarding the electronic endoscope is The image is input to the microcomputer and image processing based on this information is performed.
[0012]
Further, according to the invention of claim 2, the electronic shutter control signal is generated during the blanking period after the second horizontal line in the next second field (generally an even field, which is a second frame in the case of non-interlace). Are superimposed. That is, the brightness of an image is measured in the processor device, and an electronic shutter speed control signal (for example, 8-bit data) for adjusting the charge accumulation time (exposure time) in the image sensor based on the determination of the brightness. Is superimposed on the power supply. The electronic shutter speed control signal is separated and extracted by the electronic endoscope and supplied to the electronic shutter circuit, and the electronic shutter circuit controls the charge accumulation time (electronic shutter speed) in the image sensor.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
1 and 2 show the configuration of the electronic endoscope apparatus according to the first embodiment. In FIG. 1, a scope (electronic endoscope) A is a single coaxial line that is a power / signal sharing line. The cable 10 is connected to the processor device B. For example, a 410,000-pixel CCD 12 and an electronic shutter circuit 13 are provided at the distal end portion of the scope A. Although not shown, illumination light is supplied to the distal end portion from the light source device through a light guide. The electronic shutter circuit 13 drives the CCD 12 and sets the number of sweep pulses (SUB pulses) for sweeping out the charges accumulated in the CCD 12, so that a substantial charge accumulation time (exposure time) accumulated later is set. Is variably controlled as the electronic shutter speed.
[0014]
Further, the scope A includes a power supply circuit 14 for inputting a direct current (DC) power supply, a switching regulator and the like, and a power supply forming circuit 15 for forming a plurality of power supply voltages from the power supply from the power supply circuit 14. A waveform separation circuit 16 that separates a control signal and the like superimposed on the power supply of the coaxial cable 10, a video signal (interlaced scanning signal) is superimposed on the power supply, and the first field of the video signal in the first horizontal first A waveform superimposing circuit 17 is provided that superimposes the scope-side reference pulse in the blanking period of the line signal and superimposes the scope information signal related to the scope A in the blanking period after the second horizontal line signal of the first field. The scope information includes various types of information such as the type of scope A, the number of pixels of the CCD 12, and processing of color signals.
[0015]
Furthermore, a phase comparison circuit 18 that compares the phase of the processor side reference pulse and the phase of the oscillation signal, which will be described later, forms signals such as a pixel unit clock signal, a horizontal synchronization (HD) signal, a vertical synchronization (VD) signal, and a reset signal. A timing generator (TG) 19 is provided. The timing generator 19 has a crystal oscillator 19a that oscillates a driving frequency of 28.6363 MHz for the 410,000 pixel CCD 12 and a variable capacitance diode 19b, and outputs a clock signal having a frequency of 28.663 MHz as the scope side reference pulse. Further, by forming a PLL (Phase Locked Loop) together with the phase comparison circuit 18, it functions as a synchronization signal generation circuit that generates a signal synchronized with the processor side reference pulse.
[0016]
Also provided are a buffer 20 for inputting the output signal of the CCD 12, a microcomputer 21 for comprehensively controlling each circuit of the scope A, and an EEPROM 50 for storing scope information about the scope A such as the scope type, the number of pixels, and color signal processing. The scope information signal is supplied to the waveform superimposing circuit 17 by the microcomputer 21.
[0017]
On the other hand, the processor device B includes a power supply circuit 23 for supplying DC power to the scope A, and a waveform superimposing circuit for superimposing a waveform of a control signal such as an electronic shutter speed on the power supply in the blanking period of the second field. 24. A waveform separation circuit 25 for separating the video signal, which is an AC component, a scope-side reference pulse, and a scope information signal is provided. In addition, a phase comparator 26 and a synchronization signal generator (SSG) 27 are provided so as to input the output of the waveform separation circuit 25. The phase comparator 26 includes the phase of the scope side reference pulse and the oscillation signal. Are compared, and a voltage proportional to the phase difference is generated. The synchronization signal generator 27 includes a crystal oscillator 27a and a variable capacitance diode 27b that generate a frequency of 28.6363 MHz for driving a 410,000 pixel CCD, for example, and outputs the output voltage of the phase comparison circuit 26 from the oscillator 27a and the variable capacitance diode. By inputting to the connection point 27b and forming a PLL, a clock synchronized with the scope side reference signal, a horizontal synchronization (HD) signal, a vertical synchronization (VD) signal, and the like are generated.
[0018]
The processor device B is provided with a microcomputer 31 for overall control of each circuit, and further receives a video signal from the waveform separation circuit 25 and performs a correlated double sampling (CDS) circuit 32 for performing correlated double sampling. A / D converter 33, DSP (digital signal processor) circuit 34 for performing various processing for color image formation on the video signal, electronic zoom circuit 35 for electronically enlarging / reducing the image, D / A converter 36, an amplifier 37, and the like are provided.
[0019]
FIG. 2 shows specific circuits of the power receiving circuit 14, the waveform separating circuit 16, and the waveform superimposing circuit 17 of the scope A. In the power receiving circuit 14, a supply power line 70 connected to the coaxial cable 10 is shown. Choke coil L connected in series to block high frequency ₁ And a capacitor C connected in parallel to the supply power line 70 ₁ A smoothing circuit is constructed from the above. In the waveform separation circuit 16, a reference voltage source (Ref.) 16 A that applies a reference potential to an input from the power supply line 70, and a capacitor C for extracting an AC (alternating current) component. ₂ , Resistance R ₁ Etc. are arranged to separate the AC component from the power supply line 70, that is, the control signal supplied from the processor unit B.
[0020]
Next, in the waveform superimposing circuit 17, the coil L is connected between the power supply line 70 and the ground. ₂ And a transistor Tr, and the collector of the transistor Tr is a coil L ₂ One end of the emitter is connected to the ground, and a video signal from the buffer 20 and a reference clock pulse from the timing generator 19 are applied to the base of the transistor Tr as a superimposed signal. The configurations of the waveform superimposing circuit 17 and the waveform separating circuit 16 described above are similarly used as the configurations of the waveform superimposing circuit 24 and the waveform separating circuit 25 in the processor device B.
[0021]
The first embodiment is configured as described above, and when the power of the processor unit B is turned on, DC power is supplied from the power supply circuit 23 to the scope A via the coaxial cable 10. On the other hand, in the scope A, when the DC power supplied from the power supply circuit 23 is received by the power supply circuit 14, the power generation circuit 15 generates a predetermined voltage.
A plurality of power supplies are formed and supplied to each circuit.
[0022]
When the DC power is supplied to the electronic shutter circuit 13, the CCD 12 is driven by the electronic shutter circuit 13, and the object to be observed is imaged. The imaging signal (video signal) output from the CCD 12 is supplied to the waveform superimposing circuit 17 via the buffer 20, and the video superimposing circuit 17 superimposes the video signal on the supply power source (70). This video signal is sent to the processor device B via the coaxial cable 10. At this time, about 10 pulses of the reference pulse (clock signal with a frequency of 28.6363 MHz) are first input from the timing generator 19 to the waveform superimposing circuit 17 under the control of the microcomputer 21, and the reference pulse is used as a synchronization signal. The first field of the video signal is superimposed on the blanking period of the first horizontal line signal.
[0023]
FIG. 3 shows a part of the output state of the waveform superimposing circuit 17. For example, if the DC power supply is 12V, the horizontal line signal (substantial video signal) of the video signal is supplied on the supply voltage of 12V. ) S _a1 , S _a2 , S _a3 , ... are superimposed in the inverted state. Then, the first horizontal line signal S of the first (first) field (generally an odd field) of the video signal (when interlace scanning is performed). _a1 Blanking period B _a1 On the other hand, the reference pulse Se is superimposed by about 10 pulses (FIG. 5).
[0024]
Further, in this example, as shown in FIG. 5, the scope information is converted into the second horizontal line signal (2H-S) of the first field by the waveform superimposing circuit 17 under the control of the microcomputer 21. _a2 ) Waveform is superimposed in the subsequent blanking period. As shown in FIG. 4, the EEPROM 50 stores scope information such as the type on the scope A side, the number of pixels of the CCD 12, the processing of color signals, and the like as 8-bit data at addresses 0, 1, 2,. When one horizontal line signal is blanked, the waveform of 1 or 0 bit data representing 1 by one pulse is superimposed. That is, as shown in FIG. 5, for example, the blanking period B from the second horizontal line signal 2H to the fifth horizontal line signal 5H (the square is the actual video signal portion). _a2 ~ B _a5 The data of address 0, “0, 0, 0, 0” is superimposed on the waveform, and the blanking period B from the sixth horizontal line signal 6H to the thirteenth horizontal line signal 13H _a6 ~ B _a13 Scope data, “1, 0, 1, 0, 0, 1, 0, 0” are sequentially superimposed on the waveform.
[0025]
On the other hand, in the waveform separation circuit 25 of the processor device B, the AC component supplied via the coaxial cable 10 is separated, and the horizontal line signal S described with reference to FIGS. _a1 , S _a2 , S _a3 Are supplied to the CDS circuit 32, and the blanking period B is firstly set. _a1 The scope-side reference pulse Se separated from is supplied to the synchronization signal generator 27 through the phase comparison circuit 26. In the phase comparison circuit 26 and the synchronization signal generator 27, a clock signal synchronized with the reference pulse Se, a horizontal synchronization signal, a vertical synchronization signal, and the like are generated when the PLL functions and the voltage applied to the variable capacitance diode 27b changes. A timing signal is formed. That is, since it is known in advance that the overlapping position of the reference pulse Se is the first horizontal line signal of the first field, the horizontal scanning and vertical scanning can be synchronized based on the pulse Se. These timing signals are supplied to the CDS circuit 32 and the like.
[0026]
In the waveform separation circuit 25, the blanking period B after the second horizontal line signal 2H in FIG. _a2 ~ B _a13 , B _a14 The scope information signal is separated from ˜, and this scope information is supplied to the microcomputer 31. Based on this scope information, the microcomputer 31 executes video processing control suitable for the connected scope A, and even when a different type of scope A is connected, good processing according to the scope characteristics is performed.
[0027]
In the CDS circuit 32, the input video signal is correlated double-sampled, and the signal converted into a digital signal by the A / D converter 33 in the next stage is subjected to color video processing by the DSP circuit 34. This is supplied to the monitor via the electronic zoom circuit 35, the D / A converter 36 and the amplifier 37.
[0028]
Further, in the electronic shutter circuit 13 of the scope A in this example, the brightness of the image is adjusted by variably setting the electronic shutter speed, and a control signal for the electronic shutter speed is sent from the processor device B through the coaxial cable 10. Scope A is supplied. That is, the DSP circuit 34 detects a photometric signal or a luminance signal of the current video signal, and based on these signals, an electronic shutter speed control signal for making the video brightness constant is supplied to the microcomputer 31. As a result, the electronic shutter speed control signal is superimposed on the blanking period of the second field on the power supply via the waveform superimposing circuit 24.
[0029]
For example, the control signal for the electronic shutter speed is 8-bit data representing the number of sweep pulses (for example, 0 to 252) synchronized with one horizontal synchronization signal, and as shown in FIG. Horizontal line 2H (S _b2 ) To 9th horizontal line 9H blanking period B _b2 ~ B _b9 In addition, electronic shutter speed control data “0, 1, 1, 0, 0, 0, 0, 1” are superimposed in order.
[0030]
Then, in the waveform separation circuit 16 of the scope A, the electronic shutter speed control signal is separated from the power supplied from the coaxial cable 10, and this control signal is sent to the electronic shutter circuit 13 via the microcomputer 21. As a result, in the electronic shutter circuit 13, the accumulated charge sweep time is controlled by the number of sweep pulses as the electronic shutter speed control signal, and the charge accumulation time after the sweep is controlled as the electronic shutter speed.
[0031]
As described above, the processor apparatus B executes video processing based on the scope side reference pulse Se and the scope information supplied via the coaxial cable 10 which is a power / signal sharing line, and via the coaxial cable 10. The scope A executes the exposure time control based on the supplied electronic shutter speed control signal, so that the image of the object to be observed can be favorably displayed on the monitor.
[0032]
Further, in this embodiment, processing corresponding to the case where various scopes A having different numbers of pixels are connected can be performed. For example, when the scope A is equipped with a CCD 12 having 270,000 pixels and the processor device is configured to be based on the processing of an image sensor with 410,000 pixels, the scope A outputs a clock signal having an oscillation frequency of 19.0632 MHz. The processor device B uses a clock signal having an oscillation frequency of 28.6363 MHz, and it is not sufficient that the processor device B only synchronizes based on the scope-side reference pulse Se. That is, the reference pulse of about 10 pulses is distorted in its waveform by transmitting the length from the scope A to the processor unit B, passing through the transformer, etc., and an accurate synchronization state is obtained by this waveform distortion. Disappear.
[0033]
Therefore, in this example, the scope A is configured to be synchronized based on the processor-side reference pulse. For example, the synchronization signal generator 27 of the processor apparatus B in FIG. 1 forms 19.0909 MHz obtained by dividing the oscillation frequency 28.6363 MHz by 2/3 with a frequency divider, and this is used as the processor side reference pulse to the scope A. It is sent via the coaxial cable 10. That is, in the waveform superimposing circuit 24, as shown in FIG. 3, the first horizontal line signal S of the second field (generally an even field) of the video signal. _b1 B during the blanking period _b1 The processor-side reference pulse Sp is superimposed on about 10 pulses.
[0034]
On the other hand, the timing generator 19 of the scope A also has a function of generating a synchronization signal, and forms a signal synchronized with the processor side reference pulse Sp separated from the waveform separation circuit 16. Also in the case of this processor side reference pulse Sp, since it is known that this superposition position is the first horizontal line signal of the second field, synchronization of horizontal scanning and vertical scanning can be achieved by inputting this pulse Sp. become.
[0035]
In this way, the processor device B synchronizes with the scope-side reference pulse Se superimposed on the first field first horizontal line signal, and the scope A uses the processor-side reference pulse superimposed on the second field first horizontal line signal. By synchronizing with Sp, stable signal synchronization without waveform distortion is performed.
[0036]
Further, in the above case, since the frequency of the scope side reference pulse 19.0632 MHz and the frequency of the processor side reference pulse 19.0909 MHz are different, the horizontal width is slightly reduced, but this horizontal width is an electronic zoom circuit. It is corrected by 35 mag. That is, in the image memory provided in the electronic zoom circuit 35, the image data written at the timing synchronized with the scope side reference pulse is read out at the timing of the horizontal synchronizing signal of about 63.5 μsec formed from the oscillation frequency 28.6363 MHz. Thus, the horizontal width can be corrected.
[0037]
In the above embodiment, the scope information signal is superimposed on the blanking period after the first field second horizontal line signal, and the electronic shutter speed control signal is superimposed on the blanking period after the second field second horizontal line signal. These superposition positions can be arbitrarily changed and set. In the above example, the case of interlaced scanning has been described. However, in the case of non-interlaced scanning, the scope side reference pulse Se is used as the blanking period of the first horizontal line signal of the first (first) frame, and the scope information signal. The processor side reference pulse Sp is superimposed on the blanking period of the first horizontal line signal of the second frame, and the electronic shutter speed control signal is transmitted to the second frame. It can be superimposed on a predetermined blanking period after the first horizontal line signal.
[0038]
Further, contrary to the above embodiment, the processor-side reference pulse Sp is used as the first horizontal line signal S of the first field (or first frame). _a1 Blanking period B _a1 And the scope side reference pulse Se is superimposed on the first horizontal line signal S of the second field (or second frame). _b1 Blanking period B _b1 It can also be superimposed on.
[0039]
【The invention's effect】
As described above, according to the present invention, the power / signal sharing line is disposed between the electronic endoscope and the processor device, and the video signal is superimposed on the power supply on the electronic endoscope side, And, for example, the first field first horizontal line signal of this video signal. Of the issue During the blanking period In addition to superimposing the electronic endoscope side reference pulse, the processor side reference pulse is also superimposed on the blanking period of the second field first horizontal line signal, and on the electronic endoscope side, video signal processing synchronized with the processor side reference pulse The signal for processing the video signal is formed on the processor device side in synchronization with the reference pulse on the electronic endoscope side. Based on these signals, the signal of the video signal is generated. Since the processing is performed, the power supply line and the signal line can be shared, for example, the electronic endoscope and the processor device can be connected with one coaxial cable, and different types of electronic endoscopes can be connected to the common processor device. It is possible to form a good image even when connected to the. Further, there is no contact failure of the connection pins, and the manufacturing cost is reduced.
[0040]
According to the second aspect of the present invention, the processor device side superimposes an electronic shutter control signal on, for example, a predetermined blanking period of the second field of the video signal supplied through the power / signal sharing line, and Since the electronic shutter control is performed by the electronic shutter control signal separated from the power source on the endoscope side, a good image in which the exposure control by the electronic shutter function is executed can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an electronic endoscope apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a specific configuration of a power supply receiving circuit, a waveform separation circuit, and a waveform superimposing circuit according to an embodiment.
FIG. 3 is a diagram illustrating a state in which a transmission signal is superimposed on a power supply in the waveform superimposing circuit according to the embodiment.
FIG. 4 is a diagram illustrating scope information data stored in the EEPROM of the embodiment.
FIG. 5 is a diagram illustrating a first field signal of a video signal superimposed on a power supply in the embodiment.
FIG. 6 is a diagram illustrating a second field signal of the video signal superimposed on the power supply in the embodiment.
[Explanation of symbols]
A ... Scope (electronic endoscope), B ... Processor device,
12 ... CCD, 13 ... electronic shutter circuit,
14 ... power supply receiving circuit 16, 25 ... waveform separation circuit,
17, 24 ... Waveform superimposing circuit,
19 ... Timing generator (TG),
21, 31 ... microcomputer, 23 ... power supply circuit,
18, 26 ... phase comparison circuit,
27. Synchronization signal generator (SSG),
19a, 27a ... crystal oscillator, 32 ... CDS circuit,
34 ... DSP circuit, 50 ... EEPROM.

Claims (3)

In an electronic endoscope apparatus in which an electronic endoscope equipped with an image sensor is connected to a main body side apparatus including a processor device, and supplies power from the main body side apparatus to the electronic endoscope.
A power / signal sharing line for connecting between the electronic endoscope and the apparatus on the main body side;
A power supply circuit provided in the main body side device for supplying power to the power / signal sharing line;
An electronic endoscope side synchronization signal generating circuit that is provided in the electronic endoscope and forms an electronic endoscope side reference pulse for video signal processing using a scope side oscillator;
A processor-side synchronization signal generating circuit provided in the processor device for forming a processor-side reference pulse for video signal processing using a processor-side oscillator having an oscillation frequency different from that of the scope-side oscillator;
The video signal obtained by the image sensor is superimposed on the power supply of the power / signal sharing line, and either the first field (or first frame) or the second field (or second frame) of the video signal is used . An electronic endoscope side waveform superimposing circuit that superimposes an electronic endoscope side reference pulse in a predetermined blanking period of either field (or frame) ;
The other one in which the electronic endoscope side reference pulse of the first field (or first frame) or the second field (or second frame) of the video signal superimposed on the power supply of the power / signal sharing line is not superimposed. A processor-side waveform superimposing circuit that superimposes a processor-side reference pulse in a predetermined blanking period of a field (or frame) ;
A processor side separation circuit for separating the video signal and the electronic endoscope side reference pulse superimposed on the power / signal sharing line;
An electronic endoscope side separation circuit that separates a processor side reference pulse superimposed on the power / signal sharing line,
The electronic endoscope side synchronization signal generation circuit generates a signal for video signal processing synchronized with the processor side reference pulse obtained from the electronic endoscope side separation circuit, and the processor side synchronization signal generation circuit Generating a signal for video signal processing in synchronization with the electronic endoscope side reference pulse obtained from the processor side separation circuit, and processing the video signal based on these signals Mirror device. An electronic shutter circuit for controlling the charge accumulation time in the image sensor as an electronic shutter speed;
The processor-side waveform superimposing circuit superimposes an electronic shutter control signal in a predetermined blanking period of a video signal supplied by the power / signal sharing line,
The electronic endoscope apparatus according to claim 1, wherein the electronic endoscope side separation circuit separates an electronic shutter control signal superimposed on the power / signal sharing line.   The processor-side waveform superimposing circuit superimposes an electronic shutter control signal in a blanking period other than a blanking period in which an electronic endoscope-side reference pulse and a processor-side reference pulse are superimposed in a video signal. Item 3. The electronic endoscope apparatus according to Item 1 or 2.

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