KR101289619B1 - Allocation device by sensing loop voltage of video signal of videophone - Google Patents

Abstract

PURPOSE: An image distribution device through loop voltage detection of an image signal line of a video phone is provided to simplify a circuit configuration in distributing of an image signal using a common wire between common entrance camera terminal and household terminal and to improve image quality. CONSTITUTION: Each of loop voltage detection units (300a,300b) output a detection signal by detecting current or voltage with respect to an image signal line flowing through each impedance matching resistor of household terminals (200a,200b). Each of master relay control units (400a,400b) receives the detection signal outputted from each of the loop voltage detection units. The each of the master relay control units controls each of relays to connect the image signal line to the each of the household terminals. [Reference numerals] (AA) Household terminal 1; (BB) Common entrance camera; (CC) Household terminal 2

Description

Allocation device by sensing loop voltage of video signal of videophone

The present invention relates to an apparatus for distributing an image by detecting a loop voltage of a video signal line of a video phone for a call generation with respect to a multi-family door camera attached to a front door of a multi-family house, and more particularly, to a front door of a multi-family house. Analysis of data receiving circuit and data without reducing signal level or ghosting in distributing the image between common door camera and generation device by using attached common door camera and common wiring connecting each generation And video distribution device through loop voltage detection of video signal line of video phone, which can reduce the manufacturing cost by simplifying circuit configuration by not requiring a control device for control and amplification of video signal. It is about.

In the case of a multi-family home where multiple households, such as an apartment or villa, use a single public door, a common terminal is used to reduce costs between the terminal of the camera of a common house door attached to the apartment door and the terminal between generations of each household. Wiring is commonly used. At this time, the wiring required between the common door camera terminal and the generation unit of each generation requires a data signal line, an audio signal line, and an image signal line. Data signal line and audio signal line can usually be used from several tens of meters to hundreds of meters. However, video signal lines have not only a kind of cable recommended by the product manufacturer but also a limitation of the use distance due to the characteristics of the signal. In addition, since the video signal line is commonly connected to all generations, the signal level decreases or the ghost phenomenon occurs and the image quality is degraded. Therefore, 1: 1 connection is common between the common door camera terminal and the generation terminal.

If there are several generations on one floor, a device is needed to connect the video wires of the common door camera terminal and the generation terminal, or to distribute the video signal of the common door on each floor. In this case, if the video distribution device is used on each floor, when the generation terminal is called from the common door camera terminal, the video signal can be connected to the generation unit because it needs to know how many generations of the floor have been called. There is a need for a control circuit for and a circuit for amplifying or distributing the video signal.

The distribution of the image signal by this method requires a data receiving circuit, a control circuit including a CPU for data analysis and control, and an image distribution circuit, which causes complexity of the circuit and inconvenient maintenance.

Therefore, by using a common wiring between the common door camera terminal and the generation unit terminal, by distributing the video signal with a simple circuit configuration, the image distribution apparatus can improve not only the image quality but also the efficiency of maintenance. Development is needed.

Accordingly, an object of the present invention is to provide a video signal line of a video phone that can simplify the circuit configuration and improve image quality at the time of distributing the video signal by using common wiring between the common door camera terminal and the generation terminal. It is to provide an image distribution device through loop voltage sensing.

In addition, another object of the present invention is to reduce the manufacturing cost and maintain the distribution of the video signal distribution device in the distribution of the video signal using a common wiring between the common door camera terminal and the generation unit terminal It is to provide a video distribution device through loop voltage detection of the video signal line of the video phone that can reduce the maintenance cost by simplifying the.

According to the present invention, the common door camera terminal 100 and the common door camera terminal for receiving the call signal Sc (Sca, Scb) for the generation terminal and outputting the video signal Sv through the video signal line SL And relays 210a and 210b for relaying the connection of the image impedance matching resistors Rma and Rmb to the video signal line SL in response to the call signals Sc, Sca and Scb output from the 100. Detects the current or voltage of the video signal line SL flowing through the image impedance matching resistors Rma and Rmb of the generation terminals 200a and 200b and the generation terminals 200a and 200b to detect the detected signal Ss. The loop voltage sensing units 300a and 300b for outputting Ssa and Ssb, and the sensing signals Ss Ssa and Ssb output from the loop voltage sensing units 300a and 300b and receive call signals Sc and Sca. Video signal lines SL; SL1, SL2 The video distribution across the relay loop voltage sense of the videophone video signal line constituted by the master relay control section (400a, 400b) for connecting, by (410a, 410b) is provided.

According to the present invention, since the loop voltage sensing unit senses a common wiring connected to the called generation terminal by using the image impedance matching resistor of the generation terminal, a CPU and a circuit for separate data reception, analysis and control are not required. The configuration of the circuit can be simplified. In addition, even if multiple generation terminals are connected, the video signal line can be selectively connected to the common door camera terminal only 1: 1 to the called generation terminal, thereby preventing signal loss and ghosting of the image signal. In addition, since there is no need to use an image amplifying circuit, energy loss can be prevented.

1 is a circuit diagram of an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a first exemplary embodiment of the present invention.
2 is a circuit diagram of an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a second exemplary embodiment of the present invention.

Hereinafter, an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a first exemplary embodiment of the present invention.

In FIG. 1, for example, two generation terminals 200a and 200b are illustrated, and thus, two loop voltage sensing units 300a and 300b respectively corresponding to generation terminals 200a and 200b are illustrated. However, when the generation unit is extended to several generations, the loop voltage detection unit also increases in proportion to the number of generation terminals, and it can be understood that individual wirings are further connected to the common line for each generation unit. Will be omitted.

As shown in FIG. 1, the video distribution device through loop voltage sensing of a video signal line of a video phone according to a first exemplary embodiment of the present invention receives a generation call signal Sc and receives a video signal Sv. The resistance for image impedance matching with respect to the image signal line SL according to the common door camera terminal 100 for output through the image signal line SL and the call signal Sc output from the common door camera terminal 100. Video signal lines through generation terminals 200a and 200b having relays 210a and 210b for relaying connections of Rma and Rmb, and resistors Rma and Rmb for image impedance matching of generation terminals 200a and 200b. The loop voltage detectors 300a and 300b for sensing the current for the SL and outputting the detected signals Ssa and Ssb, and the sensed signal Ss output from the loop voltage detectors 300a and 300b. Received the call signal (Sc) A video signal line (SL) to the terminal (200a, 200b) comprises a master relay (410a, 410b) the master relay control section (400a, 400b) for connecting by.

The common door camera terminal 100 is attached to the common entrance and input unit (not shown) for calling the generation terminals 200a and 200b to the generation terminals 200a and 200b, and the input terminals of the generation terminals 200a and 200b. When a call is input, a call signal generator (not shown) for generating a call signal Sc, a camera module (not shown) for generating a visitor's video signal Sv, and a call signal Sc and a video signal And a data transmitter (not shown) for transmitting the SV. At this time, in the common door camera terminal 100, when the call signal Sc is generated, the image signal Sv is output to the image signal line SL of the common line LINE provided outside the common door camera terminal 100. It is desirable to have a relay 110 to ensure that.

The generation terminals 200a and 200b are made up of the required number of generations, and in the first embodiment, two generation terminals 200a and 200b will be described by exemplifying two generations.

The generation terminals 200a and 200b are grounded at one end and include resistors Rma and Rmb for impedance matching of the image signal Sv, and are common according to the call signal Sc output from the common door camera terminal 100. Relays 210a and 210b are provided to relay the connection of the image impedance matching resistors Rma and Rmb to the video signal line SL of the wiring LINE.

In the relays 210a and 210b of the generation terminals 200a and 200b, the call signal Sc is not input from the common door camera terminal 100 or the call signals Sca and Scb of the corresponding generation terminals 200a and 200b are input. If not, the impedance matching resistors Rma and Rmb of the corresponding generation terminals 200a and 200b are disconnected from the video signal line SL of the common line and the corresponding generation terminals 200a and 200b are disconnected. When the call signals Sca and Scb are inputted, the other ends of the impedance matching resistors Rma and Rmb of the corresponding generation terminals 200a and 200b are connected to the video signal line SL of the common line. Relay.

For example, when a call to the first generation terminal 200a is input to the input unit of the common door camera terminal 100, the relay 110 of the common door camera terminal 100 is operated to connect the image signal Sv to common wiring. While being connected to the line, only the first relay 210a of the first generation terminal 200a is operated so that only the first image impedance matching resistor Rma is connected to the image signal line SL of the common line. The second relay 210b of the second generation terminal 200b does not operate, and the resistance Rmb of the second image impedance matching of the second generation terminal 200b is connected to the common line. The connection is disconnected with respect to the video signal line SL. In the first exemplary embodiment, only two generation terminals 200a and 200b are illustrated, but when there are a plurality of other generation terminals, the remaining generation terminals all have a video signal line having a common impedance matching resistor. The connection is disconnected with respect to SL.

Each of the loop voltage detectors 300a and 300b detects a current or voltage of the image signal line SL, which is mediated through the respective image impedance matching resistors Rma and Rmb of the respective generation terminals 200a and 200b. In order to output the respective detection signals (Ssa, Ssb) for this is provided in proportion to the number of generation terminals (200a, 200b). In the first exemplary embodiment, two generation terminals 200a and 200b are illustrated, and correspondingly, two first and second loop voltage sensing units 300a and 300b are illustrated.

One end of the first loop voltage detector 300a for sensing a current or voltage of the image signal line SL, which has mediated the first image impedance matching resistor Rma of the first generation terminal 200a, The zener diode ZD1 and the resistor (D) are connected to the contacts of the distribution resistors R4 and R5 and the distribution resistors R4 and R5 connected to Vc and connected to the video signal line SL of the common line LINE. For outputting a sensing signal Ssa consisting of a high signal H and a low signal L outputted from a collector of transistor Q2 and a transistor Q2 having a base connected and an emitter grounded through R3). The resistor R2 is connected between the first output terminal LINE_1 and the power supply Vc and the collector of the transistor Q2.

Similarly, one end of the second loop voltage detector 300b for sensing a current or voltage of the image signal line SL, which is mediated by the second image impedance matching resistor Rmb of the second generation terminal 200b, may be provided. The zener diode ZD2 is connected to the contacts of the distribution resistors R10 and R11 and the distribution resistors R10 and R11 which are connected to the power supply Vc and whose other ends are connected to the video signal line SL of the common wiring LINE. Outputs a sensing signal Ssb consisting of a high signal H and a low signal L output from a collector of transistor Q4 and a transistor Q4 having a base connected and resistor grounded via a resistor R9. The second output terminal LINE_2, and a resistor R8 connected between the power supply Vc and the collector of the transistor Q4.

The master relay controllers 400a and 400b are connected to the output terminals LINE_1 and LINE_2 of the loop voltage detectors 300a and 300b, respectively, to provide respective detection signals Ssa and Ssb from the loop voltage detectors 300a and 300b. In response to the input, the video signal line SL of the common line LINE is controlled to the corresponding generation terminals 200a and 200b. In the first exemplary embodiment, two generation terminals 200a and 200b are illustrated, and thus, two loop voltage sensing units 300a and 300b are illustrated, respectively, and are connected to the loop voltage sensing units 300a and 300b. Two master relay controllers 400a and 400b, that is, first and second master relay controllers 400a and 400b are illustrated. Therefore, when there are a plurality of generation terminals, a plurality of master relay controllers are required.

The first master relay controller 400a has a base connected to the collector of the transistor Q2, which is the emitter grounded and the first output terminal LINE_1 of the first loop voltage detector 300a, through the base resistor R1. The first relay 410a is connected in parallel with the diode D1 reverse biased with respect to the power supply Vc between the collector of the transistor Q1 and the power supply Vc. At this time, the first switching terminal 412a of the first relay 410a of the first master relay controller 400a is operated when the transistor Q1 is operated, that is, the first output terminal LINE_1 of the first loop voltage detector 300a. ), When the output value of H is high (H), the first relay 410a is activated to turn off the image signal lines SL (SL1 and SL2) of the common line (LINE) connected to the common door camera terminal (100). When the transistor Q1 is inoperative, when the output value of the first output terminal LINE_1 of the first loop voltage sensing unit 300a is low, the first relay 410a is deactivated and The image signal lines SL SL1 and SL2 of the common line LINE connected to the door camera terminal 100 are turned off.

Similarly, the second master relay controller 400b may have a base connected to the collector of the transistor Q4, which is the emitter grounded and the second output terminal LINE_2 of the first loop voltage detector 300b, through the base resistor R7. A second relay 410b connected in parallel with the diode D2 reverse biased with respect to the power supply Vc between the collector of the connected transistor Q3 and the power supply Vc. At this time, the second switching terminal 412b of the second relay 410b of the second master relay controller 400b is operated when the transistor Q3 is operated, that is, the second output terminal LINE_2 of the second loop voltage detector 300b. ), When the output value of H is high (H), the second relay 410b is activated to turn off the image signal lines SL SL1 and SL2 of the common line LINE connected to the common door camera terminal 100, respectively. When the transistor Q3 is not in operation and the output value of the second output terminal LINE_2 of the second loop voltage detector 300b is low, the second relay 410b is deactivated and The image signal lines SL SL1 and SL2 of the common line LINE connected to the door camera terminal 100 are turned off.

An operation of the video distribution apparatus by detecting the loop voltage of the video signal line of the video phone according to the first embodiment of the present invention will be described.

In the description of the operation, the case where the call signal Sc (Sca) for the first generation terminal 200a is input to the input unit of the common door camera terminal 100 will be taken as an example.

When the call signal Sc (Sca) for the first generation terminal 200a is input to the input unit of the common door camera terminal 100 to output an image signal Sv generated by the common door camera terminal 100. The relay 110 of the common door camera terminal 100 is operated to relay the connection to the video signal line SL of the common line, and at the same time, the first generation terminal 200a includes the corresponding generation terminal 200a. The call signal Sca of is inputted through the data line DL, and the first relay 210a is operated by the input call signal Sca and the grounded first image impedance matching resistor Rma is connected to the video signal line. (SL) is connected.

Thereafter, the first output terminal LINE_1 of the first loop voltage detector 300a, which outputs the low L signal due to the operation of the transistor Q2, is turned on by the first loop voltage detector 300a. Is not operated, and the voltage of the power supply Vc outputs the high H signal through the resistor R2.

As the high Q signal is output from the first output terminal LINE_1 of the first loop voltage detecting unit 300a, the transistor Q1 is operated so that the first relay 410a of the first master relay control unit 400a is operated. On-off switching of the image signal lines SL SL1 and SL2 of the common line LINE connected to the common door camera terminal 100 is performed.

Accordingly, the video signal Sv is input from the common door camera terminal 100 to the corresponding first generation terminal 200a to which the call signal Sca is input through the common line LINE.

Thereafter, when the call between the common door camera terminal 100 and the first generation terminal 200a ends or a predetermined waiting time elapses, the output of the video signal Sv from the common door camera terminal 100 ends. The relay 110 of the door camera terminal 100 switches to the output standby state of the image signal Sv and at the same time, the first relay of the first generation terminal 200a through the data line DL of the common line LINE. 210a causes the image signal line SL to be disconnected from the first image impedance matching resistor Rma.

Accordingly, the first output terminal LINE_1 of the first loop voltage detection unit 300a outputs a low L signal, and the transistor Q1 of the first master relay controller 400a is output by the low L output signal. ) Is not operated so that the first relay 410a is deactivated to switch off the image signal lines SL SL1 and SL2 of the common line LINE connected to the common door camera terminal 100, respectively.

2 is a circuit diagram of an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a second exemplary embodiment of the present invention.

In the video distribution apparatus through loop voltage sensing of the video signal line of the video phone according to the second embodiment of the present invention, the same configuration as that of the first embodiment is denoted by the same reference numerals, and a description thereof will be omitted.

According to the video distribution apparatus through loop voltage sensing of the video signal line of the video phone according to the second embodiment of the present invention, when there are a plurality of generation terminals 200a and 200b located on the same floor, The process of performing the communication of the video signal Sv between the generation terminals 200a and 200b and the common door camera terminal 100 by the first master relay controller 400a for the floor is the same as that of the first embodiment. The distribution of the video signal Sv for each layer is different from the first embodiment in that it is performed by the slave relay controller 500.

According to an image distribution apparatus through loop voltage sensing of an image signal line of a video phone according to a second exemplary embodiment of the present invention, the apparatus further includes a slave relay controller 500 for distributing an image signal Sv for each layer. do.

The slave relay controller 500 has a second loop voltage detector connected to the diode D7 with respect to the first output terminal LINE_1 of the first loop voltage detector 300a connected to the diode D6 with the emitter grounded. In the state where the second output terminal LINE_2 of 300b is connected in parallel, the power supply Vc is connected between the transistor Q9 having a base connected via the resistor R28 and the collector of the transistor Q9 and the power supply Vc. A relay 510 is connected in parallel with the reverse biased diode D5.

Here, when the output value of the first output terminal LINE_1 of the first loop voltage detector 300a or the second output terminal LINE_2 of the second loop voltage detector 300b is high (H), the transistor Q9 is turned on. As the relay 510 is operated to operate, the switching terminal 512 of the relay 510 of the slave relay controller 500 outputs an image signal Sv to another layer OUT. Is switched off and the video signal line SL for outputting the video signal Sv to the corresponding generation terminals 200a and 200b is switched on.

As described above, according to the present invention, since the loop voltage sensing unit senses the common wire to which the called generation terminal is called by using the image impedance matching resistor of the generation terminal, a CPU and a circuit for separate data reception, analysis and control. Can be eliminated and the configuration of the circuit can be simplified. In addition, even if multiple generation terminals are connected, the video signal line can be selectively connected to the common door camera terminal only 1: 1 to the called generation terminal, thereby preventing signal loss and ghosting of the image signal. In addition, since there is no need to use an image amplifying circuit, energy loss can be prevented.

100: shared door camera terminal
110: relay
200a: first generation terminal
210a: a first relay of a first generation terminal
200b: second generation terminal
210b: second relay of a second generation terminal
300a: first loop voltage detector
300b: second loop voltage detection unit
400a: first master relay control unit
410a: a first relay of the first master relay controller
412a: a first switching terminal of the first relay of the first master relay controller
400b: second master relay control unit
410b: second relay of the second master relay controller
412b: second switching terminal of a second relay of the second master relay controller
500: slave relay control unit
510: relay of the slave relay controller
512: switching terminal of the relay of the slave relay control unit
DL: Data line
LINE: Common Wiring
LINE_1: First output
LINE_2: 2nd output
Rma: resistor for first image impedance matching
Rmb: resistor for matching second image impedance
Sc, Sca, Scb: Call Signal
SL, SL1, SL2: Video signal line
Sv: video signal
Vc: power

Claims (18)

delete delete A common door camera terminal 100 for receiving a call signal Sc (Sca, Scb) for the generation terminal and outputting the image signal Sv through the image signal line SL;
A relay 210a for relaying the connection of the image impedance matching resistors Rma and Rmb to the image signal line SL in response to the call signals Sc; Sca and Scb output from the common door camera terminal 100; Generation terminals 200a and 200b having 210b);
For detecting the current or voltage of the video signal line SL flowing through the image impedance matching resistors Rma and Rmb of the generation terminals 200a and 200b and outputting the detection signals Ss and Ssb corresponding thereto. Loop voltage detection units 300a and 300b; And
The image signal line SL to the generation terminals 200a and 200b that receive the detection signals Ss Ssa and Ssb output from the loop voltage detectors 300a and 300b and receive the call signals Sc and Sca and Scb; Master relay control unit (400a, 400b) for connecting the SL1, SL2 by the relay (410a, 410b),
The common door camera terminal 100 is attached to the common entrance and input unit (not shown) for calling the generation terminals 200a and 200b to the generation terminals 200a and 200b, and the input terminals of the generation terminals 200a and 200b. When a call is input, a call signal generator (not shown) for generating call signals Sc (Sca, Scb), a camera module (not shown) for generating a visitor's video signal Sv, and a call signal Sc A data transmitter (not shown) for transmitting Sca and Scb and an image signal Sv,
The common door camera terminal 100 converts the video signal Sv into a video signal line SL of a common line provided outside the common door camera terminal 100 when the call signals Sc, Sca and Scb are generated. It is provided with a relay 110 for outputting,
The generation terminals 200a and 200b are grounded at one end and include resistances Rma and Rmb for impedance matching of the image signal Sv, and call signals Sc output from the common door camera terminal 100 are Sca and Scb. And relays 210a and 210b for relaying the connection of the image impedance matching resistors Rma and Rmb to the video signal lines SL SL1 and SL2 of the common wiring LINE.
The relays 210a and 210b of the generation terminals 200a and 200b may be configured to generate the corresponding generation terminals when the call signals Sc, Sca and Scb of the generation terminals 200a and 200b are not input from the common door camera terminal 100. The impedance matching resistors Rma and Rmb of the 200a and 200b are disconnected from the video signal line SL of the common line LINE, and the call signals Sc and Sca of the corresponding generation terminals 200a and 200b are disconnected. And the other end of the impedance matching resistors Rma and Rmb of the corresponding generation terminals 200a and 200b to the video signal line SL of the common line when the Scb is input. An image distribution device through loop voltage sensing of an image signal line of a video phone. A common door camera terminal 100 for receiving a call signal Sc (Sca, Scb) for the generation terminal and outputting the image signal Sv through the image signal line SL;
A relay 210a for relaying the connection of the image impedance matching resistors Rma and Rmb to the image signal line SL in response to the call signals Sc; Sca and Scb output from the common door camera terminal 100; Generation terminals 200a and 200b having 210b);
For detecting the current or voltage of the video signal line SL flowing through the image impedance matching resistors Rma and Rmb of the generation terminals 200a and 200b and outputting the detection signals Ss and Ssb corresponding thereto. Loop voltage detection units 300a and 300b; And
The image signal line SL to the generation terminals 200a and 200b that receive the detection signals Ss Ssa and Ssb output from the loop voltage detectors 300a and 300b and receive the call signals Sc and Sca and Scb; Master relay control unit (400a, 400b) for connecting the SL1, SL2 by the relay (410a, 410b),
Generation terminal (200a, 200b) is composed of a plurality,
The generation terminals 200a and 200b are grounded at one end and include resistances Rma and Rmb for impedance matching of the image signal Sv, and call signals Sc output from the common door camera terminal 100 are Sca and Scb. And relays 210a and 210b for relaying the connection of the image impedance matching resistors Rma and Rmb to the video signal lines SL SL1 and SL2 of the common wiring LINE.
The relays 210a and 210b of the generation terminals 200a and 200b may be configured to generate the corresponding generation terminals when the call signals Sc, Sca and Scb of the generation terminals 200a and 200b are not input from the common door camera terminal 100. The impedance matching resistors Rma and Rmb of the 200a and 200b are disconnected from the video signal line SL of the common line LINE, and the call signals Sc and Sca of the corresponding generation terminals 200a and 200b are disconnected. And the other end of the impedance matching resistors Rma and Rmb of the corresponding generation terminals 200a and 200b to the video signal line SL of the common line when the Scb is input. An image distribution device by detecting a loop voltage of an image signal line of a video phone. delete delete The video signal line of claim 3 or 4, wherein the loop voltage detectors 300a and 300b use an image signal line (mediated through the respective image impedance matching resistors Rma and Rmb) of the corresponding generation terminals 200a and 200b. A loop of the video signal line of a video phone, characterized in that it is provided in proportion to the number of generation terminals 200a and 200b for sensing current or voltage for SL and outputting the respective sensing signals Ssa and Ssb. Video distribution device with voltage sensing. The method of claim 7, wherein the generation terminal (200a, 200b) is composed of a pair of first and second generation terminals (200a, 200b), the loop voltage detector (300a, 300b) is a pair of first and second A pair of first and second loop voltage detectors 300a and 300b corresponding to the second generation terminals 200a and 200b, respectively.
The first loop voltage detector 300a detects a current or voltage of the image signal line SL, which is mediated by the first image impedance matching resistor Rma of the first generation terminal 200a.
The second loop voltage detector 300b detects a current or voltage of the image signal line SL, which is mediated by the second image impedance matching resistor Rmb of the second generation terminal 200b. Video distribution device through loop voltage detection of video signal line of phone. 9. The distribution loop of claim 8, wherein one end of the first loop voltage detector 300a is connected to the power supply Vc and the other end thereof is connected to the image signal line SL of the common line. And a high signal output from the collectors of transistors Q2 and Q2 having an emitter grounded with a base connected to the contacts of the distribution resistors R4 and R5 via a zener diode ZD1 and a resistor R3. A first output terminal LINE_1 for outputting a sensing signal Ssa consisting of H and a low signal L, and a resistor R2 connected between the power supply Vc and the collector of the transistor Q2. An image distribution device through loop voltage sensing of an image signal line of a video phone. 10. The distribution resistors R10 and R11 of claim 9, wherein one end of the second loop voltage detector 300b is connected to the power supply Vc and the other end thereof is connected to the image signal line SL of the common line. And a high signal output from the collectors of transistors Q4 and Q4 having an emitter grounded with a base connected to the contacts of the distribution resistors R10 and R11 via a zener diode ZD2 and a resistor R9. A second output terminal LINE_2 for outputting a sensing signal Ssb consisting of H and a low signal L, and a resistor R8 connected between the power supply Vc and the collector of the transistor Q4. An image distribution device through loop voltage sensing of an image signal line of a video phone. The master relay controller 400a or 400b is connected to the first and second output terminals LINE_1 and LINE_2 of the pair of first and second loop voltage detectors 300a and 300b, respectively. Comprising a pair of first and second master relay control unit (400a, 400b), a common wiring line by receiving each detection signal (Ss; Ssa, Ssb) from a pair of loop voltage detector (300a, 300b) To control the connection of the video signal line SL of the video signal line SL to the corresponding first generation terminal 200a or the second generation terminal 200b. . 12. The first master relay controller 400a of claim 11, wherein the first master relay controller 400a has a base resistor R1 with respect to the collector of the transistor Q2 that is the emitter grounded and is the first output terminal LINE_1 of the first loop voltage detector 300a. A video phone comprising a first relay 410a connected in parallel with a diode D1 reversely biased with respect to the power supply Vc between the collector of the transistor Q1 to which the base is connected and the power supply Vc. Image distribution device through the detection of loop voltage of the video signal line. The first switching terminal 412a of the first relay 410a of the first master relay controller 400a has a low output value at the first output terminal LINE_1 of the first loop voltage detector 300a. When it changes from (L) to high (H), the first relay 410a is activated to turn off the image signal lines SL (SL1, SL2) of the common line (LINE) connected with the common door camera terminal (100). When the output value of the first output terminal LINE_1 of the first loop voltage detector 300a changes from high (H) to low (L), the first relay 410a is deactivated to switch on the common door camera. And an off-switching of the video signal lines SL (SL1, SL2) of the common line (LINE) connected to the terminal (100). 12. The base resistor R7 of claim 11, wherein the second master relay controller 400b has an emitter grounded and a collector of the transistor Q4 that is the second output terminal LINE_2 of the second loop voltage detector 300b. And a second relay 410b connected in parallel with the diode D2 reverse biased with respect to the power supply Vc between the collector of the transistor Q3 connected to the base and the power supply Vc. Image distribution device through the detection of loop voltage of the video signal line. The second switching terminal 412b of the second relay 410b of the second master relay controller 400b has a low output value at the second output terminal LINE_2 of the second loop voltage detector 300b. When it changes from (L) to high (H), the second relay 410b is activated to turn off the image signal lines SL (SL1, SL2) of the common line (LINE) connected with the common door camera terminal (100). When the output value of the second output terminal LINE_2 of the second loop voltage detecting unit 300b changes from high (H) to low (L), the second relay 410b is deactivated to switch on the common door camera. And an off-switching of the video signal lines SL (SL1, SL2) of the common line (LINE) connected to the terminal (100). delete A common door camera terminal 100 for receiving a call signal Sc (Sca, Scb) for the generation terminal and outputting the image signal Sv through the image signal line SL;
A relay 210a for relaying the connection of the image impedance matching resistors Rma and Rmb to the image signal line SL in response to the call signals Sc; Sca and Scb output from the common door camera terminal 100; Generation terminals 200a and 200b having 210b);
For detecting the current or voltage of the video signal line SL flowing through the image impedance matching resistors Rma and Rmb of the generation terminals 200a and 200b and outputting the detection signals Ss and Ssb corresponding thereto. Loop voltage detection units 300a and 300b; And
The image signal line SL to the generation terminals 200a and 200b that receive the detection signals Ss Ssa and Ssb output from the loop voltage detectors 300a and 300b and receive the call signals Sc and Sca and Scb; Master relay control unit (400a, 400b) for connecting the SL1, SL2 by the relay (410a, 410b),
The generation terminals 200a and 200b are divided into a plurality of groups, and further include a slave relay controller 500 for distributing the image signal Sv for each group, wherein the slave relay controller 500 has an emitter grounded. The second output terminal LINE_2 of the second loop voltage sensing unit 300b connected to the diode D7 is connected to the first output terminal LINE_1 of the first loop voltage sensing unit 300a connected to the diode D6. A transistor Q9 having a base connected via a resistor R28 in a connected state in parallel, a diode D5 reverse biased with respect to the power supply Vc between the collector of the transistor Q9 and the power supply Vc; An image distribution apparatus through loop voltage sensing of an image signal line of a video phone, characterized in that the relay is connected in parallel. The transistor of claim 17, wherein when the output value of the first output terminal LINE_1 of the first loop voltage detection unit 300a or the second output terminal LINE_2 of the second loop voltage detection unit 300b is high (H), As the Q9 is operated and the relay 510 is operated, the switching terminal 512 of the relay 510 of the slave relay controller 500 receives the generation signals 200a, Sc and Scb. Video signal for switching off the video signal line SL 'outputting the video signal Sv to the group OUT different from the group of 200b) and outputting the video signal Sv to the corresponding generation terminals 200a and 200b. An image distribution device through loop voltage sensing of an image signal line of a video phone, the line SL being switched on.

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