JP2614476B2 - Input impedance adjustment circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an input impedance of an external synchronization input terminal of a television camera or the like, which is determined based on a characteristic impedance of a transmission line according to a level of an input video signal. The present invention relates to an input impedance adjustment circuit that switches to high impedance.

[Conventional technology]

Conventionally, indoor and outdoor surveillance systems include TV cameras,
It is constructed using a monitor television or the like.

When the system is constructed using a plurality of television cameras, the video signal (composite video signal) of the reference television camera is usually supplied to the external synchronization input terminal of each of the remaining television cameras in order to synchronize the cameras. And providing external synchronization to each of the remaining television cameras.

For example, in the case of being constructed using two television cameras, as shown in FIG. 2, a reference television camera (A)
The external synchronization input terminal (ei) of the remaining television camera (B) is connected to the video output terminal (vo) of the other via a transmission line (La), and the video signal of the input terminal (ei) is converted by the camera (B). A video signal is formed in synchronization with the separated synchronization signal,
The video signal is output from the video output terminal (vo) 'of the camera (B) to the transmission path (Lb).

By the way, the transmission unit (La). As (Lb), a coaxial cable having a characteristic impedance of 75Ω is used as in the case of a normal video signal transmission path.

In the case of FIG. 2, since the video signals of the cameras (A) and (B) are monitored by the two monitor televisions (M1) and (M2), the transmission path (La) is connected to the output terminal (v).
o), the input terminal (ei), and the video axis input terminal (vi) of the television (M1) are connected to three T-shaped coaxial connectors (a), (b), and (c), respectively. k).

The transmission line (Lb) is composed of one coaxial cable (d) having both ends connected to the output terminal (vo) 'and the video input terminal (vi)' of the television (M2).

On the other hand, when a monitoring system is constructed using one monitor television, for example, the television (M1) instead of using two televisions (M1) and (M2) as shown in FIG. And (d) are alternately supplied to the input terminal (vi) of the television (M1) via the switcher.

According to the surveillance system, for example, the video signals of the cameras (A) and (B) are also supplied to a computer, and the video signals of both cameras (A) and (B) are image-processed and monitored. Sometimes.

By the way, the cameras (A) and (B) and the television (M
1) and (M2) are the same as ordinary video equipment, because the video signal transmission path is terminated with a characteristic impedance of 75Ω for matching, so that video signals from input terminals (ei), (vi), (vi) ', etc. The input impedance of each input terminal of the signal and the output impedance of each output terminal of the video signal such as the output terminals (vo) and (vo) 'are set to the characteristic impedance of 75Ω.

Therefore, as shown in FIG. 2, when the video signal of the camera (A) is supplied to the camera (B) and the television (M1) via the transmission line (La), the input impedance of the input terminals (ei) and (vi) is reduced. The transmission line (La) is terminated by the parallel combined impedance. At this time, the input terminal (e) is terminated based on a decrease in the termination impedance of the transmission line (La) from the matching impedance.
Level (voltage) of video signal input to i) and (vi)
Is significantly lower than the rated level in the matching state, that is, when the camera (B) and the television (M1) are individually supplied.

Then, when the video signal at the input terminal (ei) drops below the rated level by a certain amount or more, the camera (B) cannot obtain a synchronization signal of an appropriate level due to synchronization separation, making it difficult to output a normal video signal. .

Even if the video signal at the input terminal (ei) becomes too large than the rated level, it becomes difficult to obtain a synchronization signal of an appropriate level due to synchronization separation.

Therefore, in the conventional surveillance system, as shown in FIG. 3, a video distributor (VD) is provided instead of the connector (k) in FIG. 2, or an input terminal (ei) is connected to the camera (B). Is provided with a mechanical switch for manually switching the input impedance of the input terminal to a characteristic impedance of 75Ω and a high impedance (for example, 10KΩ) sufficiently larger than the characteristic impedance, and when connected as shown in FIG. Is set to a high impedance, thereby preventing mismatching of the transmission line (La) and preventing a decrease in the level of the video signal at the input terminal (ei).

In Japanese Utility Model Application Laid-Open No. 58-149875 (H04N9 / 39), when the color video signals of a plurality of television cameras are switched and supplied to one monitor television via a coaxial cable, they are input to the monitor television. An automatic compensating amplifier of a color TV signal transmission device for correcting a high frequency characteristic of a video signal according to a color burst level of the video signal is described.

[Problems to be solved by the invention]

By the way, when the distributor (VD) is used as shown in FIG. 3, since the distributor (VD) is a separate device from the camera (B) and the like, the number of constituent devices of the monitoring system increases, and There is a problem that the configuration becomes complicated and the cost increases.

On the other hand, when a camera (B) is provided with a mechanical switch to manually switch the input impedance of the input terminal (ei),
Instead of requiring the distributor (VD), a large mechanical switch must be provided in the camera (B), so that the camera (B) cannot be downsized and the external design of the camera (B) is impaired. In addition, there is a problem that the input impedance must be switched according to whether the television (M1) is connected to the transmission line (La), for example, and a complicated operation is required. .

For example, when the above-mentioned mechanical switch is provided in the operation cabinet closed by the door of the camera (B), the switching operation requires the opening and closing operation of the door, and the operation is extremely complicated.

Further, when the input impedance of the input terminal (ei) is manually switched, it is not easily known whether or not the input impedance has been correctly switched by the switching. For example, when the camera (B) is additionally provided later. In
Measurement of input impedance and the like must be performed using a measuring instrument, and there is a problem that appropriate switching of input impedance cannot be easily performed.

The present invention has been made in consideration of the above-mentioned problems, and the input impedance of an external synchronization input terminal such as an input terminal (ei) of a camera (B) can be adjusted without providing a distributor on a transmission line. And without using mechanical switches,
The purpose is to automatically switch between the characteristic impedance and high impedance of the transmission line automatically and automatically control the video signal input to the external synchronization input terminal to the rated level when the transmission line is in a matching state. .

[Means for solving the problem]

Means for achieving the above object will be described below with reference to FIG. 1 corresponding to the embodiment.

An impedance adjustment circuit according to the present invention detects an external synchronization input terminal (ei) connected to a video signal transmission line (La), a synchronization level of a video signal at the input terminal (ei), and detects the synchronization level. A synchronous level detecting section (1) for outputting a signal; and a semiconductor switch based on a decrease and a rise of the detection signal from a reference level, that is, switching of a transistor (Q) to change an input impedance of the input terminal (ei) to the transmission line. And an impedance switching section (2) for switching from the characteristic impedance of (La) to a high impedance sufficiently larger than the characteristic impedance and vice versa.

[Action]

Therefore, according to the present invention, for example, the transmission path (L
Other input terminals of the video signal other than the input terminal (ei) are also connected to a), and the transmission path (La) becomes inconsistent, and the input terminal (e)
When the video signal of i) falls below the rated level, the input of the input terminal (ei) is turned off by turning off the transistor (Q) of the switching section (2) based on the fall of the detection signal of the detection section (1) from the reference level. The impedance is switched from the characteristic impedance determined by the resistance (Ra) to the high impedance determined by the resistances (Rb) and (Rc).
When the input impedance of the input terminal (ei) is high impedance and the other input terminal is disconnected from the transmission line (La) and the video signal of the input terminal (ei) becomes higher than the rated level, the detection unit (1) The input impedance of the input terminal (ei) is switched from high impedance to characteristic impedance by turning on the transistor (Q) of the switching unit (2) based on the rise of the detection signal from the reference level in (2).

The input impedance of the input terminal (ei) is automatically switched according to the matching state of the transmission line (La) by a simple electronic circuit configuration using a transistor (Q) and the like. The video signal at the input terminal (ei) is automatically controlled to the rated level without providing a distributor and without providing a large mechanical switch in the camera (B).

〔Example〕

Next, the present invention will be described in detail with reference to FIG. 1 showing one embodiment.

In FIG. 1, the same signals as those in FIGS. 2 and 3 indicate the same signals, and (1) and (2) are a synchronization level detection unit and an impedance switching unit provided in the camera (B).
The input impedance of the input terminal (ei)
Form an input impedance adjustment circuit that selectively switches between characteristic impedance 75Ω and high impedance of 10KΩ or more in a).

The detection unit (1) includes a buffer circuit (3) connected to the input terminal (ei), a low-pass filter (4), an amplifier (5), and a clamp circuit (6) connected in series to the buffer circuit (3). ), A sample-and-hold circuit (7), a detection circuit (8), a synchronization separation circuit (9), a differentiation circuit (10), and a synchronization circuit provided in series between the buffer circuit (3) and the sample-and-hold circuit (7). And a waveform shaping circuit (11).

The switching unit (2) includes a comparison unit (12) that determines the level of the detection signal D of the detection unit (1) output from the detection circuit (11) and an RS that holds a comparison result of the comparison unit (12). Type flip-flop (13) and Q of flip-flop (13)
An impedance section (14) for selectively switching the input impedance of the input terminal (ei) to a characteristic impedance or a high impedance according to the level of the output signal of the output terminal (q).

The comparing section (12) includes two comparators (12a) and (12b) to which the detection signal D is input, and two comparators (12a) and (12a).
b) consists of three voltage dividing resistors (R1), (R2) and (R3) for setting the upper and lower level voltages A and B.

The signal output from the comparator (12a) to the reset terminal (r) of the flip-flop (13) rises from the low level to the high level only when the level (voltage) of the detection signal D changes to the voltage A or more. Top flip-flop (1
3) The signal output from the comparator (12b) to the set terminal (S) of the flip-flop (13) is changed from the low level to the high level only when the level of the detection signal D is changed to the voltage B or less. And the flip-flop (13) is set.

The impedance section (14) includes an inverter (14a) for level inversion connected to the output terminal (q) of the flip-flop (13), an NPN transistor (Q) forming a semiconductor switch, and a transistor (Q). ), A resistor (Ra) for characteristic impedance of 75Ω provided between the emitter and the ground, and two resistors (R) for impedance provided in series between the power supply terminal (+ B) and the ground.
b), (Rc), the pull-down resistor (R4) provided between the input terminal of the inverter (14a) and the ground, and the output terminal of the inverter (14a) and the base of the transistor (Q). It comprises a base input resistor (R5) provided and a pull-down resistor (R6) provided between the base of the transistor (Q) and the ground.

The input terminal (ei) is connected to a video signal line (e) for external synchronization of the camera (B) via a coupling capacitor (C), and a collector of a transistor (Q) and a resistor (Rb). ) And (Rc) are connected to the line (e), and the parallel combined impedance Zbc of the resistors (Rb) and (Rc) is the impedance Za of the resistor (Ra).
The resistance values of the resistors (Rb) and (Rc) are set so as to be 10 KΩ or more, which is sufficiently larger than (= 75Ω).

And the video signal (composite video signal) of the input terminal (ei)
Are input to a filter (4) and a synchronization separation circuit (9) via a buffer circuit (3), and unnecessary high-band components are reduced and removed by the filter (4), and the synchronization separation circuit (9) ) Separates and extracts the horizontal synchronizing signal.

Further, the output signal of the filter (4) is input to the clamp circuit (6) via the amplifier (5), and the leading end of the horizontal synchronizing signal is DC-clamped by the clamp circuit (6). The output signal is input to the sample and hold circuit (7).

The horizontal synchronizing signal output from the sync separation circuit (9) is differentiated by a differentiating circuit (10), and the output signal of the differentiating circuit (10) is shaped by a waveform shaping circuit (11). From 11) to the sample and hold circuit (7),
A sampling pulse is output at the timing of the back porch of the horizontal synchronization signal.

Therefore, the sample and hold circuit (7) samples and holds the horizontal synchronization level (voltage) of the video signal at the input terminal (ei) and outputs the same to the detection circuit (8).

Then, a detection signal D proportional to the horizontal synchronization level of the video signal at the input terminal (ei) is formed by the DC detection of the detection circuit (8), and the detection signal D is applied to the non-inverting input terminal ( +), Inverting input terminal (-) of comparator (12b)
Is input to

By the way, the input impedance of the buffer circuit (3) and the input impedance of each circuit section in the camera (B) except for the impedance section (14) connected to the line (e) are very high, and the input impedance of the transmission path (La) is high. The impedance of the input terminal (ei) for the viewed video signal, that is, the input impedance Zei of the input terminal (ei) is determined substantially by the impedance between the line (le) of the impedance section (14) and the ground.

Then, the impedance Za of the resistance (Ra) and the resistance (R
b), the parallel combined impedance Zbc of (Rc) is Zbc≫Z
When the transistor (Q) is turned on, the input impedance Zei becomes Za, that is, a characteristic impedance of 75Ω, and when the transistor (Q) is turned off, the input impedance Zei becomes Zbc, that is, the characteristic impedance. The impedance becomes large enough.

On the other hand, the camera (M1) in which the input terminal (vi) is connected to the transmission line (La) has the input impedance Zv of the input terminal (vi).
i is a resistor (R) provided between the input terminal (vi) and ground.
i) is determined by the impedance Zi, and the impedance Zi is usually set to a characteristic impedance of 75Ω.

Then, a camera (B) and a television (M1) are placed on the transmission line (La).
Is connected, the transmission line (La) is terminated in parallel with the input impedance Zei of the input terminal (ei) and the input impedance Zvi of the input terminal (vi), and both input impedances Zei and Zvi are both 75Ω. With the characteristic impedance of, the terminal impedance of the transmission line (La) decreases from the matching impedance of 75Ω, and the video signals at the input terminals (ei) and (vi) greatly decrease from the voltage of the rated level. In particular, due to the drop in the level of the video signal at the input terminal (ei), a proper level of synchronization signal cannot be obtained from the video signal at the input terminal (ei), and a normal video signal is output from the camera (B). Disappears.

Also, when both input impedances Zei and Zvi become high impedance like impedance Zbc, or input impedance Zei becomes high impedance even though only camera (B) is connected to transmission line (La). , The terminal impedance of the transmission line (La) increases from the matching impedance and the input terminal (e
The voltage of the video signal i) rises above, and a so-called excessive input state occurs, so that an appropriate level of synchronization signal cannot be obtained, and a normal video signal cannot be output from the camera (B).

Therefore, based on the divided voltages of the resistors (R1) to (R3), voltages A and B corresponding to the voltage of the detection signal D in each of the over-input state and the under-input state are set in the comparison unit (12). Then, the voltage A is input to the inverting input terminal (-) of the comparator (12a), and the voltage B is input to the non-inverting input terminal (+) of the comparator (12b).

Therefore, the comparator (12a) detects whether the detection signal D is higher than the voltage A, and the comparator (12b) detects whether the detection signal D is lower than the voltage B. According to (12), based on the comparison between the voltages A and B and the voltage of the detection signal D, a decrease or a rise from the reference level of the detection signal D, that is, the level of the detection signal D when the video signal is at the rated level is detected. You.

When the detection signal D falls below the voltage B, the flip-flop (13) is set by the rise of the output signal of the comparator (12b). Conversely, when the detection signal D rises above the voltage A, the comparison is made. The flip-flop (13) is reset by the rise of the output signal of the switch (12a).

By the way, when the flip-flop (13) is reset, the output signal of the Q output terminal (q) goes low, and when set, the output signal of the Q output terminal (q) goes high.

Then, the Q output terminal (q) of the flip-flop (13)
When the output signal goes low, the inverter (14a)
Becomes high level, the transistor (Q) turns on and the input impedance Zei becomes characteristic impedance. Conversely, when the Q output signal of the flip-flop (13) becomes high level, the output of the inverter (14a) becomes The signal goes low, the transistor (Q) turns off, and the input impedance Zei goes high.

By the way, since the input terminal of the inverter (14a) is pulled down by the resistor (R4), immediately after the power supply of the camera (B) is turned on, the output signal of the inverter (14a) becomes low level immediately and the transistor ( Q) turns on,
The input impedance Zei unconditionally becomes a characteristic impedance based on the impedance Za.

If the input terminal (ei) is in an open state without being connected to the transmission line (La), the flip-flop (13)
Is not performed, the output signal of the Q output terminal (q) of the flip-flop (13) is held at a low level, and the transistor (Q) is held on.

On the other hand, if the input terminal (ei) is connected to the transmission line (La) with the transistor (Q) turned on, the detection signal D becomes equal to or lower than the voltage B at this time, so that the output signal of the comparator (12b) is output. Rises to the high level, the flip-flop (13) is set, the output signal of the output terminal (q) goes to the high level, the output signal of the inverter (14a) goes to the low level, and the transistor (Q) turns off. Input impedance
Zei automatically switches to high impedance.

Therefore, the terminal impedance of the transmission line (La) is almost matched to the input impedance Zvi of the television (M1), and the video signals of the input terminals (ei) and (vi) rise to the rated level.

By the way, when the video signal of the input terminal (ei) reaches the rated level, the output signal of the comparator (12b) is inverted from the high level to the low level, but the flip-flop (13) is kept set and the transistor (Q) is turned off, and the input impedance Zei is maintained at a high impedance.

Then, the state in which the input impedance Zei is maintained at the high impedance is, for example, when the television (M1) is disconnected from the transmission line (La), or when the resistance (Ri) is switched to the high impedance, the input impedance Zvi is reduced. The impedance is switched to high impedance, and the video signal at the input terminal (ei) rises from the rated level due to the mismatch of the terminal impedance of the transmission line (La), and continues until the detection signal D becomes equal to or higher than the voltage A.

That is, when the voltage of the video signal at the input terminal (ei) rises and the detection signal D fluctuates beyond the voltage A, the comparator (12)
The output signal of a) is inverted to the high level, the flip-flop (13) is reset, the output signal of the output terminal (q) is inverted from the high level to the low level, the transistor (Q) turns on, and the input impedance Zei Automatically switches from high impedance to characteristic impedance.

Then, since the input impedance Zei switches to the characteristic impedance, the transmission line (La) becomes the input impedance.
Zei is matched and terminated, and the video signal at the input terminal (ei) becomes the rated level.

When the video signal at the input terminal (ei) reaches the rated level, the output signal of the comparator (12a) goes low,
The flip-flop (13) is held in a reset state, the transistor (Q) turns on and the input impedance
Zei is held at the characteristic impedance.

Therefore, in the case of FIG. 1, the horizontal synchronization level of the video signal at the input terminal (ei) is changed from the reference level to the voltage B by the input impedance adjustment circuit having a simple electronic circuit configuration provided in the camera (B). If the horizontal impedance level of the video signal at the input terminal (ei) rises from the reference level to the voltage A, the input impedance Zei is switched from the characteristic impedance to the high impedance based on the turning off of the transistor (Q). When the transistor (Q) is turned on, the input impedance Zei is automatically switched from the high impedance to the characteristic impedance, and the input impedance Zei is automatically switched so that the video signal of the input terminal (ei) is maintained at the rated level. .

Therefore, even when other video equipment such as a television (M1) is connected to the transmission path (La) together with the camera (B), the distributor (VD) is not provided on the transmission path (La), and
Without providing a large mechanical switch on the camera (B),
Input impedance Ze according to the termination state of the transmission line (La)
i can be selectively switched between characteristic impedance and high impedance, and the video signal at the input terminal (ei) can always be controlled to the rated level, and the number of components in the monitoring system does not increase, simplifying the system. Since the size of the camera (B) can be reduced and the external design is not impaired, and the input impedance Zei is automatically and appropriately switched, for example, the camera (B)
There is no need to measure the input impedance Zei at the time of installation, and handling becomes extremely easy.

In the above embodiment, the present invention is applied to the camera (B) provided in the surveillance system. However, a television camera having an external synchronization input terminal of various video systems other than the surveillance system,
Of course, it can be applied to video equipment having various external synchronization input terminals other than the television camera.

In the above-described embodiment, the input impedance Zei is switched by detecting the horizontal synchronization level. However, the input impedance Zei may be switched by detecting the vertical synchronization level.

Further, in the above embodiment, the transistor (Q) is used as the semiconductor switch to connect and disconnect the resistor (Ra) to the line (e) to switch the input impedance Zei. However, for example, an analog switch may be used as the semiconductor switch. Alternatively, for example, the connection between the resistor (Ra) and the connection point of the resistors (Rb) and (Rc) may be switched to the line (le) and connected.

〔The invention's effect〕

As described above, according to the input impedance adjustment circuit of the present invention, the termination of the transmission line connected to the external synchronization input terminal is performed by the switching of the semiconductor switch based on the detection of the synchronization level of the video signal input to the external synchronization input terminal. According to the impedance matching state, the input impedance of the external synchronization input terminal is changed to the characteristic impedance of the transmission line,
By selectively switching to high impedance, the input impedance of the external synchronization input terminal is automatically switched so that the terminal impedance of the transmission line becomes the matching impedance, and the video signal of the external synchronization input terminal is transmitted to the transmission line. It can be controlled to the rated level at the time of matching. For example, when applied to a television camera having an external synchronization input terminal of a monitoring system, the transmission line end can be provided without providing a matching distributor in the middle of the transmission line. Impedance mismatch is prevented, and there is no need to provide a large mechanical switch for manually switching the input impedance of the external synchronization input terminal to the TV camera. This simplifies the system and reduces the size of the camera. In addition, the camera can be easily handled.

[Brief description of the drawings]

FIG. 1 is a block diagram of an embodiment of an input impedance adjusting circuit according to the present invention, and FIGS. 2 and 3 are block diagrams of a conventional monitoring system. (1): Synchronization level detection unit, (2): Impedance switching unit, (La): Transmission line, (ei): External synchronization input terminal.

Claims (1)

(57) [Claims] An external synchronization input terminal connected to a video signal transmission line; a synchronization level detection unit for detecting a synchronization level of the video signal at the input terminal and outputting a detection signal of the synchronization level; An impedance switching unit for switching the input impedance of the input terminal from a characteristic impedance of the transmission line to a high impedance sufficiently larger than the characteristic impedance by a switching of a semiconductor switch based on a decrease and a rise of the signal from a reference level, and vice versa. An input impedance adjustment circuit characterized in that: