KR100647553B1 - Synchronous circuit of a multi-camera system - Google Patents

Abstract

The present invention relates to a synchronization circuit of a multi-camera system composed of a reference signal generator, a phase comparator, a calculator, and a divider for synchronously controlling at least one camera on one screen divider. The reference signal generator outputs a color signal generation frequency signal as a reference signal during internal synchronization, and outputs a power frequency as a reference signal during external synchronization, and the phase comparator feeds back the system drive signal inputted according to the synchronization selection signal. The phase comparison signal is output by matching the reference signal, and the calculation unit outputs a DC voltage of a predetermined level by varying the path of the low pass filtering process and the voltage controlled oscillation process of the phase comparison signal according to the synchronization selection signal, and the division unit outputs the DC voltage. The frequency component of the voltage is divided in half to output a system driving signal. As a result, since commercial AC power applied to each camera is used as a synchronization signal, synchronization can be performed without installing a separate cable for external synchronization.

Multi Camera, Internal Synchronization, External Synchronization, AC Power Frequency, Crystal Oscillation, LC Oscillation

Description

Synchronous circuit of a multi-camera system

1 is a configuration diagram of a synchronization circuit of a multi-camera system according to a first embodiment of the present invention.

2 is a block diagram illustrating a synchronization circuit of a multi-camera system according to a second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: reference signal generator 110, 350: crystal voltage controlled oscillator

120: waveform shaper 130: phase adjuster

200: phase comparison unit 300, 500: calculation unit

310, 370, 510, 540: selectors 320, 520: vertical low pass filter

330: LC voltage controlled oscillator 340, 530: vertical low pass filter

360: stopper 400: dispensing part

The present invention relates to a synchronization circuit of a camera having a multi function, and more particularly, to a synchronization circuit of a camera having a multi function for synchronizing and operating at least one or more cameras on one screen divider.

Conventionally, when reproducing images captured by a plurality of cameras to a single monitor through a screen splitter, there is a problem in that an installation cost increases with a burden of separately installing an external synchronization cable.

However, when the external synchronization is not used, that is, the camera clock is generated by oscillating the crystal oscillator during the camera's internal synchronization, and the system clock is generated by operating the LC voltage oscillator during the power frequency synchronization. .

In this internal synchronization or external synchronization mode, since the clock oscillated from the crystal oscillator is used as a 4fc clock that generates a color signal by halving, the crystal oscillation must be continued for the color signal generation even in the external synchronization mode. There was a problem that noise occurs due to the clock interference between.

Therefore, an object of the present invention is to solve this problem, and when a video signal provided from a plurality of cameras is reproduced on one monitor through one screen divider, a separate device for external synchronization may be used to synchronize the plurality of cameras. It is to provide a synchronization circuit of a camera having a multi-function which does not need to install an external synchronization cable.

In addition, another object of the present invention is to provide a synchronization circuit of a camera having a multi-function capable of removing noise caused by the interference between the clock of the external synchronization system and the internal synchronization system.

Synchronization circuit of a multi-camera system according to a feature of the present invention for achieving the above object,

A reference signal generator for outputting a first reference signal for generating a color signal through crystal oscillation, and for outputting a second reference signal matched to a predetermined phase of a commercial AC power supply by an applied phase adjustment signal;

In internal synchronization, a phase comparison signal is output by comparing the system driving signal fed back and input with the first reference signal, and in phase synchronization, the phase comparison signal is compared by comparing the system driving signal with the second reference signal. A phase comparator for outputting a;

A low frequency filtering and voltage controlled oscillation of the vertical frequency components of the phase comparison signal during the external synchronization, and a low frequency filtering and voltage controlled oscillation of the horizontal frequency components of the phase comparison signal during the internal synchronization; And

And a divider for dividing the signal output from the calculator to output a system driving signal through one end, and to output the system driving signal to the phase comparator through the other end.

According to the synchronization circuit of the multi-camera system, since a commercial AC power applied to a plurality of cameras is used as an external synchronization signal, it is possible to synchronize without installing a separate cable for external synchronization.

Then, embodiments will be described so that those skilled in the art can easily implement the present invention.

1 is a structural diagram of a synchronization circuit of a camera having multiple functions according to a first embodiment of the present invention.

Referring to FIG. 1, the synchronization circuit of the multi-camera system according to the present invention includes a reference signal generator 100, a phase comparator 200, a calculator 300, and a divider 400.

The reference signal generator 100 includes a 4fsc oscillator 110 for generating a 4fsc clock for generating a color signal, a waveform shaper 120 for shaping and outputting a waveform of a commercial AC power applied from the outside, and a phase adjusting terminal. The phase adjuster 130 outputs a signal adjusted to a predetermined phase of the commercial AC power supply by the provided phase adjustment signal b ', and is output from the 4fsc oscillator 110 as a first reference signal during internal synchronization. The 4fsc clock a for generating a color signal to be output is output to the phase comparator 200, and a signal having a power frequency component as a second reference signal is output to the phase comparator 200 during external synchronization.

The phase comparator 200 matches the system driving signal fed back and input to the first and second reference signals a and c output from the reference signal generator 100 according to the applied internal / external synchronization selection signal. Output That is, during internal synchronization, the system driving signal i is matched with the clock signal for 4fsc for generating a color signal, and the phase comparison signal d is output to the operation unit 300, and during external synchronization, the phase adjustment signal ( b ') matches the system drive signal i to a signal c that is aligned with a predetermined phase of the commercial AC power frequency signal, and outputs a phase comparison signal to the calculation unit 300.

The operation unit 300 may include a first selector 310 for switching an output path of an input signal according to an internal / external synchronization selection signal, and a first vertical low pass filter that passes only vertical frequency components of the input signal and filters out other components. 320, LC voltage controlled oscillator 330, a first horizontal low pass filter 340 that passes only the horizontal frequency components of the input signal and removes other components, crystal voltage controlled oscillator 350, internal / external synchronization The stopper 360 controls the driving of the crystal oscillation controller according to the selection signal, and the second selector 370 for switching the input path.

The calculation unit 300 passes only the vertical frequency component of the phase comparison signal d inputted after the signal path is switched according to the internal / external synchronization selection signal by the user, and then outputs the operation signal by performing LC voltage control oscillation. Alternatively, after passing only the horizontal frequency component of the phase comparison signal, the crystal voltage is controlled to oscillate and outputs an operation signal to the divider 400.

The division unit 400 outputs the system driving signal i, which is divided into a predetermined level, preferably 1/2, of the frequency component of the operation signal output from the operation unit 300 through one end, and phases through the other end. Feedback to the comparator 200.

Hereinafter, the principle of the operation of the synchronization circuit of a camera having a multi-function according to an embodiment of the present invention will be described in more detail by dividing each of an external synchronization and an internal synchronization.

First, the operation during external synchronization will be described.

The reference signal generator 100 outputs a power frequency of an AC power source, preferably 60 Hz as a reference signal, wherein the AC power frequency is 60 Hz in the NTSC (National Television System Committe) method, and PAL (Phase Alternation by Line) ) Is 50㎐ in the method. For example, in a country using the NTSC method, the waveform shaper 120 receives an AC power of 60 kV from the outside and shapes the DC power source of 3 to 5 volts suitable for each camera and outputs it to the phase adjuster 130. do.

The phase adjuster 130 responds to a waveform shaper in response to a phase adjustment signal b 'provided from a phase adjustment terminal (not shown) to display a plurality of images captured by a plurality of cameras on one screen through a screen divider. The phase of the shaped signal b provided from 120 is adjusted, and the phase-adjusted signal c is used as a reference signal and outputted to the phase comparator 200. At this time, the reference signal is a signal adjusted to a predetermined phase of a signal of 60 Hz, which is a commercial AC power supply signal, by the phase adjustment signal b '.

The operation of the phase adjuster 130 will be described in more detail in accordance with the external synchronization. The external synchronization synchronizes the system with the AC power signal, and thus, at a certain position, that is, at an angle, from the zero crossing point during the cycle of the power signal. When it is necessary to synchronize a plurality of cameras, a reference signal can be input and adjusted.

For example, if multiple cameras are installed at the same time and you want to centrally control multiple cameras using a screen splitter, you can use the phase adjuster 130 to synchronize each camera at the same position (angle) of the AC power signal. have. Also, when the 4fsc oscillator 110 is in the external synchronization mode, the 4fsc oscillator 110 is limited to color signal generation regardless of phase comparison.

The phase comparator 200 matches the system driving signal i fed back according to the external synchronization selection signal to the reference signal c output from the phase adjuster 130, and the phase comparison signal d as a matched signal. ) Is output to the first selector 310 of the calculator 300.

The first selector 310 switches the output path to the first vertical low pass filter 320 in response to the external synchronization mode selection signal, and outputs a phase comparison signal d to the first vertical low pass filter 320.

The first vertical low pass filter 320 filters the phase comparison signal excluding the 60 Hz component from the vertical component of the phase comparison signal d, preferably the phase comparison signal d, and then supplies the LC voltage controlled oscillator 330 to the LC voltage controlled oscillator 330. Output

The LC voltage controlled oscillator 330 receives the low frequency filtered signal e of the vertical component from the first vertical low pass filter 320 and LC oscillates and outputs the LC oscillation signal f to the second selector 370. . In this case, when the external synchronization selection signal is applied, the stopper 360 stops the operation of the crystal voltage controlled oscillator 350 to remove the interference between the synchronization modes.

The second selector 370 is switched to the LC voltage controlled oscillator 330 side according to the external synchronization mode selection signal provided to provide the LC oscillation signal f output from the LC voltage controlled oscillator 330 to the division unit 400. do.

The divider 400 is preferably constituted by a 1/2 divider, and divides the frequency component of the LC oscillation signal f output from the second selector 370 to provide a corresponding system drive signal i. Output to the outside. These system drive signals are respectively transmitted to a plurality of cameras not shown, and are also fed back to the phase comparator 200.

This operation is repeatedly performed, so that the output of the phase comparison unit 200, that is, the signal having the vertical frequency component is fed back to the LC voltage controlled oscillator 330 to drive the multi-camera system. At this time, the reference for phase comparison when the camera is operated in accordance with external synchronization is a signal c having a power source frequency component corresponding to a phase manipulation signal output from an AC power supply signal, a waveform being shaped, and output from a phase adjustment terminal.

Next, the operation at the internal synchronization will be described.

The 4fsc oscillator 110 of the reference signal generator 100 outputs a 4fsc signal a, preferably 15.7 kHz, which is a frequency signal for generating a color signal, to the outside as a reference signal, and also to the phase comparator 200. Output

The phase comparison unit 200 compares a phase in which the system driving signal i fed back according to the internal synchronization selection signal as the synchronization selection signal is matched to the color signal generation frequency signal a output from the crystal oscillator 110. The signal d is output to the first selector 310 of the calculator 300.

The first selector 310 switches the output path of the phase comparison signal d to the first horizontal low pass filter 340 in response to the internal synchronization mode selection signal, thereby converting the phase comparison signal d provided to the first horizontal low pass. Output to the pass filter 340.

The first horizontal low pass filter 340 filters and removes the horizontal component of the phase comparison signal d and outputs the same to the crystal voltage controlled oscillator 350. In this case, the stopper 360 generates the driving stop signal s in response to the internal synchronization selection signal to turn on the operation of the crystal voltage controlled oscillator 350.

The crystal voltage controlled oscillator 350 operates according to the operation ON signal s of the stopper 350 to receive the low frequency filtered signal g of the horizontal component from the horizontal low pass filter 320 and to oscillate the crystal by oscillating the crystal. (h) is output to the second selector 370.

The second selector 370 switches the input path of the oscillation signal according to the internal synchronization mode selection signal provided to provide the crystal oscillation signal output from the crystal voltage controlled oscillator 350 to the division unit 400.

The frequency divider 400 is preferably configured as a 1/2 frequency divider, and divides the frequency component of the LC oscillation signal output from the second selector 370 by 1/2 to output a corresponding system driving signal i. These system drive signals are transmitted to a plurality of cameras not shown, respectively, and are also output to the phase comparison unit 200.

Such an operation is repeatedly performed so that the output of the phase comparison unit 200, that is, a signal having a horizontal frequency component is fed back to the crystal voltage controlled oscillator 350 to drive the multi-camera system. At this time, the reference of the phase comparison is the clock signal for generation 4fsc (a) output from the color signal generation 4fsc oscillator 110.

Next, a synchronization circuit of a camera having multiple functions according to a second embodiment of the present invention will be described.

2 is a schematic diagram of a synchronization circuit of a camera having multiple functions according to a second embodiment of the present invention.

Referring to FIG. 2, a synchronization circuit of a camera having a multi-function according to a second embodiment of the present invention includes a reference signal generator 100, a phase comparator 200, a calculator 500, and a divider 400. In this case, the configuration and operation of the reference signal generator 100, the phase comparator 200, and the divider 400, which are assigned the same reference numerals as in FIG. 1, are the same as those of the first embodiment. Therefore, description thereof will be omitted, and only the changed operation unit 500 will be described.

The calculation unit 500 includes a third selector 510, a second vertical low pass filter 520, a second horizontal low pass filter 540, and a fourth selector 540, and compares phases according to a synchronization selection signal. The low frequency filtering process and the voltage controlled oscillation process of the phase comparison signal output from the unit 200 are changed to output a DC voltage having a predetermined level to the divider unit 400.

More specifically, the third selector 510 allocates an output path of the phase comparison signal d output from the phase comparison unit 200 according to the synchronization selection signal. That is, the phase comparison signal d is output to the second vertical low pass filter 520 when the synchronization selection signal is in the external synchronization mode, and the phase comparison is performed by the second horizontal low pass filter 530 when the synchronization selection signal is in the external synchronization mode. Output the signal d.

The second vertical low pass filter 520 filters and removes the phase comparison signal except the vertical component, preferably 60 Hz, of the phase comparison signal d when the synchronization selection signal is the external synchronization selection signal. 540).

The second horizontal low pass filter 530 filters and removes the phase comparison signal except the horizontal component of the phase comparison signal d, preferably the 15.7 kHz component, when the synchronization selection signal is an internal synchronization selection signal. 540).

The fourth selector 540 is a low pass filtering signal j output from the second vertical low pass filter 520 and a low pass filtering signal k output from the second horizontal low pass filter 530 according to the synchronization selection signal provided. Assigns the output path to

The LC voltage controlled oscillator 550 oscillates the signal output from the fourth selector 540 to output the LC oscillation signal to the divider 400, and the operation of the oscillator 400 is as described with reference to FIG. 1.

As mentioned in the first and second embodiments of the present invention, the technical principle of the present invention is to adjust the phase comparison result d of the phase comparator 200 vertically or horizontally according to the user's selection of the synchronization mode. The voltage of a predetermined level is converted into a system driving signal through the low pass filter, respectively, and outputted, and is fed back to the phase comparator 200.

In addition, 4fsc clock for color signal generation is used as the master clock, and it is used as the reference for phase comparison. For external synchronization, power frequency is used as the master clock for the phase comparison.

As such, since the 4fsc clock is separately used to generate the color signal, the internal synchronization clock oscillation circuit can be stopped during external synchronization, thereby eliminating interference noise with the external synchronization clock.

While the foregoing has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

As described above, when at least one or more cameras are simultaneously installed according to the present invention, for example, when a plurality of cameras are to be centrally controlled using a screen splitter, a commercial AC power source and a clock for generating color signals of the cameras may be used. By synchronizing each camera with a signal as a reference signal, a camera system having a multi-function can be configured simply without adding an external synchronization input cable, thereby reducing installation costs.

In addition, by synchronizing the paths of the internal synchronization and the external synchronization to synchronize the plurality of cameras having the multi-function, it is possible to block noise between the synchronization operations generated during the synchronization of the multi-camera system.

Further, as mentioned in the second embodiment of the present invention, component reduction can be realized by unifying only the LC voltage controlled oscillation without the need of separately oscillating the system oscillation circuit during the internal synchronization and the external synchronization of the multi-camera system.

Claims (5)

In the synchronization circuit of the multi-camera, A reference signal generator for outputting a first reference signal for generating a color signal through crystal oscillation, and for outputting a second reference signal matched to a phase of a commercial AC power source by an applied phase adjustment signal; In internal synchronization, a feedback signal is inputted to compare a system driving signal for driving the camera and the first reference signal to output a phase comparison signal, and in external synchronization, the system driving signal and the second reference signal are output. A phase comparator for comparing and outputting a phase comparison signal; A low frequency filtering and voltage controlled oscillation of the vertical frequency components of the phase comparison signal during the external synchronization, and a low frequency filtering and voltage controlled oscillation of the horizontal frequency components of the phase comparison signal during the internal synchronization; And And a divider for dividing the signal output from the computing unit to output a system driving signal through one end, and to output the system driving signal to the phase comparator through the other end. . The method of claim 1, wherein the reference signal generator is An oscillator for outputting a first reference signal for generating a color signal; A waveform shaping unit which receives a commercial AC power signal and converts the signal into a signal having a predetermined level; And And a phase adjusting unit for adjusting a phase of a signal output from the waveform shaping unit in response to an applied phase adjusting signal to output a corresponding second reference signal. The method of claim 1, wherein the operation unit A first selector for switching the output path of the phase comparison signal according to the internal / external synchronization selection signal; A second low pass filter for filtering the phase comparison signal according to the external synchronization selection signal and outputting a first phase comparison signal having a horizontal frequency component; A first voltage controlled oscillator for LC oscillating the first phase comparison signal; A first low pass filter filtering the phase comparison signal according to the internal synchronization selection signal and outputting a second phase comparison signal having a vertical frequency component; A second voltage controlled oscillator for crystal oscillating the second phase comparison signal; And And a second selector configured to output the first phase comparison signal to the division unit or to output the second phase comparison signal to the division unit according to the internal / external synchronization selection signal. . The synchronization circuit of claim 3, wherein the operation unit further comprises a stopper for stopping the operation of the second voltage controlled oscillator when an external synchronization selection signal is applied. The method of claim 1, wherein the operation unit A third selector for switching the output path of the phase comparison signal according to the internal / external synchronization selection signal; A third low pass filter for filtering the phase comparison signal according to the external synchronization selection signal and outputting a first phase comparison signal having a horizontal frequency component; A fourth low pass filter filtering the phase comparison signal according to the internal synchronization selection signal and outputting a second phase comparison signal having a vertical frequency component; A fourth selector configured to output the first phase comparison signal to the division unit or to output the second phase comparison signal to the division unit according to the internal / external synchronization selection signal; And And a voltage controlled oscillator for LC oscillating and outputting the first and second phase comparison signals routed by the fourth selector.

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