KR100724821B1 - Transmission system for transmitting multi-channel video signal and data signal simultaneously and transmission method thereof - Google Patents

Abstract

The present invention relates to a transmission system and a transmission method for simultaneously transmitting a multi-channel video signal and a data signal.

According to the present invention, there is provided a headend including a video transmitter for transmitting a multi-channel video signal and a data transmitter for transmitting a data signal; And an intermediate node system for distributing the multi-channel video signals and data signals independently transmitted from the headend for each subscriber, and multiplexing specific video channel and data signals required by the subscriber to the subscriber end. This is disclosed.

In addition, according to another aspect of the invention, the step of transmitting the multi-channel video signal and the data signal from the head end to the intermediate node independently; And distributing the multi-channel video signal and the data signal for each subscriber, and multiplexing a specific video channel and data signal required by the subscriber to the subscriber end.

Optical CATV System, Headend, Middle Node, Multiplexer, Channel Selector

Description

Transmission system for transmitting multi-channel video signal and data signal at the same time and transmission method thereof

The following drawings attached to this specification are illustrative of preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to

1 is a block diagram of an optical CATV system according to the prior art.

FIG. 2 is a graph showing the frequency allocation band of the signal transmitted by the system of FIG.

3 is another configuration of the optical CATV system according to the prior art.

4 is a block diagram of a demand access optical CATV system according to the prior art;

FIG. 5 is a graph showing a frequency band for the signal region? In FIG.

FIG. 6 is a graph showing a frequency band for the signal region ② in FIG.

7 is a block diagram of a signal transmission system according to a preferred embodiment of the present invention.

FIG. 8 is a graph showing a frequency band for the signal region? In FIG.

9 is a graph showing a frequency band for the signal region ② in FIG.

FIG. 10 is a graph showing a frequency band for the signal region? Of FIG.

<Description of main reference numerals in the drawings>

100.Headend 101.Video Transmitter

102 ... data transmission section 150 ... distribution

200 ... Mid-node system 201 ... Video signal receiver

Distribution ... 203 ... Transmitter

204 Channel selector 205 Modulator

206 Multiplexer 207 Optical Transceiver

208 ... data signal transceiver 209 ... switching device

250 Subscriber 251 Subscriber Terminal

The present invention relates to a transmission system for transmitting a multi-channel video signal and a data signal at the same time, and more particularly, to a method of transmitting a specific channel to simultaneously transmit a video signal and a data signal at high speed. A transmission system and a transmission method thereof.

Conventional optical CATV systems for simultaneously transmitting video and data signals from the headend to the subscriber end are RF-modulated with the baseband data signal at the frequency allocated for data transmission and then frequency multiplexed with the multichannel video signal. The method of passively distributing the signal to the subscriber station was used.

Referring to FIG. 1, a conventional optical CATV system includes a head end 10 having a multiplexer 13 and an optical transceiver 14 for multiplexing a multi-channel video channel 11 and a data channel 12, A subscriber end including a distribution stage 15 for manually distributing the signal transmitted from the headend 10 to the subscriber end 16 and a plurality of subscriber stations 17 having an optical transmitter 18 ( 106).

The optical CATV system is multiplexed with a multi-channel video signal by the frequency multiplexer 13 after the baseband data signal is RF-modulated by an RF modulator or CATV modem at the headend 10. Here, the frequency band of the data signal is allocated to 500MHz ~ 552MHz in the case of DOCSIS 1.0, the ultra-high speed data transmission standard, the analog video channel is allocated to 54 ~ 500MHz, the digital video channel 552 ~ 750MHz band (see Fig. 2).

However, the frequency bandwidth allocated to data transmission is narrower than the frequency bandwidth allocated to a plurality of video channels, and even in the distribution method, a method in which multiple subscribers share a narrow frequency bandwidth by simply using a manual distribution method. The conventional optical CATV system is not suitable for high speed data transmission.

3 shows another configuration of a conventional optical CATV system. The optical CATV system shown in the figure includes a head end 20 having a video transmitter 21 and a data transmitter 22, a distribution stage 23 provided with a passive optical distributor, and a plurality of subscriber stations 25. This consists of the subscriber station 24 included.

Here, the optical CATV system transmits the video signal and the data signal to the subscriber station 24 using different lines and distribution terminals, respectively, or to the subscriber station 24 using different wavelengths even when using a single line. Use the method. That is, the video signal and the data signal transmitted independently from each other at the head end 20 are transmitted to the distribution terminal 23 by different lines or wavelengths, and then the video signal is distributed by the passive optical splitter at the distribution terminal 23. Passively distributed and delivered to the subscriber terminal 25, the data signal is switched by the router or switch of the distribution terminal 23 is transmitted to the subscriber terminal (25).

In the case of such an optical CATV system, data signals and video signals need to be transmitted from the head end 20 to the subscriber end 24 using different lines or different wavelengths. In addition, since all video channel signals are transmitted to the subscriber station 24 in video signal transmission, the performance of the optical receiver and the RF signal processing unit constituting the subscriber station 24 must satisfy the frequency band characteristics accommodating all video channels. There is a vulnerability that requires the use of special techniques such as scramble techniques in order to provide and maintain differentiated channel services.

Meanwhile, FIG. 4 illustrates a configuration of a demand access optical CATV system that can selectively allocate a channel. Referring to FIG. 4, a demand-access optical CATV system includes a head end 30 having a multiplexer 33 and an optical transmitter 34 for multiplexing a multi-channel video channel 31 and a data channel 32. A manual distribution stage 35 for distributing the signal transmitted from the head end 30 to the intermediate node 36, an optical receiver 37 for photoelectric conversion of the optical signal transmitted from the manual distribution stage 35, A channel selection / optical receiver 39, corresponding to the subscriber station 41, a distributor 38 for distributing signals transmitted from the optical receiver 37 to the respective channel selection / optical receiver 39; It consists of a subscriber station 40 comprising an intermediate node 36 and a plurality of subscriber stations 41 with an optical transmitter and receiver 42. 5 and 6 show the frequency bands of the multi-channel video signals and the frequency bands of the specific selected channels, respectively, corresponding to the signal regions 1 and 2 of FIG.

In such a demand-access optical CATV system, a video signal transmitted from the headend 30 is photoelectrically converted by the optical receiver 37 of the intermediate node 36 and assigned to each subscriber by the distributor 38. It is sent to the selection / optical transmission and reception unit 39, and only the video channel required by the subscriber by the tuner in the channel selection / optical transmission and reception unit 39 is selected and then all-optically converted and transmitted to the subscriber end 40. Since the demand access optical CATV system can selectively transmit only a few channels from the intermediate node 36 to the subscriber station 41, the requirements for the frequency bandwidth of the system from the intermediate node 36 to the subscriber station 40 are alleviated. In addition, since the modulation index of the signal input to the optical channel selection / optical receiver 39 of the intermediate node 36, the optical transmitter 42 of the subscriber station 40, etc. becomes small, the requirement for linearity of the part is reduced. This has the advantage of being mitigated.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and an object thereof is to provide a transmission system and a transmission method having a structure capable of simultaneously transmitting a multi-channel video signal and a data signal using a demand access method.

In order to achieve the above object, a transmission system according to an embodiment of the present invention, a head end having a video transmission unit for transmitting a multi-channel video signal, and a data transmission unit for transmitting a data signal; And an intermediate node system for distributing multi-channel video signals and data signals independently transmitted from the headend for each subscriber, and multiplexing specific video channel and data signals required by the subscriber to the subscriber end.

The intermediate node system includes a video signal receiving unit configured to receive a multi-channel video signal distributed in correspondence with an intermediate node after being transmitted from the head end; A data signal transceiver configured to receive a data signal distributed in response to an intermediate node after being transmitted from the headend, and to transmit a subscriber end data signal to be transmitted to the headend; A distribution unit for distributing the multi-channel video signal received by the video signal receiver for each subscriber; And a channel selector for selecting a specific channel required by the subscriber among the multi-channel video signals allocated by the distributor and the data signal transmitted from the data signal transceiver and the video signal selected by the channel selector. And a transmitter having a multiplexer for multiplexing and a transceiver for transmitting the multiplexed signal to a subscriber end and receiving a subscriber end data signal transmitted from the subscriber end.

The intermediate node system may further include a switching device for switching so that only data to be transmitted to a subscriber end is selected among the distributed data signals.

The intermediate node system may further include a modulator for RF modulating the base band data signal selected by the switching device.

According to another aspect of the present invention, an intermediate node system interposed between a head end and a subscriber end for simultaneous transmission of a video signal and a data signal, the multi-channel video signal distributed in response to the intermediate node after being transmitted from the head end A video signal receiving unit for receiving; A data signal transceiver configured to receive a data signal distributed in response to an intermediate node after being transmitted from the headend, and to transmit a subscriber end data signal to be transmitted to the headend; A distribution unit for distributing the multi-channel video signal received by the video signal receiver for each subscriber; And a channel selector for selecting a specific channel required by the subscriber among the multi-channel video signals allocated by the distributor and the data signal transmitted from the data signal transceiver and the video signal selected by the channel selector. And a transmitter having a multiplexer for multiplexing and a transceiver for transmitting the multiplexed signal to a subscriber end and receiving a subscriber end data signal transmitted from the subscriber end. .

According to another aspect of the invention, the first step of transmitting a multi-channel video signal and a data signal independently from each other from the head end to the intermediate node; And a second step of distributing the multi-channel video signal and the data signal for each subscriber, and multiplexing a specific video channel and data signal required by the subscriber to the subscriber end.

The second step may include: (a) selecting a specific channel required by a subscriber from among the distributed multi-channel video signals; (b) multiplexing the video signal with the video signal of the selected channel; And (c) transmitting the multiplexed signal to a subscriber end, while receiving a data signal transmitted from the subscriber end.

Preferably, before step (b), the step of switching so that only the data to be transmitted to the subscriber end of the distributed data signal is selected; may be further included.

In addition, before the step (b), the step of RF modulating the base band data signal selected by the switching process; preferably further includes.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

7 shows a configuration of a signal transmission system according to a preferred embodiment of the present invention.

Referring to FIG. 7, the signal transmission system according to an exemplary embodiment of the present invention includes a head end 100 for transmitting a video signal and a data signal, and a subscriber end 250 by multiplexing a specific video channel and data signal required by a subscriber. It includes the intermediate node system 200 for transmitting to.

The head end 100 includes a video transmitter 101 for transmitting a multi-channel video signal using an assigned line or wavelength, and a data transmitter 102 for transmitting a data signal. The video transmitter 101 and the data transmitter 102 are preferably configured to convert the multi-channel video signal and the data signal into optical signals and transmit the optical signals to the intermediate node system 200 through the optical fiber cable. In this case, the multi-channel video signal may correspond to a CATV, satellite broadcasting, terrestrial broadcasting video signal. In addition, the multi-channel video signal may be provided in a form in which one carrier frequency is allocated to each channel or in a form in which one carrier frequency is allocated to several channels, and an analog or digital modulation method may be used as the modulation method. 8 and 9 schematically show examples of frequency bands of a multi-channel video signal and a data signal corresponding to the signal regions 1 and 2 of FIG. 7, respectively.

Here, the present invention is not limited to the example of transmitting the multi-channel video signal and the data signal using the optical signal, of course, may be configured to transmit using an electrical signal or an RF signal. Hereinafter, a preferred embodiment of the present invention will be described with reference to an example of transmitting a video signal and a data signal using an optical signal.

Preferably, a distribution stage 150 is provided between the headend 100 and the intermediate node system 200 to distribute the multi-channel video signal and the data signal transmitted from the headend 100 to the intermediate node system 200. do. Here, the distribution stage 150 may be provided with a passive optical splitter for distributing the multi-channel video signal, and a router or switch for switching and distributing the data signal.

The intermediate node system 200 distributes the multi-channel video signal and the data signal distributed by the distribution unit 150 separately from each other after being independently transmitted from the headend 100 for each subscriber, and performs channel selection, multiplexing, transmission and reception processing, and the like. Perform the transmission to the subscriber end (250).

That is, the intermediate node system 200 includes a video signal receiver 201 for receiving and photoelectrically converting a multi-channel video signal, and a subscriber end 250 for receiving and photoelectrically converting a data signal and transmitting the photonic signal to the headend 100. A data signal transmission / reception unit 208 that transmits the data signal by optical conversion, a distribution unit 202 that distributes the multi-channel video signal received by the video signal reception unit 201 for each subscriber, and channel selection, transmission / reception processing, and the like. There is provided a transmitter 203 assigned for each subscriber to perform.

In particular, the transmitter 203 includes a channel selector 204 for selecting only a specific channel required by the subscriber among the multi-channel video signals distributed by the distribution unit 202, a video signal selected by the channel selector 204, and A multiplexer 206 for multiplexing the data signal transmitted from the data signal transmission and reception unit 208, and the subscriber unit 250 is transmitted to the subscriber station 250 while all-optically converting the multiplexed signal However, an optical transmitter 207 for receiving a photo signal and performing photoelectric conversion is provided. FIG. 10 schematically shows an example of frequency bands of a video signal and a data signal of a specific channel multiplexed by the multiplexer 206, corresponding to 3 in FIG. 7.

The channel selector 204 may be configured by adopting a channel selection circuit including a predetermined tuner, which is used in a conventional demand optical CATV system.

The multiplexer 206 preferably multiplexes the data signal to be transmitted to the subscriber station 250 with the video signal selected by the channel selector 204. To this end, between the data signal transceiver 208 and the multiplexer 206, a switching device 209 for switching so that only data to be transmitted to the subscriber end 250 is selected among the data signals distributed by the distribution end 150. ) Is interposed.

Also interposed between the switching device 209 and the multiplexer 206 is a modulator 205 for RF modulating the base band data signal selected by the switching device 209. Here, the data signal may be input to the intermediate node system 200 in a state of being RF-modulated. In addition, when an RF modulated data signal is input to the intermediate node system 200, a predetermined RF demodulator (not shown) may be further provided at the front end of the switching device 209.

After the channel is selected by the transmitter 203 of the intermediate node system 200, the multiplexed signal is transmitted by the optical transceiver 207 to the subscriber end 250. The subscriber end 250 includes a plurality of subscriber stations 251 corresponding to each transmitter 203, and each subscriber terminal 251 is a die for distributing a photoelectric converter, a video signal, and an RF modulated data signal. There is provided an optical transceiver 252 including a flexure, an antenna system for emitting an RF modulated data signal, or a demodulator for demodulating an RF data signal.

Next, a signal transmission method performed by the signal transmission system according to the preferred embodiment of the present invention will be described.

According to the present invention, ultra-fast simultaneous transmission processing of a multi-channel video signal and a data signal is performed to the subscriber end 250 through the headend 100, the distribution end 150, and the intermediate node system 200.

That is, when the multi-channel video signal and the data signal are independently transmitted from the video transmitter 101 and the data transmitter 102 of the headend 100 to the intermediate node system 200, the distribution unit 150 After the signals are distributed by the intermediate nodes, in the intermediate node system 200, the multi-channel video signal is distributed by the distribution unit 202 and the data signals by the switching device 209 by the subscriber, and the transmission unit 203 In multiplexing the specific video channel and data signal required by the subscriber to transmit to the subscriber end 250.

Here, the transmitter 203 is provided with a channel selector 204 to select a particular channel desired by the subscriber from the multi-channel video signal.

In addition, the video signal of the channel selected by the channel selector 204 and the data signal to be transmitted to the subscriber end 250 are multiplexed by the multiplexer 206 to be connected to the subscriber end through one optical fiber cable or one optical wavelength channel. 250 is transmitted at high speed.

Although the invention has been described above by means of limited embodiments and drawings, the invention is not limited thereto and will be described below by the person skilled in the art and the technical spirit of the invention. Of course, various modifications and variations are possible within the scope of the claims.

According to the present invention, a video signal and a data signal can be simultaneously transmitted from one intermediate node system to one subscriber using one signal.

In addition, since the video channel is selectively selected and transmitted by the subscriber's request in the intermediate node system, it is possible to provide differentiated channel service and maintenance for each subscriber, and to reduce the frequency bandwidth and linearity requirements of each part of the system. have.

Claims (11)

In the optical CATV system, A head end having a video transmitter for transmitting a multi-channel video signal and a data transmitter for transmitting a data signal; And And an intermediate node system for distributing multi-channel video signals and data signals independently transmitted from the headend for each subscriber, and multiplexing specific video channel and data signals required by the subscriber to the subscriber end. The intermediate node system, A video signal receiver configured to receive a multi-channel video signal transmitted from the headend and distributed in correspondence with an intermediate node; A data signal transceiver configured to receive a data signal distributed in response to an intermediate node after being transmitted from the headend, and to transmit a subscriber end data signal to be transmitted to the headend; A distribution unit for distributing the multi-channel video signal received by the video signal receiver for each subscriber; And A channel selector for selecting a specific channel requested by the subscriber among the multi-channel video signals allocated by the subscriber and distributed by the distribution unit, and multiplexing the video signal selected by the channel selector and the data signal transmitted from the data signal transceiver And a transmitter having a multiplexer and a transceiver for transmitting the multiplexed signal to a subscriber end and receiving a subscriber end data signal transmitted from the subscriber end. delete The method of claim 1, wherein the intermediate node system, And a switching device for switching so that only data to be transmitted to a subscriber end is selected among the distributed data signals. The method of claim 3, wherein the intermediate node system, And a modulator for RF modulating the base band data signal selected by the switching device. An intermediate node system of an optical CATV system interposed between a headend and a subscriber end for simultaneous transmission of a video signal and a data signal, A video signal receiver configured to receive a multi-channel video signal transmitted from the headend and distributed in correspondence with an intermediate node; A data signal transceiver configured to receive a data signal distributed in response to an intermediate node after being transmitted from the headend, and to transmit a subscriber end data signal to be transmitted to the headend; A distribution unit for distributing the multi-channel video signal received by the video signal receiver for each subscriber; And A channel selector for selecting a specific channel requested by the subscriber among the multi-channel video signals allocated by the subscriber and distributed by the distribution unit, and multiplexing the video signal selected by the channel selector and the data signal transmitted from the data signal transceiver And a transmitter having a multiplexer and a transceiver for transmitting the multiplexed signal to a subscriber end and receiving a subscriber end data signal transmitted from the subscriber end. The method of claim 5, And a switching device for switching so that only data to be transmitted to the subscriber end is selected among the data signals distributed by the distribution unit. The method of claim 6, And a modulator for RF modulating the base band data signal selected by the switching device. In the signal transmission method of the optical CATV system, Transmitting a multi-channel video signal and a data signal independently from each other to the intermediate node from the head end; And And distributing the multi-channel video signal and the data signal for each subscriber and multiplexing a specific video channel and data signal required by the subscriber to the subscriber end. The second step, (a) selecting a specific channel required by a subscriber from the distributed multichannel video signals; (b) multiplexing the video signal with the video signal of the selected channel; And (c) transmitting the multiplexed signal to a subscriber end and receiving a data signal transmitted from the subscriber end. delete The method of claim 8, wherein before step (b), Switching so that only the data to be transmitted to the subscriber end of the distributed data signal is selected; further comprising a. The method of claim 10, wherein before step (b), RF modulating the base band data signal selected by the switching process.

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