KR200339656Y1 - An apparatus for division-distribution and combination - Google Patents

Abstract

The present invention relates to an optical signal separation distribution and coupling device, and to transmit and receive signals necessary for broadcast transmission and communication with a plurality of devices through a single optical cable, after distributing the optical signal as an electrical signal required for the device It is an object of the present invention to provide an apparatus for converting and supplying an electrical signal from a device, converting the electrical signal into an optical signal, converting the electrical signal, combining the electrical signal, and converting the electrical signal.

Description

An apparatus for division-distribution and combination

The present invention relates to an apparatus for separating and combining optical signals, and more particularly, converts optical signals into electrical signals so that signals necessary for broadcasting transmission and communication with a plurality of devices can be transmitted and received through one optical cable. It is an object of the present invention to provide an apparatus for supplying to an apparatus, converting an electrical signal from the apparatus into an optical signal, and then converting and combining the electrical signal into an electrical signal, and then converting and converting the electrical signal into an optical signal.

Optical communication was accomplished by a Ruby laser developed by Maiman in 1960. However, commercialization was made in earnest by Corning Glass in 1970 through the development of optical fiber with 20dB / km transmission loss. Representative examples of such optical communication systems include optical fiber transmission paths as transmission media, semiconductor lasers or light emitting diodes as light sources, and optical transmission systems using optical detectors as light receivers. That is, it is a communication system having a principle of transferring information by converting an electrical signal into an optical signal through an optical fiber using light as a physical transmission line.

Such an optical communication method has been able to simultaneously process up to tens of thousands of times the information content in a much better state than copper wires, causing a decisive change in the expansion of the communication network. The advantages of optical communication compared to telecommunications based on conventional copper lines are as follows. First, there is no electromagnetic interference (ENI) and no influence of climate. Although it is necessary, it can extend the no-distance distance to more than 50km, and the transmission capacity is much larger than the existing transmission line, and it is excellent in security because it is not possible to eavesdrop from the outside. It is advantageous to build communication system. Taking advantage of these advantages, optical communication has become a core technology of the next generation information communication network.

This optical communication method can be used very conveniently when transmitting or receiving data necessary for an external device using different frequencies in one optical cable. In this case, the optical signal transmitted from the optical cable is converted into an electrical signal and separated according to the frequency, and then supplied to a required device, the signal output from the device is synthesized according to the frequency, and then converted into an optical signal and provided through the optical cable. have.

However, a problem may occur when transmitting or receiving data and broadcast signals required for an external device with the same multiple optical wavelengths on one optical cable. That is, when optical signals made of light have the same wavelengths, they cause interference with each other, resulting in a change of data and broadcast signals.

For example, in a CATV system, when a plurality of signals having the same wavelength, which are optically converted, are transmitted to a single optical cable by synthesizing the upstream signals outputted from a plurality of CATV terminals, the signals of the CATV terminals converted into optical signals are synthesized. In this case, signals having the same wavelength interfer with each other, resulting in a synthesis of distorted signals.

In order to solve this problem, a method of using a high-speed switching device in the case of data transmission and reception has been conventionally proposed. This method does not combine output signals from a device converted into an optical signal into a single signal, but delivers the output from one device at a time in accordance with the switching operation of the switching device. However, such a prior art has a problem that the switching speed of the switching device has to increase as the size of data and broadcast signals increases and the number of connected devices increases, thereby causing a sharp increase in manufacturing costs. Therefore, when a switching device corresponding to a certain size of data and a certain number of devices is used, and the size of the data increases or the number of devices increases, the switching device needs to be additionally installed. In addition, all the signals of the broadcasting system should be transmitted in real time, but due to the limitation of the operating speed of the switching device, it is difficult to transmit all the signals in real time.

Another prior art, in order to solve the above-mentioned problems, has been proposed to directly connect broadcast and data signals 1: 1 with a terminal. However, when the number of terminals to be connected such as a large apartment complex is large, the number of optical cables supplied increases the installation cost, and there is a problem that management and A / S is difficult.

The present invention is derived to solve the above-described problems of the prior art, an optical signal capable of transmitting and receiving real-time data and broadcast signals by directly combining data and broadcast signals transmitted from a plurality of devices in real time without using a switching device It is an object to provide a separate dispensing and combining device.

1 is a block diagram of an optical signal separation distribution and coupling device according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: optical signal synthesizer 40, 70: optical signal separator

12, 55, 155: electro-optical converter

42, 51, 61, 72, 151, 161: opto-electric converter

26, 30: optical splitter 52, 152: first band separator

53, 63, 153, 163: 2nd band separator 80, 90: combiner

A, B: optical signal input cable C: optical signal output cable

6, 50, 150: optical signal synthesis / separator A1, AN: consumer (generation)

In order to achieve the above object, the optical signal separation distribution and combining apparatus according to the present invention is a N small group of two or more natural numbers including CATV, mobile communication, MATV, satellite broadcasting devices using the same or different frequency bands In a network composed of M intermediate groups of two or more natural numbers, the first optical signal cable carrying signals required for CATV and mobile communication devices and the second optical signal cables carrying signals required for MATV and satellite broadcasting devices. In the apparatus for receiving and distributing, combining the electrical signal output from the CATV and the mobile communication device by a third optical signal cable, synthesized the signal of the first optical signal cable and the second optical signal cable and transmits to the optical signal synthesizer A first optical signal synthesizer / separator for transferring a signal of the optical signal synthesizer to the third optical signal cable; An optical signal synthesizer for transferring the optical signal from the first optical signal combiner and separator to the first optical splitter, and for transferring the optical signal from the second electro-optical converter to the first optical signal combiner and separator; A first optical splitter for distributing the optical signal transmitted from the optical signal synthesizer to M intermediate group units; A second optical splitter for distributing the middle group optical signal distributed by the first optical splitter into N small group units; One of the small group optical signals distributed by the second optical splitter is transferred to the second optical signal synthesizer and the separator, and the optical signals output from the second optical signal synthesizer and separator of the small group are separated to the third optical-electric converter. An optical signal separator for transmitting; Second optical signal synthesis, which transmits the optical signal transmitted from the optical signal separator to the first optical-to-electric converter and the second optical-to-electric converter, synthesizes the optical signal output from the first electro-optical converter, and delivers the optical signal to the optical signal separator. Separator; A first optical-to-electric converter for converting the optical signal transmitted from the second optical signal synthesizer / separator into an electrical signal and transferring the optical signal to the first band separator; A first band separator for filtering the frequency for the device to pass the electrical signal from the first opto-electric converter to the first second band separator and for transferring the signal from the first second band separator to the first electro-optical converter ; A first second band separator for band separating the filtered electrical signal from the first band separator to the device and transferring the electrical signal output from the device to the first band separator; A first electro-optical converter for converting an electrical signal output from the first band separator into an optical signal; A second optical-to-electric converter for converting the optical signal transmitted from the second optical signal synthesizer / separator into an electrical signal and transferring the optical signal to the second second band separator; A second second band separator for band separating and transmitting the electric signal transmitted from the second photo-electric converter to the device; A third optical-to-electric converter outputted from the first electro-optical converter and synthesized by the second optical signal synthesizer / separator and converted into an electrical signal by the optical signal separator; A first combiner for coupling the electrical signal converted in the third opto-electric converter and the electrical signals converted in N-1 other third opto-electric converters other than the third opto-electric converter; A second combiner for coupling the signal coupled at the first combiner with the signals coupled at M-1 other first combiners other than the first combiner; And a second electro-optical converter converting the electrical signal coupled by the second combiner into an optical signal and transferring the electrical signal to the first optical signal synthesizer.

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

Embodiment

An optical signal separation distribution and coupling device according to an embodiment of the present invention will be described with reference to FIG.

1 is a block diagram of an optical signal separation distribution and coupling device according to an embodiment of the present invention.

In the embodiment, the optical signal cable A is an optical signal input cable for transmitting optical signals for CATV and mobile communication, and the optical signal cable B is an optical signal input cable for transmitting optical signals for MATV and satellite broadcasting, and the optical signal cable C is assumed to be an optical signal output cable for transmitting signals from CATV and mobile communication devices to the outside. In addition, it is assumed that the number of middle groups is M, the number of small groups is N, and the above devices are installed at home. However, the present invention is not particularly limited thereto, and it is noted that various modifications and changes are possible within the spirit of the present invention according to various environments.

In FIG. 1, LD denotes an electro-optical converter, and PD denotes an opto-electric converter.

The first optical signal synthesizer / separator 6 synthesizes the signals of the first optical signal cable A and the second optical signal cable B, passes them to the optical signal synthesizer, and separates the upstream signals synthesized by the optical signal synthesizer. To the third optical signal cable (C).

The optical signal synthesizer 10 is connected to the first optical signal combiner / separator 6 and connected to the first optical splitter 26, and synthesizes the signal from the second electro-optical converter 12 to the first optical signal. It is sent to the synthesis / separator (6).

The first optical splitter 26 distributes the optical signal from the optical signal synthesizer 10 to the number of M intermediate groups.

The second optical splitter 30 is connected to one of the M optical signals distributed from the first optical splitter 26 and distributes it into N optical signals.

The optical signal separator 40 is connected to the second optical splitter 30 and is connected to the second optical signal combiner / separator 50, and the second optical splitter 30 receives signals from the second optical splitter 30 through one optical cable. The optical signal is separated in order to transmit the signal to the signal combiner / separator 50 and to transmit the uplink signal synthesized in the second optical signal combiner / separator 50 to the third optical-to-electric converter 42.

The second optical signal synthesizer 50 is connected to the optical signal separator 40 and the first optical-to-electric converter 51, the second optical-to-electric converter 61, and the first electrical-to-optical converter 55. And separates and transmits the signal from the optical signal separator 40 to the first optical-to-electric converter 51 and the second optical-to-electric converter 61 through one optical cable and from the first electro-optical converter 55. The optical signal is synthesized to deliver the signal to the optical signal separator 40.

The first optical-to-electric converter 51 converts the optical signal from the second optical signal combiner / separator 50 into an electrical signal and transfers the electrical signal to the first band separator 52.

The first band separator 52 receives an electrical signal from the first opto-electric converter 51 and passes it to the first second band separator 53, and transmits the electrical signal from the first second band separator 53. 1 to the electro-optical converter 55. That is, the first band separator 52 separates the received signal from the transmitted signal so that the received signal is transmitted to the first second band separator 53 and the transmitted signal is transmitted to the first electro-optical converter 55. It has the function of a lexer.

The first second band separator 53 transmits the electrical signal from the first band separator 52 to the device and the electrical signal from the device to the first band separator 52. That is, the first second band separator 53 filters the frequencies used in the device from the signal of the first band separator 52 and supplies them to the device. The first band separator 52 filters the frequencies from the signal of the device. It will act as a diplexer to pass to. In addition, the second band separator 53 has not only the function of the band separator but also the function of the broadband divider which simultaneously accommodates all the bands as necessary.

The first electro-optical converter 55 converts the electrical signal of the first band separator 52 into an optical signal and transfers the electrical signal to the second optical signal synthesizer 50.

The third photo-electric converter 42 converts the optical signal from the first electro-optic converter 55 through the second optical signal synthesizer 50 separated by the optical signal separator 40 into an electrical signal. .

The first combiner 80 combines the electrical signals of the N-1 third opto-electric converters other than the third opto-electric converter 42 and the third opto-electric converter 42 into one.

The second combiner combines the signals coupled through the M first combiners into one.

The second electro-optical converter 12 converts the electrical signal coupled in the second combiner into an optical signal and transmits the converted optical signal to the optical signal synthesizer 10.

The third optical signal cable C is equipped with an optical signal output from the aforementioned second electro-optical converter 12, synthesized by the optical signal synthesizer 10 and separated by the first optical signal synthesizer / separator 6 ( (Not shown) for transmission optical signal cable. This allows data to be transmitted.

In addition, the operation from the optical signal separator 40 to the first and second second band separators 53 and 63 occurs in the same way in the other two second band separators 153 and 163 from the optical signal separator 70.

The operation of the embodiment will be described below.

CATV, mobile communication, MATV, and satellite broadcasting signals synthesized and transmitted through the optical signal cables A and B are transmitted to the optical signal synthesizer 10 through the first optical signal synthesizer / separator.

Thereafter, the optical signals are distributed to the M signals in the first optical splitter 26 after passing through the optical signal synthesizer 10.

One of the signals is divided into N signals in the second optical splitter 30. Of course, M-1 signals are also divided into N signals in the M-1 second optical splitters (not shown).

The signal distributed by the second optical splitter 30 passes through the optical signal separator 40 and the second optical signal combiner / separator 50, and then the first optical-to-electric converter 51 and the second optical-to-electric converter ( Is converted into an electrical signal.

Next, the electrical signal converted by the first opto-electric converter 51 passes through the first band separator 52 and then is transmitted to the device through the second band separator 53.

At the same time, the electrical signal converted by the second opto-electric converter 61 is transmitted to the device through the second second band separator 63.

Thereafter, the signal from the device passes through the second band separator 53, and is then converted into an optical signal by the first electro-optical converter 55 through the first band separator 52, and the second optical signal synthesizer / separator ( 50, and then separated in the optical signal separator 40, and then converted to an electrical signal in the third photo-electric converter 42.

Here, since the MATV and satellite broadcasting connected to the second second band separator 63 are unidirectional signals, there is no separate transmission signal from the device.

Electrical signals from the N second opto-electric converters are combined into one signal at the first combiner, and electrical signals from the M first combiners are combined into one signal at the second combiner.

One electrical signal output from the second combiner is converted into an optical signal in the second electro-optical converter 12, synthesized in the optical signal synthesizer 10, and then passed through the first optical signal synthesizer / separator 6. 3 optical signal cable (C).

The third optical signal cable C transmits the optical signal to the outside through equipment (not shown).

(Example)

In the following, examples according to the embodiment will be described.

First, it is assumed that one optical signal cable transmits and receives a CATV and a mobile communication signal, and the other optical signal cable transmits and receives a MATV and a satellite broadcasting signal. The embodiment is applied to an apartment complex consisting of 1000 households, and it is assumed that 50 households constitute one building and 20 apartment buildings. There may be various combinations of M and N for supplying an optical signal to the 50th generation, but in this embodiment, it is assumed that M and N are 2 ³ (that is, M and N are 8). By this assumption, one optical cable can be separated into 64 optical signals of up to 2 ³ x 2 ³ .

CATV, satellite broadcasting, MATV and mobile communication signals are synthesized as one in the optical signal synthesizer and splitter, and one optical cable is distributed to each building in the management room. That is, one optical cable is transmitted to each copper through the optical cable through the same number of optical cables. Therefore, one optical cable is divided into 20 optical cables, and the total number of optical cables from the management room is 20.

Each building is connected to the management room by one optical cable, and in each building one optical cable is connected to each household through an optical distributor. Therefore, every household in each building is connected by 50 cables.

Therefore, the number of optical cables connected from the management office to all the buildings is 20, and the number of optical cables connected to all households in each building is 50.

Fifty optical cables from each household constituting a copper are converted into electrical signals and combined, and then converted into optical signals and combined into one optical cable and connected to the management office.

(Comparative Example)

In the comparative example as in the embodiment, it is assumed that one optical signal cable transmits and receives a CATV and a mobile communication signal, and the other optical signal cable transmits and receives a MATV and a satellite broadcasting signal. The embodiment is applied to an apartment complex consisting of 1000 households, and it is assumed that 50 households constitute one building and 20 apartment buildings.

In the comparative example, the management office and each household are directly connected in a 1: 1 manner.

Therefore, since two optical cables must be connected to each household in total of 1000 households, a total of 2000 optical cables are directly connected to each household from the management office.

(Comparison of Examples and Comparative Examples)

Table 1 shows the number of cables used in Examples and Comparative Examples.

Item Management room → number of cables used for connection to each building The number of cables used for the connection to each house Management room → number of cables used for connection to all buildings Example One 50 20 Comparative example 100 100 2000

Therefore, in the comparative example, since 2000 cables come out of the management room, the material cost, equipment cost, and management cost increase.

However, in the embodiment, since only 20 cables come out of the management room, material cost, equipment cost, and management cost can be greatly reduced.

In addition, when one generation of the optical cable is damaged and needs to be replaced or repaired, the management room has to find and repair or replace a specific generation of the optical cable in 2000 optical cables, which greatly reduces the management efficiency and takes a lot of time. In this area, 100 generations of fiber can be found and repaired or replaced by a specific generation, resulting in increased management efficiency.

Embodiments of the present invention have been described in detail with reference to the accompanying drawings.

However, the present invention is not limited thereto, and it should be noted that various modifications and changes are possible within the spirit and spirit of the appended claims.

According to the present invention, there is provided a method and apparatus for transmitting / receiving RF signals from various devices that perform convergence transmission of broadcasting and communication, and perform bidirectional transmission functions through one optical cable, and include transmission speed, transmission capacity, and transmission quality. This greatly simplifies construction by reducing the number of pipes and wiring, and greatly reduces material, equipment and maintenance costs.

In addition, according to the present invention, in a device requiring real-time data and broadcast signal transmission and reception, it is possible to provide a method and apparatus capable of transmitting and receiving data and broadcast signals in real time without interruption.

Claims (1)

In a network consisting of M intermediate groups of two or more natural numbers, including N small groups of two or more natural numbers, including CATV, mobile, MATV, and satellite broadcasting devices using the same or different frequency bands, Receives and distributes the first optical signal cable that transmits the necessary signal to the communication device and the signals necessary for the MATV and satellite broadcasting device through the second optical signal cable, and distributes the electrical signals output from the CATV and the mobile communication device to the third optical signal. In the device for coupling with a cable, A first optical signal synthesizer / separator for synthesizing the signals of the first optical signal cable and the second optical signal cable to a optical signal synthesizer, and transferring the signal of the optical signal synthesizer to the third optical signal cable; An optical signal synthesizer for transferring the optical signal from the first optical signal combiner and separator to a first optical splitter, and for transferring the optical signal from the second electro-optical converter to the first optical signal combiner and separator; A first optical splitter for distributing the optical signals transmitted from the optical signal synthesizer into M intermediate groups; A second optical splitter for distributing the middle group optical signals distributed by the first optical splitter into N small group units; A third optical-electric converter by transferring one of the small group optical signals distributed by the second optical splitter to a second optical signal synthesizer and a separator, separating the optical signals output from the second optical signal synthesizer and separator of the small group Optical signal separator for transmitting to; A second light that transmits the optical signal transmitted from the optical signal separator to the first optical-electric converter and the second optical-electric converter, and synthesizes the optical signal output from the first electrical-optical converter to the optical signal separator Signal synthesis / separator; A first optical-to-electric converter for converting the optical signal transmitted from the second optical signal synthesizer / separator into an electrical signal and transferring the optical signal to the first band separator; An electrical signal transmitted from the first optical-to-electrical converter to filter the frequency for the device and to pass it to the first second-band separator, and to transfer the signal from the first second-band separator to the first electro-optical converter One-band separator; A first second band separator for band separating the electrical signal filtered by the first band separator to the device and transferring the electrical signal output from the device to the first band separator; A first electro-optical converter for converting an electrical signal output from the first band separator into an optical signal; A second optical-to-electric converter for converting the optical signal transmitted from the second optical signal synthesizer / separator into an electrical signal and transferring the optical signal to a second second band separator; A second second band separator for separating and transferring the electric signal transmitted from the second photo-electric converter to the device; A third optical-to-electric converter outputted from the first electro-optical converter and converted by the second optical signal synthesizer / separator and separated from the optical signal separator into an electrical signal; A first combiner for coupling the electrical signal converted by the third opto-electric converter and the electrical signals converted by N-1 other third opto-electric converters other than the third opto-electric converter; A second combiner for coupling the signal coupled at the first combiner and the signals coupled at M-1 other first combiners other than the first combiner; And And a second electro-optical converter converting the electrical signal coupled by the second combiner into an optical signal and transferring the electrical signal to the first optical signal synthesizer.