KR101095352B1 - Closed-circuit television system for providing hd image using single transmission line - Google Patents

Abstract

PURPOSE: A single line transmission type digital closed circuit television system is provided to set a channel not to overlap each camera. CONSTITUTION: A link terminal(100) searches for a channel band of a downlink signal transmitted to an image collector(300,300A) through a communication line(10). The link terminal sets a channel which is not overlapped with the used channel in a downward signal transmitted from an uplink communication line. The link terminal modulates an image signal of a camera into a set channel. The link terminal synthesizes the modulated image signal with the downlink signal. An image collector modulates the downlink signal according to a channel.

Description

Single Line Transmission High Definition Digital Closed Circuit Television System {CLOSED-CIRCUIT TELEVISION SYSTEM FOR PROVIDING HD IMAGE USING SINGLE TRANSMISSION LINE}

The present invention relates to a digital closed circuit television system, and more particularly, to transmit a plurality of camera video signals to a remote image collector through a single communication line, while automatically transmitting a channel that does not overlap with a channel being used in the communication line. It detects and transmits a video signal, and automatically assigns an ID assigned to a camera according to a set channel to remotely control the camera, and enables a high speed long distance communication to a plurality of local communication networks connected to a plurality of cameras. The present invention relates to a single line transmission type high-definition digital closed circuit television system connected to a wide area network so as to be remotely controlled through the wide area network.

Closed circuit television systems are installed in various facilities such as apartments, intelligent high-rise buildings, department stores, and large discount marts for customer protection and safety. To utilize. Recently, a low pixel analog camera has been replaced by a high pixel digital camera. In such a case, a technical issue of how to transmit a high quality image over a long distance without deterioration of image quality has been a technical issue.

In the conventional closed circuit television system, the image transmission method is classified into an analog transmission method and a digital transmission method.

Analog transmission system consists of UTP cable or coaxial cable. In this case, when the communication line is composed of UTP cable, one or two lines are allocated to the video signal and the audio signal, but one or more lines cannot transmit 8 or more camera images. Accordingly, as the number of cameras increases, UTP Cabling was difficult because the number of cables had to be increased. In addition, since the image collector uses an analog modulator, it is impossible to transmit HD-quality video. If the transmission distance is too long, loss of image quality and noise also occur, resulting in a decrease in transmission quality. When composing a communication line with a coaxial cable, a certain number of camera images are collected and processed by an analog modulator and a channel modulator, which are converted into different channel signals and transmitted through a coaxial cable. It was difficult, and if the transmission distance is too long, there is a problem that the transmission quality is degraded due to image quality damage and noise generation.

The digital transmission method is an alternative to solve the problem of the analog transmission method. It converts the camera image into a digital signal and transmits it over a long distance through the IP network. In order to minimize the load, increasing the number of cameras that normally shoot at 60 fps (frame per second) image increases network load, making normal data transmission difficult, and operating costs associated with the use of IP networks also increase. There was no choice but to reduce the image quality and transmit it, and high compression technology could be applied in other ways, but in this case, the image quality deteriorated, which made it impossible to utilize the advantages of HD.

In addition, the above-described conventional methods may separate the camera image only when the remote image collectors divide the cameras, and may sometimes remotely control the cameras in the image collector. In addition, the channel setting has to be assigned to each camera individually.

Therefore, an object of the present invention is not to use a plurality of communication lines, it is possible to transmit a plurality of camera images in a high quality over a single line without loss of quality, and to set up and identify the channel used by each camera while using a single line It is possible to set or specify automatically when connecting to a single line without having to manually specify the ID for each one, and according to this, a single line transmission type high-definition digital closed circuit television system can be easily installed without difficulty in channel management. To provide.

In order to achieve the above object, the present invention provides a plurality of link terminals 100 for transmitting a downlink signal through a single communication line 10 by modulating the video signal of the camera 11 into a digital video signal, and a single communication line. It is configured to include a video collector (300, 300A) is connected to the (10) to receive and demodulate the downlink signal, the link terminal 100 is transmitted to the image collector (300, 300A) through a communication line (10) After the channel band of the downlink signal is searched, a channel that does not overlap with the channel being used is set, and the video signal of the camera 11 is modulated into the set channel and then synthesized into the downlink signal transmitted through the communication line 10. And the image collectors 300 and 300A demodulate the downlink signal for each channel.

The link terminal 100 sets a channel which does not overlap with a channel being used in a downlink signal transmitted from an uplink communication line 10 opposite to the image collectors 300 and 300A on the communication line 10. It features.

The image collectors 300 and 300A may assign an ID for each channel of the demodulated image signal and transmit a control signal as an uplink signal to control the operation of the camera according to the assigned ID.

The ID is designated in one-to-one with respect to a channel that can be set in the link terminal 100, so that the link terminal 100 can recognize its ID when setting the channel, and an uplink signal. Controls the camera operation according to a control signal corresponding to its own ID, and the link terminal 100 generates a video stream of the plurality of cameras 11 as one stream, modulates it into a set channel, and collects the video collector ( 300 divides the channel video signal for each link terminal 100 into individual camera video signals, and assigns IDs to respective cameras.

The control signal is a signal for controlling any one or more of the pan, tilt, and zoom operations of the camera 11, and is generated by the image collectors 300 and 300A to upward. It is transmitted as a signal, the link terminal 100 is characterized in that for controlling the operation of the camera 11 by demodulating the uplink signal.

The communication line 10 is connected to the heterogeneous communication line 20 through the signal converter 200 by using a plurality of communication line 10 to which the link terminals 100 are connected, and the image collector 300 is a heterogeneous communication line. By connecting to the furnace 20, by specifying a different frequency band for each communication line 20, the link terminal 100 connected to each communication line 20 to set the channel in a frequency division scheme in the specified frequency band In addition, the signal converter 200 is characterized by converting the uplink signal and the downlink signal to the communication signal adopted in the communication line 10 and the heterogeneous communication line 20 to relay.

The communication line 10 is composed of a coaxial cable to be transmitted as an RF signal, and the heterogeneous communication line 20 is configured as an optical communication line to transmit the optical signal.

Therefore, the present invention is configured as described above, but using a single communication line 10 to transmit the channel separated camera video signal, each camera is set to a channel that does not overlap individually, it is difficult to set the channel In addition, the addition of the camera can also be easily added.

In addition, since the present invention assigns an ID of a camera according to a channel set by the camera, the present invention also has an advantage of not having to perform a separate operation for identifying cameras when establishing a telecommunication network.

In addition, the present invention can easily connect the local communication networks 1 to the wide area communication network 2 capable of long-distance transmission, while setting the frequency band to be used in the local communication network 1 in advance so that the signals between the local communication networks 1 can be reached. Work to prevent interference is also unnecessary, whereby the local communication network 2 can be easily configured.

1 is a block diagram of a single-line transmission system high-definition digital closed circuit television system according to an embodiment of the present invention.
2 is a block diagram of a link terminal 100 in an embodiment of the present invention.
3 is a block diagram of a signal converter 200 in an embodiment of the present invention.
Figure 4 is a block diagram of an image collector 300 in an embodiment of the present invention.
Figure 5 is a block diagram of an image collector 300A connected to a communication line 10 in the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or known configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The present invention provides a plurality of link terminals 100 for modulating the video signal of the camera 11 into a digital video signal and transmitting the downlink signal through a single communication line 10, 20, and the single communication line 10, 20. It is configured to include a video collector 300 for receiving and demodulating the downlink signal is connected to, in the description of a specific embodiment of the present invention, the downlink signal transmitted from the link terminal 100 to the video collector 300 The signal transmitted from the image collector 300 to the link terminal 100 is called an uplink signal. In FIGS. 1 to 5, the path of the downlink signal is indicated by a solid line, and the path of the uplink signal is shown by a dotted line. .

1 is a block diagram of a single-line transmission high-definition digital closed circuit television system according to an embodiment of the present invention.

The closed-circuit television system according to the embodiment of the present invention shown in FIG. 1 is, from the viewpoint of a communication network configuration, a local communication network 1 connecting the link terminals 100 to a communication line 10, and an image collector ( A heterogeneous communication line 20 connected to 300 is configured as a wide area communication network 2 connected to a local communication network 1. Here, the local communication network (1) is configured to separate the digital signal for each channel and transmit the RF signal through a communication line 10 made of a coaxial cable or a UTP cable, the wide area communication network (2) is a heterogeneous communication line made of optical cables ( 20), and the local communication network 1 and the wide area communication network 2 use different communication methods, so that the local communication network 1 and the wide area communication network 2 are transmitted through the signal changer 200. Connect. In addition, the local communication network 1 connected to the wide area network 2 may be configured in plural as shown in FIG.

In this case, the link terminal 100 converts the analog image signal of the camera 11 into a digital image signal, modulates it into an RF signal, and transmits it through the communication line 10 as a downlink signal, and then transmits it from the image collector 300. The uplink signal is received through the communication line 10 to control the PTZ operation of the camera 11. Here, the PTZ operation refers to a pan, tilt and zoom operation. In addition, RF signal modulation adopts a method of setting a channel by frequency division by frequency division.

Here, since the plurality of link terminals 100 are connected to a single communication line 10, each link terminal 100 searches for a channel of a downlink signal transmitted to the image collector 300 through the communication line 10. Subsequently, a channel not overlapping with the channel being used is set, and the video signal of the camera 11 is modulated into a set channel and synthesized into a downlink signal and transmitted. This is to allow the plurality of link terminals 100 to transmit downlink signals to different channels so that transmission is performed without interference.

In addition, a frequency band that can be used for each communication line 10 is specified in advance, and the frequency band information specified in this way is stored in each link terminal 100. In other words, the plurality of local communication networks 1 enable the use of a plurality of channels in frequency bands designated differently from each other.

The signal converter 200 transmits the downlink signals transmitted from the link terminals 100 connected to the communication line 10 to the image collector 300 through the heterogeneous communication line 20, and at this time, the local communication network 1. Since the communication methods of the and the wide area network (2) are different from each other, in order to achieve a smooth communication between both communication networks (1, 2), the communication system of the communication line 10 and the heterogeneous communication line (20) adopted It converts into a signal and relays it. That is, the signal converter 200 converts the downlink RF signal of the communication line 10 into an optical signal, transmits the downlink optical signal to the heterogeneous communication line 20, and transmits the uplink optical signal of the heterogeneous communication line 20. The signal is converted into an uplink RF signal and transmitted to the communication line 10. Here, since the frequency bands available for each local communication network 1 are specified differently, even if a signal is transmitted to a single heterogeneous communication line 20 through a plurality of signal converters 200, there is no interference for each channel.

The image collector 300, by dividing and demodulating the downlink signal received through the heterogeneous communication line 20 for each channel to output to the display device installed in the management station 301 or to store on the disk, controlling the camera The control signal for the uplink optical signal is transmitted through the heterogeneous communication line 20.

In addition, the uplink signal may include a voice signal in addition to the control signal for the camera operation described above. Accordingly, when the image collector 300 transmits the voice signal as an uplink signal, the link terminal 100 transmits the uplink signal to the uplink signal. Extracted from and output through the souper (13). In addition, the downlink signal transmitted from the link terminal 100 may include a microphone 12 signal. Accordingly, the downlink signal transmitted from the link terminal 100 receives an audio signal from the microphone 12 connected to the link terminal 100 and is modulated to be included in the video signal. In addition, the image collector 300 separates and stores an audio signal or outputs it through a speaker when demodulating the downlink signal.

On the other hand, the local communication network (1) by installing the image collector 300A connected to the communication line 10, it may be configured to communicate with the link terminal 100 connected to the local communication network (1). Since the image collector 300A connected to the local communication network 1 receives the RF signal instead of the optical signal, the image collector 300A demodulates the downlink image signal of the communication line 10 which is an RF signal without wavelength division.

Hereinafter, the link terminal 100, the signal converter 200, and the image collectors 300 and 300A will be described in detail with reference to FIGS. 2 to 5.

2 is a block diagram of the link terminal 100 in the embodiment of the present invention.

Referring to FIG. 2, the link terminal 100 includes two first and second line connection ports 110a and 110b for cutting the communication line 10 so as to connect the cut sides. Here, the first line connection port 110a is connected to the communication line 10 to which the other link terminal 100 is connected, that is, the uplink line, and the second line connection port 110b is connected to the image collector 300. It is connected to the communication line 10, that is, the downward line.

The link terminal 100 receives a plurality of video signals from a plurality of cameras 11, converts them into digital data using each encoder 132, and then compresses the plurality of pieces of compressed data using the stream generator 131. One stream is generated from the stream, and then a digital channel modulator 130 is used for data transmission to perform channel coding and modulation to the set channel to generate a downlink signal of the set channel. Here, the stream generator 131 may receive an audio signal of the microphone 12 and convert the audio signal to the encoder 132 to include in the stream.

In addition, the link terminal 100 sets the channels for data transmission and combines the first and second line connection ports 110a and 110b with components for synthesizing the set channel signals with the downlink signals of the communication line 10. ) Between. Specifically, the first up and down channel filter 110 for transmitting an uplink signal through the first line connection port 110a and separating the downlink signal input through the first line connection port 110a; A first signal distributor 111 for distributing the separated down signals; A signal combiner (112) for combining the distributed downlink signal and the signal modulated by the digital modulator (130); The synthesized downlink signal is transmitted through the second line connection port 110b, and the uplink signal input through the second line connection port 110b is transmitted to the first up and down channel filter 110. And a second up and down channel filter 114 to be transmitted through the line connection port 110a.

The link terminal 100 includes: a channel detector 120 for searching for a channel being used in another downlink signal distributed by the first signal splitter 111; An output channel setter 121 for setting a channel which does not overlap with the channel searched by the channel detector 120 and using the set channel for modulation in the digital modulator 130; Also provided.

In addition, the link terminal 100 distributes one uplink signal distributed to the second signal distributor 113 when the uplink signal is transmitted from the second uplink channel filter 114 to the first uplink channel filter 110. Is transmitted to the first up-down channel filter 110 and the other one uplink signal is distributed. That is, the link terminal 100 demodulates another distributed uplink signal to the digital demodulator 140, and then separates the control signal from the demodulated upstream signal using the camera control signal separator 141, and separates the audio signal separator 142. To separate the audio signal. Here, the uplink signal is a signal transmitted from the image collector 300 and includes a signal for controlling the operation of the camera, for example, PTZ (pan, tilt, zoom) and an audio signal to be output to the speaker 13.

In addition, the link terminal 100 includes an ID setter 150 for setting an ID, and includes only an ID set as the ID setter 150 and a control signal or a voice signal coded upward. The voice signal separator 142 and the camera control signal separator 141 are controlled to be separated from each other. This is because the image collector 300 configures a closed circuit television system to remotely control all the link terminals 100. In an embodiment of the present invention, IDs are designated one-to-one in advance for the channels that can be set in the downlink signal frequency band used in the system, and the IDs for each channel are stored in the ID setter 150 as described above. When a channel is set in the output channel setter 121, the ID setter 150 sets an ID corresponding to the set channel. This ID setting method is equally applied when allocating an ID for a channel in the ID allocator 321 of the image collector 300 to be described later.

On the other hand, the link terminal 100, it is preferable to be able to set the channel manually, which may be used to designate a specific channel in the construction of a closed circuit television system according to the present invention and also the system This is because the transmission quality may be degraded in a certain channel even during operation, and it is necessary to artificially change the channel. Accordingly, the link terminal 100 includes a manual channel selector 122 connected to an external device, for example, a mobile device that can interface with the link terminal 100 through the input terminal 120a. When the channel is selected by the interface through the output channel setter 121 to the selected channel.

3 is a block diagram of the signal converter 200 in the embodiment of the present invention.

Referring to FIG. 3, the signal converter 200 has one port 220a for connecting to the communication line 10, and two for cutting the heterogeneous communication line 20 so as to connect both sides thereof. Heterogeneous communication ports 210a and 210b are provided. Here, having two heterogeneous communication ports 210a and 210b includes connecting the signal converter 200 in the middle of the heterogeneous communication line 20 and downlinking the local communication network 1 through the port 220a. This is to transmit through the heterogeneous communication line 20 and extract the uplink signal through the heterogeneous communication line 20 to transmit to the local communication network 2 through the port 220a. Accordingly, one of the two heterogeneous communication ports 210a and 210b is connected to the communication line 10 in the direction in which the image collector 300 is connected, which is called the first heterogeneous communication port 210b, and the other The second heterogeneous communication port 210a will be referred to and the internal structure of the signal converter 200 will be described in detail.

Looking at the internal structure of the signal converter 200, the first optical wavelength splitter / multiplexer 217 and the second optical splitter connected to the first heterogeneous communication port 210b as two components for dividing and combining the up and down optical signals The second optical wavelength splitter / multiplexer 210 is connected to the heterogeneous communication port 210a. In addition, it is connected to the port 220a to separate and combine the RF uplink signal and the downlink signal through filtering to transmit the uplink signal to the communication line 10 through the port 220a and through the port 220a. An up-down channel filter 220 separating the down-signal of the communication line 10 is provided.

In addition, the signal converter 200 processes an uplink optical signal and a downlink optical signal transmitted through the heterogeneous communication line 20, and firstly, the second heterogeneous communication port 210a from the first heterogeneous communication port 210b. Referring to the processing of the uplink optical signal transmitted to the, using the first optical wavelength splitter / multiplexer 217 to separate the uplink signal from the optical signal through the first heterocommunication port (210b) and the first O / The E-converter 215 converts the uplink signal into an RF signal, and then divides the uplink signal converted into the RF signal into the signal distributor 213 and transfers the distributed one uplink signal to the up-down channel filter 220. To be transmitted through the communication line 10, and converts another uplink signal back to an optical signal using the second E / O converter 211, and then multiplexes it to the second optical wavelength splitter / multiplexer 210. It is transmitted through the first heterogeneous communication port 210a.

Next, a process of synthesizing the downlink RF signal transmitted through the port 220a to the downlink optical signal transmitted from the second heterogeneous communication port 210a to the first heterogeneous communication port 210b will be described. After separating the downlink optical signal using the second optical wavelength splitter / multiplexer 210 from the optical signal through the second heterocommunication port 210a, the second O / E converter 212 converts the downlink optical signal into an RF signal. . The RF signal obtained by combining the RF signal converted by the second O / E converter 212 and the downlink signal of the communication line 10 separated by the up and down channel filter 220 by the signal combiner 214 and combining the RF signal is obtained. The downlink signal is converted into an optical signal using the first E / O converter 216 and multiplexed so that the converted optical signal can be transmitted to the heterogeneous communication line 20 to be transmitted through the first heterocommunication port 210b.

In the description of the signal converter 200, the multiplexing operation performed by the optical wavelength splitter / multiplexers 210 and 217 is for transmitting an uplink and a downlink optical signal to a single optical path, and the splitting operation performs a filter on the optical signal. Extracting an uplink signal or a downlink signal, and the signal conversion operation performed by the E / O converters 211 and 216 converts an RF signal into an optical signal, and the signal conversion operation performed by the O / E converters 212 and 215. Is to convert the optical signal into an RF signal, and these operations correspond to the techniques generally known in the optical communication technology, and thus detailed descriptions thereof are omitted.

4 is a block diagram of the image collector 300 in the embodiment of the present invention.

Referring to FIG. 4, the image collector 300 includes an optical communication port 310a connected to the heterogeneous communication line 20, while a microphone 301a, a camera control signal inputter 301b, a camera image and a microphone are provided. And audio ports 301c and ports 320a, 320b, 330a, and 330b connected to the output device 301d.

In addition, the image collector 300 is an optical wavelength division multiplexer for separating the downlink optical signal from the optical signal transmitted through the heterogeneous communication line 20 and multiplexing the uplink optical signal to transmit through the heterogeneous communication line 20. And an O / E converter 311 for converting the downlink optical signal separated by the optical wavelength division multiplexer 310 into a downlink signal of an RF signal type, and converting the uplink signal of an RF signal type into an optical signal type. Since the E / O converter 320 allows multiplexing in the optical wavelength division multiplexer 310, it can be processed internally as an RF signal.

That is, the image collector 300 separates the downlink signal converted into the RF signal type by the O / E converter 311 for each channel using the channel separator 320, and separates the downlink signal for each channel from the digital demodulator 321. Demodulate by) to obtain streams for each channel, and process the streams for each channel by stream separator 322 to separate them into individual streams corresponding to individual cameras, and decode the separated individual streams into decoder 323 to process the original camera. Restore video and audio signals. The restored camera image and audio signal are transmitted to the storage device 301c and the output device 301d. Here, since the downlink signal obtained by the O / E converter 311 includes all the channel signals of the link terminals 100 installed in the local communication networks 1, the digital demodulator 321 and the stream separator 322 The number of channel signals is required, and the decoder 323 for each stream separator 322 is required for the number of streams included in one stream. Meanwhile, the downlink signal of a specific channel may not be processed by the digital demodulator 321, the stream separator 322, and the decoder 323, but may be transmitted to an output device 301d capable of outputting the separated channel signal.

In addition, the image collector 300 transmits a control signal for controlling the operation of the camera 11 and a voice signal to be output through the speaker 130 as the uplink signal through the heterogeneous communication line 20. That is, the image collector 300 converts camera-specific control data received from the camera control signal inputter 301b into a single stream using the stream converter 332, and converts the audio signal received from the microphone 301a into an encoder ( 331 is converted and compressed as digital, and the stream and the compressed coded audio signal are coded and modulated into an uplink channel using a digital modulator 330 to transmit a control signal and an audio signal as an uplink signal. Transfer to the E / O converter 312.

Meanwhile, the image collector 300 assigns an ID allocator 340 for allocating IDs for each channel of the received downlink signal in order to identify each link terminal 100 connected to the local communication networks 1. Equipped.

That is, when the digital closed circuit television system is constructed and the system is initially set up, the ID allocator 340 transmits a signal to a channel set by each link terminal 100. ID), so that the corresponding ID is included in the code when coded by the digital modulator 330.

The ID assigned here is associated with the frequency at which the channel is set, so that the uplink signal can be distinguished from the link terminal 100 without setting the ID assigned by the video collector 300 to the corresponding link terminal 100. do. In other words, the ID is designated in one-to-one with respect to the channel that can be set in the link terminal 100, so that the link terminal 100 can recognize its ID when setting the channel. . To this end, the ID setter 150 of the link terminal 100 illustrated in FIG. 2 and the ID allocator 340 of the image collector 300 illustrated in FIG. 4 set or assign an ID according to the same rule. Thus, the same ID is assigned to the same channel. In detail, the frequency band used in the present invention is specified in advance, and small frequency bands to be set as channels in the designated frequency band are pre-assigned, and small frequency bands, that is, IDs are assigned to channels according to a predetermined rule. By doing so, the link terminal 100 can know the ID of the channel set when the channel is set. Accordingly, when the uplink signal and the downlink signal are transmitted between the link terminal 100 and the image collector 300 with the same ID for the same channel, they can be recognized. Meanwhile, the ID assigned by the ID allocator 340 of the image collector 300 may be manually set and set for each link terminal 300.

In addition, when a closed circuit television system is constructed by connecting a plurality of cameras 11 to the link terminal 100, a sub-ID is assigned to the link terminal 100 according to a stream generation order. It is desirable to be able to control the connected camera 11 individually.

5 is a block diagram of an image collector 300A connected to a communication line 10 in the embodiment of the present invention.

The image collector 300A illustrated in FIG. 5 is configured to communicate only with link terminals 100 installed in the local communication network 10, and thus, the image collector of FIG. 4 connected to the heterogeneous communication network 20. Unlike 300, the optical communication interface is provided instead of the optical communication interface. Here, since the image collector 300A is different from the image collector 300 of FIG. 4 only in the communication interface, only the image collector 300A will be described.

That is, when looking at the interface between the uplink signal and the downlink signal, the image collector 300A includes a first line 350a connected to a communication line connected to the link terminals 100 and a communication line connected to the signal converter 200. It has a second port 350b connected to it.

In addition, the image collector 300A transmits an uplink signal of the digital modulator 330 through the first port 350a and separates a downlink signal received through the first port 350a. A filter 350; A signal splitter 351 which divides the separated down signal into two and transmits one downlink signal to the channel separator 320; The other downlink signal distributed by the signal splitter 351 is transmitted through the second port 350b, and the uplink signal received through the second port 350b is separated to the first uplink channel filter 350. A second up and down channel filter 352 which is transmitted and combined with an upstream signal of the digital modulator 330; Also provided.

The image collector 300A configured as described above may branch and monitor the downlink signal transmitted through the communication line 10, and include a camera control signal and an audio signal in an uplink signal to transmit the local communication network ( It is possible to remotely control the link terminals 100 in 1).

On the other hand, in the case of configuring a single local communication network that is not connected to the wide area network 1, the image collector 300A is connected to the end of the local communication network, but the signal distributor 351, the second up and down channel filter 352 and It is not necessary to include the second port 350b, and in this case, the downlink signal transmitted to the channel separator 320 may be directly transmitted from the first up and down channel filter 350 without signal distribution.

Although illustrated and described in the specific embodiments to illustrate the technical spirit of the present invention, the present invention is not limited to the same configuration and operation as the specific embodiment as described above, within the limits that various modifications do not depart from the scope of the invention It can be carried out in. Therefore, such modifications should also be regarded as belonging to the scope of the present invention, and the scope of the present invention should be determined by the claims below.

1: local communication network 2: wide area network
10: communication line 11: camera 11a: camera controller
12: microphone 13: speaker
20: heterogeneous communication line
100: link terminal
200: signal converter
300, 300A: Image Collector

Claims (7)

delete A plurality of link terminals 100 for modulating the video signal of the camera 11 into a digital video signal and transmitting the downlink signal through a single communication line 10 and a single communication line 10 are connected to receive a downlink signal. It is configured to include a video collector (300, 300A) to receive and demodulate,
The link terminal 100,
After retrieving the channel band of the downlink signal transmitted to the image collectors 300 and 300A through the communication line 10, the uplink communication line 10 on the communication line 10 opposite to the image collectors 300 and 300A. In the downlink signal transmitted from the) to set the channel that does not overlap the channel being used, modulates the video signal of the camera 11 to the set channel, and then synthesized and transmitted to the downlink signal transmitted through the communication line 10,
The image collector 300, 300A,
Single-line transmission method high-definition digital closed circuit television system characterized in that the downlink signal is demodulated for each channel.
The method of claim 2,
The image collectors 300 and 300A allocate an ID for each channel of the demodulated video signal and transmit a control signal as an uplink signal to control the operation of the camera according to the assigned ID. High-definition digital closed circuit television system with line transmission.
The method of claim 3, wherein
The ID (ID),
One-to-one is designated in advance for the channel that can be set in the link terminal 100, so that when the channel is set in the link terminal 100 can recognize its own ID, corresponding to its ID in the uplink signal Control the camera operation according to the control signal,
The link terminal 100 generates a video signal of the plurality of cameras 11 into a single stream to modulate the set channel,
The video collector 300 separates the channel video signal for each link terminal 100 into individual camera video signals, and assigns IDs to respective cameras.
The method of claim 3, wherein
The control signal is a signal for controlling any one or more of the pan, tilt, and zoom operations of the camera 11, and is generated by the image collectors 300 and 300A to upward. Signaled,
The link terminal 100 demodulates an uplink signal to control the operation of the camera (11).
The method according to any one of claims 2 to 5,
The communication line 10 is connected to the heterogeneous communication line 20 through the signal converter 200 by using a plurality of communication line 10 to which the link terminals 100 are connected, and the image collector 300 is a heterogeneous communication line. To the furnace 20,
By designating a different frequency band for each communication line 10, the link terminal 100 connected to each communication line 10 to set the channel in a frequency division scheme in the specified frequency band,
The signal converter 200,
Single-line transmission method high-definition digital closed circuit television system characterized in that the uplink signal and the downlink signal to the communication line 10 and the communication signal adopted in the heterogeneous communication line to convert the relay.
The method of claim 6,
The communication line 10 is composed of a coaxial cable to be transmitted as an RF signal,
Single line transmission method high-definition digital closed circuit television system, characterized in that the heterogeneous communication line 20 is configured as an optical communication line to transmit as an optical signal.

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