JPH0414915B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a television camera device, for example, a camera head and a camera control unit (CCU) in a surveillance television camera or the like.
This invention relates to a device for synchronously coupling these by connecting them with a single coaxial cable.

Conventional technology A synchronization signal generation circuit (SSG) is installed in the camera head.
When operating multiple color television cameras equipped with color coders, etc. in a synchronous manner, it is necessary to synchronously combine an SSG with a reference synchronization signal and a color carrier wave. Conventionally, as this type of synchronous coupling method, for example, the synchronous coupling method described in Japanese Patent Publication No. 52-28329, a carrier wave has been AM-modulated with a synchronous coupling signal, transmitted, and supplied to a camera head. There is.

Problems to be solved by the invention The above conventional method uses a carrier wave as a synchronous coupling signal.
Since the configuration uses AM modulation, the circuit becomes complicated,
It cannot be constructed at a low cost, requires highly accurate frequency management, and has problems such as unnecessary radiation.

The present invention provides a television camera device in which subcarrier phase information is transmitted to a camera head as a pulse width change of a horizontal synchronizing signal, and the circuit can be configured more easily and at a lower cost than the conventional device using AM modulation. The purpose is to provide.

Means for Solving the Problems The present invention provides a camera control unit that includes:
The phase difference between the color burst signal generated from the subcarrier output from the first synchronization signal generator and the subcarrier output from the second synchronization signal generator in the video signal supplied from the camera head is detected. A first phase comparison circuit outputs a first phase comparison error signal according to the phase difference, and a pulse width of a horizontal synchronization signal outputted by a second synchronization signal generator according to the first phase comparison error signal. A pulse width modulation circuit that modulates the pulse width is provided in the camera head, and a horizontal synchronization signal whose pulse width is modulated, which is supplied from the pulse width modulation circuit, is converted into a second phase comparison error signal corresponding to the pulse width. a conversion circuit; and a second circuit that compares the phase of the horizontal synchronization signal whose pulse width is modulated with the phase of the horizontal synchronization signal output from the first synchronization signal generator, and outputs a third phase comparison error signal. a phase comparison circuit, and a reset signal generation circuit that is supplied with the vertical synchronization signal output from the second synchronization signal generator and outputs a vertical reset signal,
The second phase comparison error signal output from the conversion circuit locks the phase of the subcarrier generation circuit in the first synchronization signal generator, and the third phase comparison error signal output from the second phase comparison circuit locks the phase of the subcarrier generation circuit in the first synchronization signal generator. By locking the phase of the horizontal synchronizing signal generation circuit in the first synchronizing signal generator and resetting the first synchronizing signal generator using the vertical reset signal output from the reset signal generating circuit, the first synchronizing signal is reset. The generator and the second synchronization signal generator are synchronously coupled.

Operation By transmitting the subcarrier phase information to the camera head 1 as a pulse width change of the horizontal synchronization signal, the subcarrier synchronization signal can be transmitted with a simple circuit configuration.

Embodiment FIG. 1 shows a block system diagram of an embodiment of the apparatus of the present invention. In the figure, 1 is the camera head and 2 is the camera head.
These are connected by a single coaxial cable 3 in the CCU. The output of the constant current source 4 of the CCU 2 is supplied via the cable 3 to the power supply stabilizing circuit 5 of the camera head 1 to obtain a power supply of, for example, 9V.

On the other hand, the video process circuit 6 of the camera head 1
The output is supplied to the frequency characteristic compensation circuit 7 of the CCU 2 via the cable 3, and the frequency characteristic deterioration caused by the cable 3 is compensated for. Video process circuit 6
The output is a video signal including video information and a color burst signal, but does not include a horizontal/vertical composite synchronization signal. Color burst signal is SSG1
It is generated from the subcarrier created in 2.

The output of the frequency characteristic compensation circuit 7 is subjected to blanking processing in the video processing circuit 8, and a regular composite synchronization signal is added thereto.The output is outputted from the output terminals 10 ₁ and 10 ₂ via the buffer circuit 9 as two video signals. taken out. Note that the time constant is changed by operating the switch 11 according to the length of the cable 3 used (0 m, 100 m, 200 m, 300 m), and the amount of compensation for frequency characteristics is changed.

Here, in this embodiment, the camera head 1 and
CCU2 has SSG12 and SSG13 respectively,
For synchronous coupling, the reference camera output coming from the external input terminal 14 is separated by the sync separation circuit 15, and the synchronization signal CCU2 is synchronously coupled to the SSG13, and then this SSG13 and the SSG of the camera head 1 are synchronously coupled.
A system is in place to synchronously connect 12.

The horizontal and vertical synchronization signals output from the SSG 12 are mainly used for timing the video signal output from the camera head, and the horizontal and vertical synchronization signals output from the SSG 13 are used for the composite signal that is added to the video signal. Used for synchronization signals.

For this synchronous coupling system, comparator 1
6, during the color burst period, the subcarrier (SC) from the SSG 13 and the external signal from the terminal 14 are phase-compared, and the phase comparison error signal is used as the SSG signal.
The phase of the 13 output subcarriers is controlled. or,
In the comparator 17, the horizontal synchronization signal from the SSG 13 and the horizontal synchronization signal from the synchronization separation circuit 15 are phase-compared, and a phase comparison error signal is obtained from the SSG1.
Controls the phase of horizontal synchronization signal No. 3. Further, a V reset signal is generated in the V reset generation circuit 18, and the vertical synchronization signal is reset to the SSG 13. As will be described later, the horizontal synchronization signal output from the SSG 13 has its pulse width modulated by subcarrier phase information in the pulse width modulation circuit 19.
Further, as will be described later, the vertical synchronization signal output from the SSG 13 is superimposed with a white balance control signal, a lens and camera head remote control signal in a mixing circuit 20, and is sent to the camera head 1 via a cable 3, respectively.
supplied to

The SSG 13 outputs various pulses such as a blanking signal and a color burst flag pulse in addition to the above-mentioned horizontal synchronization signal, vertical synchronization signal, and subcarrier (SC). As shown in FIG. 1, the SSG 13 supplies a composite synchronization signal and a blanking signal to the video processing circuit 8, and
6, a vertical synchronization signal to the mixing circuit 20, a horizontal synchronization signal to the H shift circuit 24, a color burst flag pulse to the comparator 27, The shift circuit 28 is supplied with a subcarrier (SC) and a color burst flag pulse.

In the camera head 1, the phase of the horizontal synchronization signal separated by the synchronization separation circuit 21 is compared with the horizontal synchronization signal output from the SSG 12 in the comparator 22, and the horizontal synchronization signal generation circuit of the SSG 12 is locked using the phase comparison error signal. . In this case, operate the switch 23 according to the length of the cable 3 used to shift the delay amount of the horizontal synchronizing signal by 1 μs in steps of every 100 m, and adjust the horizontal The synchronization signal is finely adjusted with a variable width of ±1μs to compensate for the amount of delay in the horizontal synchronization signal due to changes in cable length.

The switch 23 and volume 25 are provided in this way because the horizontal blanking period for shifting the horizontal synchronization signal transmitted from the CCU 2 is narrow.
1μs is the limit, and the length of cable 3 is up to 300m.
This is because the shift by CCU2 alone cannot compensate.

The above horizontal synchronization is performed from CCU 2 to camera head 1.
The falling edge of the horizontal synchronization signal transmitted to the horizontal synchronization signal is used as horizontal synchronization coupling information.

Further, the vertical synchronization signal separated by the synchronization separation circuit 21 is supplied to a V reset generation circuit 26, which generates a V reset signal and applies a reset of the vertical synchronization signal to the SSG 12.

By the way, in this embodiment, in addition to the above-mentioned horizontal synchronization signal and vertical synchronization signal, the signals transmitted from the CCU 2 to the camera head 1 include a subcarrier synchronization signal, a white balance control signal, and a lens and pan head remote control signal. , these signals are multiplexed during the blanking period.

In particular, the present invention is characterized in that subcarrier phase information is transmitted to the camera head 1 as a pulse width change of a horizontal synchronizing signal.

The signal output from the frequency characteristic compensation circuit 7 of the CCU 2 is supplied to the comparator 27, where:
During the color burst period, the phase comparison error signal is compared with a subcarrier taken out from the SSG 13 of the CCU 2 and supplied via an SC 360° shift circuit 28 to be described later, and the phase comparison error signal is supplied to the pulse width modulation circuit 19. Here, the horizontal synchronizing signal taken out from the SSG 13 and supplied via the H shift circuit 24 has its pulse width modulated by the phase comparison error signal from the comparator 27, for example, as shown in FIGS. 2A to 2C. Ru. Note that compensation for subcarrier phase shifts due to changes in cable length is adjusted by the volume 29 of the SC360° shift circuit 28.

On the other hand, since the main purpose of white balance adjustment control is to compensate for changes in color temperature, only one adjustment volume, volume 30, is used, and the pulse width modulation circuit 31 is used to adjust the width of approximately 1 axis to 2500.
〓, 3200〓, 10000〓 will be compensated. In the pulse width modulation circuit 31, the horizontal synchronization signal from the H shift circuit 24 changes its pulse width to a volume 30.
The signal is modulated by the adjustment and supplied to the mixing circuit 20. Here, due to the vertical synchronizing signal from the SSG 13, as shown in FIG. 3, a pulse P ₁ (H cut pulse) which is within the vertical synchronizing signal period T and has a polarity opposite to that of the horizontal synchronizing signal is transmitted to, for example, A to C in FIG. It can be varied as shown.

On the other hand, the lens and pan head remote control signal S (for example, a 4-bit digital signal) input to the terminal 32
is supplied to the mixing circuit 20, where it is superimposed, for example, during the horizontal synchronizing signal pulse _P2 in the latter half of the vertical blanking period T _B , as shown in FIG.
Note that the timing of the remote control signal S is obtained by counting a predetermined number of horizontal synchronization signals from the start of the vertical blanking period T _B.

In this way, in this embodiment, subcarrier phase information is transmitted as a pulse width modulation of the horizontal synchronization signal, white balance control information is transmitted as a pulse width modulation of the H cut pulse _P1 , and The remote control information is transmitted as a 4-bit digital signal within the vertical blanking period T _B.

In the camera head 1, the horizontal synchronization signal separated by the synchronization separation circuit 21 is converted by the converter 33 into a DC voltage phase comparison error signal according to its pulse width, and is supplied to the subcarrier generation circuit of the SSG 12 to generate the subcarrier phase. lock.

Further, the H cutting pulse separated by the synchronous separation circuit 21 is converted into a DC voltage according to the pulse width by the converter 34, and the gain of the red signal circuit and the gain of the blue signal circuit of the video process circuit 6 are converted into a DC voltage according to the pulse width. variable based on the gain of

Further, the horizontal synchronization signal and vertical synchronization signal separated by the synchronization separation circuit 21 are sent to the video processing circuit 6.
remote control signal processing circuit 3 along with the output video signal of
5, where the lens and pan head remote control signal at a position where a predetermined number of horizontal synchronization signals are counted from the start of the vertical blanking period is detected and converted to a DC voltage according to a digital code,
Drive and control the lens and camera platform.

Effects of the Invention According to the device of the present invention, the phase information of the subcarrier is transmitted to the camera head as a pulse width change of the horizontal synchronization signal. It can be performed with a simple circuit configuration, is inexpensive, does not require high-precision frequency management compared to conventional systems, and does not generate unnecessary radiation.

[Brief explanation of drawings]

FIG. 1 is a block system diagram of an embodiment of the device of the present invention, FIG. 2 is a waveform diagram showing the pulse width modulation of the horizontal synchronizing signal, and FIG. 3 is a diagram for explaining the position of the H cutting pulse. FIG. 4 is a diagram showing the pulse width modulation of the H cutting pulse, and FIG. 5 is a diagram for explaining the positions of the lens and pan head remote control signals. 1...Camera head, 2...Camera control unit (CCU), 3...Coaxial cable, 6...
...Video process circuit, 12, 13...Synchronization signal generation circuit (SSG), 14...External input terminal, 19
... Pulse width modulation circuit, 20 ... Mixing circuit, 21
... Synchronization separation circuit, 24 ... H shift circuit, 27
... Comparator, 28 ... SC shift circuit, 3
3...Converter.

Claims (1)

[Scope of Claims] 1. A horizontal synchronization signal, a vertical synchronization signal, etc. are transmitted from a camera control unit having a second synchronization signal generator to a camera head having a first synchronization signal generator. In a television camera device in which a signal generator and the second synchronization signal generator are synchronously coupled, the camera control unit includes a signal of the first synchronization signal generator in the video signal supplied from the camera head. A first detecting phase difference between the color burst signal generated from the output subcarrier and the subcarrier output from the second synchronization signal generator, and outputting a first phase comparison error signal corresponding to the phase difference. a phase comparison circuit; and a pulse width modulation circuit that modulates the pulse width of the horizontal synchronization signal output from the second synchronization signal generator according to the first phase comparison error signal; a conversion circuit that converts a horizontal synchronization signal, the pulse width of which is modulated, supplied from the pulse width modulation circuit into a second phase comparison error signal that corresponds to the pulse width; a second phase comparison circuit that compares the phase of the horizontal synchronization signal with the phase of the horizontal synchronization signal output from the first synchronization signal generator and outputs a third phase comparison error signal; a reset signal generation circuit that is supplied with the vertical synchronization signal output from the synchronization signal generator and outputs a vertical reset signal; The phase of the subcarrier generation circuit in the signal generator is locked, and the third phase comparison error signal output from the second phase comparison circuit is used to lock the phase of the horizontal synchronization signal generation circuit in the first synchronization signal generator. By locking the phase and resetting the first synchronizing signal generator by the vertical reset signal output from the reset signal generating circuit, the first synchronizing signal generator and the second synchronizing signal generator A television camera device characterized by synchronous coupling with a camera.