KR101140524B1 - Hfc net managing system - Google Patents

Abstract

PURPOSE: An HFC(Hybrid Fiber Coax) network operating system is provided to maintain signal quality by increasing the bandwidth of a signal. CONSTITUTION: An OFD(Optical Fiber Distribution)(20) unit separates an UL(Up Link) signal line from a DL(Down Link) signal line. An optical splitter(30) distributes the DL signal line. A optical MUX(Multiplexer)(40) unit accumulates the UL signal line. Plural mini optical network communication modules(50) are connected with the optical MUX unit by an optical cable.

Description

HFC NET MANAGING SYSTEM

The present invention relates to an HFC (Hybrid-Fiber Coaxial) network operation system, and more particularly, to an HFC network operation system installed in an apartment complex and partitioning a communication network relating to CATV and Internet communication in each apartment building.

Recently, a CATV network installed in an apartment constitutes a coaxial cable network for each apartment building, and integrates a coaxial cable network branched from each apartment building into an optical coaxial network communication module (ONU).

Then, the optical coaxial network communication module (ONU) is connected to an optical fiber distribution (OFD) of the main head end, and in the optical fiber distribution, the transmitter and the receiver are separated by wavelength. Will be sent.

In this case, the optical fiber network communication module (ONU) is installed in the basement of the apartment complex, the optical cable connected to the broadcasting head (Main HeadEnd) is installed in the basement of the apartment complex is connected to the optical fiber network communication module (ONU).

In addition, a coaxial cable connected to the optical coaxial network communication module (ONU) is installed from the basement of the apartment complex to each apartment building, and an amplifier is installed at each branch point to amplify the signal supplied to the coaxial cable.

Here, the optical coaxial network communication module (ONU) is connected to the optical transceiver of the broadcasting head (Main HeadEnd) 1: 1, in this case, between the optical coaxial network communication module (ONU) and the optical transmitter of the broadcasting head (Main HeadEnd). The downlink is usually 1310n / m, and the uplink is bidirectional communication using a single wavelength of 1260 ~ 1600n / m.

As described above, the conventional apartment HFC network operation system is widely used, and the optical coaxial network communication module (ONU) because the optical transmission receiver in the broadcasting head (Main HeadEnd) must be connected 1: 1 because the optical coaxial network communication module (ONU) should be increased, the optical transceiver of the ONU broadcasting main headend should be increased, and the optical cable between the optical fiber communication module ONU and the broadcasting head main main end is laid. must do it.

Therefore, in the conventional apartment HFC network operation system, since the number of optical fiber network communication modules (ONU) should be increased, optical fiber receivers of the main headend and expansion of optical cables should be carried out. There is a problem that the construction cost increases according to the number of installation of ONU).

The present invention has been made to solve the above problems, the technical problem to be solved when the expansion of the optical coaxial network communication module (ONU) corresponding to the number of optical coaxial network communication module (ONU) broadcasting transmission room (Main HeadEnd) Of optical fiber transceivers) and multiple optical fiber network communication modules (ONUs) in one optical fiber without installing additional optical cables between the optical fiber transceiver modules (ONU) and the optical transceivers in the main headend. The present invention provides an HFC network operation system that can operate as a transceiver.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The HFC network operation system of the present invention for achieving the above technical problem is operated in apartment complexes having a plurality of apartment buildings in the HFC network operation system for transmitting and receiving CATV and Internet communication signals, which is installed in the broadcasting transmission room Optical transmitter; An optical distribution box connected by the optical transmitter and the optical cable and separating an uplink signal line and a downlink signal line; An optical splitter connected to the optical splitter and an optical cable to distribute the downlink signal line; An optical coupler connected to the optical distribution enclosure and an optical cable to integrate an uplink signal; And a small optical coaxial network communication module configured of a plurality, connected by the optical splitter and the optical cable, and connected to the optical coupler. It includes, The plurality of small optical coaxial network communication module is supplied with a down signal from the optical splitter, by transmitting an uplink signal through the optical coupler, to operate a plurality of small optical coaxial network communication module in one optical transceiver It is characterized by.

In this case, when the optical distribution enclosure is operated as one, the small optical coaxial network communication module may be configured to operate between two to eight.

The optical splitter may be connected to the optical splitter by one optical cable line, and the optical coupler may be connected to the optical splitter by one optical cable line.

In addition, the plurality of small optical coaxial network communication module transmits by setting different wavelengths of the uplink signal supplied to the optical coupler, the optical coupler is a single optical cable for optical signals of different wavelengths output from the small optical coaxial network communication module Can be delivered.

In addition, each of the plurality of small optical coaxial network communication module is installed in each apartment in the apartment complex, at least one of the coaxial cable modem for the Internet communication and the digital broadcast receiver for broadcast reception is further installed in each apartment in the apartment complex And it can communicate with the small optical coaxial network communication module.

According to the present invention, since the optical receiver and the optical coaxial network communication module are not configured as 1: 1, a plurality of small optical coaxial network communication modules may be connected to one optical receiver and one optical distribution enclosure, and thus, the optical receiver and the optical coaxial network communication module may be configured. It is effective in reducing installation costs.

In addition, the present invention can separate and operate the wavelength of the uplink signal for each small optical coaxial network communication module in a state in which a plurality of small optical coaxial network communication module is connected to one optical distribution enclosure, the bandwidth of the signal that can be transmitted This increase has an effect of maintaining a much better signal quality than the conventional one.

1 is a block diagram of an HFC network operation system according to an embodiment of the present invention.
2 is a schematic diagram of the HFC network operation system shown in FIG.
3 is a schematic diagram of a comparative example according to the HFC network operation system shown in FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, the components constituting the HFC network operation system according to an embodiment of the present invention, the coupling relationship between the components, and the role of the components will be described.

1 is a block diagram of an HFC network operation system according to an embodiment of the present invention. FIG. 2 is a schematic diagram of the HFC network operation system shown in FIG. 1. 3 is a schematic diagram of a comparative example according to the HFC network operation system shown in FIG.

1, the HFC network operation system according to an embodiment of the present invention is an optical transceiver 10, optical distribution enclosure 20, optical distributor 30, optical coupler 40 and a small optical coaxial network communication module And 50.

The optical transmitter 10 is installed in a broadcasting transmission room. The optical transceiver 10 is installed in the broadcasting transmission room to transmit and receive the Internet communication signal input and output from the optical distribution enclosure 20, and transmits the CATV signal output from the broadcasting transmission room as an optical signal.

The optical fiber distribution unit 20 (OFD) is connected to the optical transceiver 10 by an optical cable. The optical splitter 20 is connected to the optical splitter 30 and an optical cable of one core, and is connected to the optical coupler 40 and an optical cable of one core, thereby separating the uplink signal line and the downlink signal line. The light distribution enclosure 20 may be installed in a pillar or a basement communication panel in the complex formed around the apartment complex.

The optical splitter 30 is connected to the optical splitter 20 by an optical cable and distributes a downlink signal line. The optical splitter 30 distributes the downlink signal output from the optical distribution enclosure 20 to each of the plurality of small optical coaxial network communication modules 50. In the present exemplary embodiment, the optical splitter 30 may receive an optical signal from the optical distribution enclosure 20 through one optical cable and distribute the input optical signal to up to eight lines.

The optical coupler 40 (MUX) is connected to the optical distribution enclosure 20 by an optical cable and integrates an uplink signal. The optical coupler 40 receives an upward signal output from each of the plurality of small optical coaxial network communication modules 50 and transmits the signal to the optical distribution enclosure 20 through one optical cable. In the present embodiment, up to eight signals input from the small optical coaxial network communication module 50 may be input, and a maximum of eight signals may be integrated and transmitted to the optical distribution box through one optical cable.

Here, the reason why the optical splitter 30 and the optical coupler 40 are connected to the optical splitter 20 and one optical cable line is that the optical splitter 30 and the optical combiner 40 to the optical splitter 20. This is to reduce the number of lines of the optical cable between long distance lines by operating the distance of the long distance, and to maintain the transmission quality of the signal above a certain level by separating the upstream signal and the downlink signal.

The miniature optical coaxial network communication module 50 (Mini ONU) transmits a downlink signal through the optical splitter 30. In addition, the small optical coaxial network communication module 50 transmits an uplink signal through the optical coupler 40.

Here, the plurality of small optical coaxial network communication module 50 transmits by setting different wavelengths of the uplink signal supplied to the optical coupler 40, the optical coupler 40 is another output from the small optical coaxial network communication module 50 Optical signal of wavelength can be transmitted through one optical cable. The wavelength range of the uplink signal separated and output from the small optical coaxial network communication module 50 may use a band within 1260n / m to 1600n / m. On the other hand, the small optical coaxial network communication module 50 may output the wavelength of the downlink signal in a single bandwidth of 1310n / m. As such, the plurality of small optical coaxial network communication modules 50 can narrow down the communication band of the downlink signal and widen the communication band of the uplink signal by different wavelengths, thereby preventing bottlenecks in the communication signal and improving signal quality. Will be. That is, in the conventional case, one optical coaxial network communication module is used, but the present invention uses a plurality of small optical coaxial network communication modules 50.

Meanwhile, each of the plurality of small optical coaxial network communication modules 50 is installed in each apartment in the apartment complex, and each generation in the apartment complex is a coaxial cable modem 60 for internet communication and a digital broadcast receiver 70 for broadcast reception. At least one of them is installed.

Here, the coaxial cable modem 60 for the Internet communication to establish the Internet communication environment by performing communication with the small optical coaxial network communication module 50 when generating an uplink signal and a downlink signal for the Internet.

In addition, the digital broadcasting receiver 70 for CATV transmission and reception receives a downlink signal for receiving the CATV signal through the small optical coaxial network communication module 50 to build a CATV reception environment.

In this case, in each apartment, a trunk amplifier (TVA) or an expansion amplifier (EA) may be installed at each coaxial cable section to amplify the up and down signals.

The plurality of small optical coaxial network communication module 50 separates the communication signal input and output from each generation of the apartment building into an uplink signal and a downlink signal, receives the downlink signal from the optical splitter 30, and receives the uplink signal from the optical combiner 40 ) Will be supplied.

In this case, the optical splitter 30 and the optical coupler 40 signal through two optical cable cores in a state in which the uplink signal and the downlink signal for CATV and the Internet output from the plurality of small optical coaxial network communication modules 50 are integrated. Will be sent.

That is, a plurality of small optical coaxial network communication module 50 that can be connected to one optical distribution enclosure 20 may be operated. In the present embodiment, a total of eight small optical coaxial network communication module 50 that can be connected to one optical distribution enclosure 20, the number of the small optical coaxial network communication module 50 is the optical splitter 30 and the optical coupler It may vary depending on the signal separation form of 40.

Here, FIG. 3 is a schematic diagram of a conventional HFC network operating system according to a comparative example, in FIG. 3, an optical receiver (not shown), an optical distribution box (OFD), and an optical coaxial network communication module (ONU). ) Is installed in the apartment complex in a 1: 1 connection, and the optical coaxial network communication module (ONU) transmits and receives communication signals of each generation while connected to the trunk amplifier (TBA) or the expansion amplifier (EA) through a coaxial cable. do. In the case of Figure 3, the optical distribution box (OFD) and the optical coaxial network communication module (ONU) can only be configured in a 1: 1 day, if the number of apartments is large, out of the signal processing capacity of the optical coaxial network communication module (ONU) Since the number of optical coaxial network communication modules (ONU) must be increased, the optical distribution enclosure (OFD) and optical receivers are expanded to correspond to the number of optical coaxial network communication modules (ONU), and the newly expanded optical coaxial network communication modules (ONU) are added. Two cores of optical cable must be installed between and the optical distribution enclosure (OFD). This increases the installation cost of the HFC network operation system.

On the other hand, as shown in Figure 2, in the HFC network operation system according to an embodiment of the present invention, the optical distribution box 20 and the optical coaxial network communication module is not configured as 1: 1, as in the conventional one optical A plurality of small optical coaxial network communication module 50 may be connected to the distribution enclosure 20. In this case, preferably, the HFC network operation system according to an embodiment of the present invention is a small optical coaxial network communication module (at least two to a maximum of eight to one optical receiver 10 and one optical distribution enclosure 20 ( 50) can be installed and operated.

That is, the HFC network operating system according to an embodiment of the present invention can connect several small optical coaxial network communication modules 50 to one optical receiver 10 and one optical distribution enclosure 20, which is more expensive than before. This is reduced.

Furthermore, the HFC network operation system according to an embodiment of the present invention is to install a small optical coaxial network communication module 50 for each apartment building, and separate the wavelength of the uplink signal differently for each small optical coaxial network communication module 50 Since the bandwidth of the signal that can be transmitted is increased, the signal quality can be maintained much better than that of FIG.

It will be appreciated by those skilled in the art that changes may be made to the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

10; Optical transceiver 20; Light distribution enclosure
30; Optical splitter 40; Optical coupler
50; Small optical coaxial network communication module
60; Coaxial cable modem
70; Digital broadcasting receiver

Claims (5)

In the HFC network operation system that operates in apartment complexes having a plurality of apartment buildings and transmits and receives CATV and Internet communication signals,
An optical transceiver installed in a broadcasting transmission room;
An optical distribution box connected by the optical transmitter and the optical cable and separating an uplink signal line and a downlink signal line;
An optical splitter connected to the optical splitter and an optical cable to distribute the downlink signal line;
An optical coupler connected to the optical distribution enclosure and an optical cable to integrate an uplink signal; And,
A small optical coaxial network communication module composed of a plurality, connected by the optical splitter and the optical cable, and connected to the optical coupler; Including;
The plurality of small optical coaxial network communication module receives a down signal from the optical splitter, and transmits an uplink signal through the optical coupler, so that a plurality of small optical coaxial network communication module is operated in one optical transceiver,
The plurality of small optical coaxial network communication module transmits by setting different wavelengths of the uplink signal supplied to the optical coupler,
The optical coupler transfers optical signals of different wavelengths output from the small optical coaxial network communication module to one optical cable,
The optical splitter is connected with the optical splitter by one optical cable line, and the optical coupler is connected with the optical splitter with one optical cable line,
Each of the plurality of small optical coaxial network communication module is installed in each apartment in the apartment complex,
At least one of a coaxial cable modem for internet communication and a digital broadcasting receiver for broadcast reception is installed in each generation in the apartment complex to communicate with the small optical coaxial network communication module.
The method of claim 1,
When the optical distribution box is operated by one, the small optical coaxial network communication module is configured to operate between two to eight HFC network operating system, characterized in that the operation.
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