KR100557141B1 - Optical signal transmission system and method for broadcasting and communication mergence ftth - Google Patents

Abstract

Disclosed is an optical signal transmission system for broadcast communication convergence FTTH. The optical signal transmission system is provided on the OLT side, synthesizes different types of broadcast optical signals having different optical wavelengths, distributes the synthesized broadcast synthesized optical signal in proportion to the number of ONUs connected to the OLT, and distributes each broadcast synthesized. An optical multiplex unit (OMU) for synthesizing an optical signal and a communication optical signal and transmitting the synthesized broadcast / communication optical signal to the ONU through one optical fiber; And an optical demultiplex unit (ODU) provided at the ONU side and classifying the broadcast / communication composite optical signal transmitted from the OMU according to the type of the signal.

Broadcast, Communication, FTTH, OLT, ONU, Optical Transmission, Fusion

Description

OPTICAL SIGNAL TRANSMISSION SYSTEM AND METHOD FOR BROADCASTING AND COMMUNICATION MERGENCE FTTH             

1 is a block diagram showing an example of a conventional optical signal transmission system;

2 is a block diagram showing a preferred embodiment of the optical signal transmission system according to the present invention;

3 is a flowchart illustrating an optical signal transmission process in the OLT of FIG. 2 according to the present invention;

4 is a flowchart illustrating an optical signal transmission process in the ONU of FIG. 2 according to the present invention.

Explanation of symbols on the main parts of the drawings

120: digital broadcasting provider 140: analog broadcasting provider

160: Gigabit Ethernet provider 210: the first photosynthesis

220, 360: optical amplifier 230, 340: optical splitter

250: second photosynthesis machine 270, 320: coupler

420: digital broadcasting port 440: analog broadcasting port

460: Gigabit Ethernet Port

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical signal transmission system, and more particularly, to establish a transmission path of different types of optical signals between an optical line terminal (OLT) and an optical network unit (ONU) of a fiber to the home (FTTH). The present invention relates to an optical signal transmission system.

With the development of broadcasting and communication technology, there is a demand for a transmission system capable of providing a better transmission quality and transmission speed in transmitting an optical signal from a service provider to a subscriber. One of them is FTTH (Fiber To The Home). FTTH is a transmission system in which a transmission medium connected from a service provider (or head end) of a network to a subscriber is connected with an optical cable instead of a coaxial cable.

In a transmission system using an optical signal, a transmission system of a service provider is called an optical line terminal (OLT), and a transmission system of a service subscriber side that receives a service provided from the OLT and transmits the signal to an end subscriber after receiving a signal from the optical network unit (ONU) ). Such a transmission system generally has a structure in which a plurality of ONUs are connected to one OLT. The ONU provides services at the request of subscribers. Such a transmission system is called an active optical network.

Here, ONU, which is a transmission system of a service subscriber, is an end device of an optical communication network that provides a service interface to end users. The ONU accommodates Fiber To The Curb (FTTC), Fiber To The Building (FTTB), Fiber To The Floor (FTTF), Fiber To The Home (FTTH), and Fiber To The Office (FTTO). Accordingly, ONU implements high service accessibility to subscribers. ONU is connected to the subscriber and the cable for transmitting the analog signal transmitted from the subscriber and the OLT is connected to the optical facilities for transmitting and receiving optical signals to perform the function. Accordingly, the ONU performs photoelectric conversion for converting the optical signal transmitted from the OLT into an electrical signal and transmitting the signal to the subscriber, and all-optical conversion for converting the electrical signal transmitted from the subscriber into the optical signal and transmitting the optical signal to the OLT.

1 is a block diagram illustrating an example of a conventional optical signal transmission system. As shown, a method of serving broadcasting and communication to subscribers connected to the optical access node 22 is a hybrid fiber coaxial (HFC) network, each of which uses a different optical fiber for data and analog broadcasting signals for digital broadcasting. Transmission is common. That is, in the illustrated optical signal transmission system, the data signal is (dense) wavelength division multiplexed (Dense Wavelength Division Multiplex, hereinafter referred to as DWDM) and transmitted through one optical fiber, and the analog broadcast signal is transmitted through another optical fiber. .

Optical coaxial mixed networks, on the other hand, are communication networks in which optical fiber cables and coaxial cables are used in different parts of the network to transmit broadband content such as video, data, and voice. In general, for local cable television companies, fiber-optic cable is used to service nodes that are in close proximity to users in the enterprise or home from cable headends. Coaxial cables are also used to enter individual businesses or homes from nodes where fiber optic cables are used.

Hereinafter, the Dense Wavelength Division Multiplex (DWDM) will be described. First, Wavelength Division Multiplexing (WDM) will be described before describing DWDM. WDM refers to equipment that creates a virtual line by creating a separate frequency band in addition to the existing frequency in the optical fiber, and makes the same effect as installing a new cable network while using the existing network as it is.

Dense Wavelength Division Multiplexer (DWDM) refers to a device that divides and concentrates large-scale traffic such as 155M, 622M, 2.5G, 10G, and Gigabit data by wavelength using an existing transmission path. In other words, DWDM enables the transmission of multiple wavelengths over a single fiber. More precisely, broadcast data, Internet data, SONET data, and ATM data can all be transmitted simultaneously in the optical fiber.

As shown, a conventional optical signal transmission system optically transmits data signals for analog broadcasting and analog broadcasting signals from OLT to ONU using two different optical fibers. Therefore, there is a problem in that a transmission line of two different optical fibers is required in order to provide a subscriber with a conventional optical signal transmission system for digital broadcasting and analog broadcasting. Accordingly, when the conventional optical signal transmission system is constructed, there is a problem in that the cost of the system construction is high. In addition, when the transmission line is composed of two different optical fibers, there is a problem that the structure of the transmission line of the optical fiber laid from the OLT to ONU becomes complicated.

Hereinafter, a process of transmitting a data signal for digital broadcasting will be briefly described with reference to the accompanying drawings. The MUX 12 synthesizes data signals output from a plurality of DWDM Txs (32 in the figure). An Erbium Doped Fiber Amplifier (EDFA) 14 optically amplifies the data signal synthesized in the MUX 12. The optical amplification principle of the EDFA 14 doped a special material called erbium into the optical fiber and pumped with a laser to directly amplify the weak optical signal.

The amplified data signal is transmitted to the ONU, and the EDFA 16 of the ONU performs the same function as the EDFA 14 of the OLT. The DEMUX 18 classifies and outputs the data signal optically amplified by the EDFA 16 for each DWDM Tx.

The optical combination unit 20 combines the data signal outputted from the DEMUX 18, the optical signal transmitted from the OLT, and the analog broadcast signal AB outputted from the analog broadcast Tx transmitted through another optical fiber, respectively. Output to (22).

An object of the present invention for solving the above problems, when configuring a system for optical transmission of data communication and analog broadcast signal for digital broadcasting from OLT to ONU, optical signal transmission system that can be built at a lower cost And to provide an optical signal transmission method using the same.

Another object of the present invention, when configuring a system for optical transmission of data communication and analog broadcast signal for digital broadcasting from OLT to ONU, optical signal transmission system that can connect the OLT and ONU with a simpler structure and using the same An optical signal transmission method is provided.

According to the present invention, the above object is provided on the OLT side, and synthesizes different types of broadcast optical signals having different optical wavelengths, and distributes the synthesized broadcast synthesized optical signals in proportion to the number of ONUs connected to the OLT. An optical multiplex unit (OMU) for synthesizing each broadcast composite optical signal and a communication optical signal and transmitting the synthesized broadcast / communication composite optical signal to an ONU through one optical fiber; And an optical demultiplex unit (ODU) provided at the ONU side and classifying the broadcast / communication combined optical signal transmitted from the OMU according to the type of the signal.

Preferably, the OMU includes a first synthesizer for synthesizing a first broadcast optical signal and a second broadcast optical signal, which are heterogeneous broadcast optical signals having different wavelengths, into one signal, and the broadcast synthesized in the first optical synthesizer. A broadcast optical amplifier for amplifying a synthetic optical signal to a predetermined level, a broadcast optical splitter for distributing the broadcast optical amplifier amplified by the broadcast optical amplifier in proportion to the number of ONUs connected to the OLT, and each broadcast distributed in the broadcast optical splitter And a second optical synthesizer for synthesizing the synthesized optical signal and the communication optical signal into one signal, and a transmission coupler for transmitting the broadcast / communication synthesized optical signal synthesized by the second optical synthesizer to the ONU through one optical fiber.

Preferably, the ODU, in the receiving coupler, the receiving coupler for distinguishing the broadcast / communication composite optical signal transmitted and received from the transmission coupler of the OMU and the uplink optical signal for transmission to the OLT to transmit to each transmission path An optical splitter for dividing the divided and transmitted broadcast / communication optical signals by the type of signals and outputting the first broadcast optical signal and the communication optical signal to the subscribers among the divided optical signals, and the optical signals separated by the optical splitter Has an optical amplifier for optically amplifying and distributing the second broadcast optical signal in proportion to the number of subscribers subscribed to receive the service, and transmitting the optically amplified and optically distributed second broadcast optical signal to the subscriber. .

Preferably, the first broadcast optical signal is a digital broadcast optical signal having an optical wavelength of 1570 nm (λ ₁ ) provided from a digital broadcast provider. The second broadcast optical signal is an analog broadcast optical signal having an optical wavelength of 1530 nm (λ ₂ ) provided from an analog broadcast provider. The communication optical signal is a gigabit Ethernet optical signal having an optical wavelength of 1550 nm (λ ₃ ) provided from a gigabit Ethernet provider. The uplink optical signal is an optical signal having an optical wavelength of about 1300 nm for transmitting from a subscriber subscribed to receive a gigabit Ethernet service to a gigabit Ethernet provider. Accordingly, the reception coupler is preferably applied to the 1300/1550 WDM coupler.

On the other hand, according to the present invention, according to the present invention, a) OMU (Optical Multiplex Unit) provided on the OLT side of the ONU that synthesizes different types of broadcast optical signals having different optical wavelengths and synthesized broadcast synthesized optical signal to the OLT Distributing in proportion to the number, synthesizing each of the divided broadcast synthesized optical signals and the communication optical signals, and transmitting the synthesized broadcast / communication combined optical signals to the ONU through one optical fiber; And b) an optical demultiplex unit (ODU) arranged on the ONU side, classifying the broadcasting / communication composite optical signal transmitted from the OMU according to the type of signal and transmitting the classified optical signal to the subscribers subscribed to receive the corresponding service. It is achieved by an optical signal transmission method using an optical signal transmission system.

Preferably, the step a) comprises the steps of: synthesizing the first broadcast optical signal and the second broadcast optical signal, which are heterogeneous broadcast optical signals having different wavelengths, into one signal, wherein the broadcast amplifier comprises: Amplifying the broadcast synthesized optical signal synthesized by the photosynthesis to a predetermined level, distributing the broadcast synthesized optical signal amplified by the broadcast optical amplifier in a number proportional to the number of ONUs connected to the OLT, and second photosynthesis Synthesizing each of the broadcast composite optical signals and the communication optical signals distributed by the giga broadcast optical splitter into one signal, and the transmission coupler ONU through the single optical fiber by combining the broadcast / communication composite optical signals synthesized by the second optical synthesizer It is achieved by an optical signal transmission method using an optical signal transmission system comprising the step of transmitting to.

Preferably, the step b), the receiving coupler is transmitted from each transmission path by separating the broadcast / communication composite optical signal transmitted from the transmission coupler of the OMU and the uplink optical signal for transmission to the OLT, The optical splitter divides the broadcast / communication composite optical signal transmitted by being divided by the receiving coupler according to the type of the signal and outputs the first broadcast optical signal and the communication optical signal among the divided optical signals to the subscriber, and the optical amplifier. Amplified and distributed optically by a number proportional to the number of subscribers subscribed to receive the second broadcast optical signal from among the optical signals divided by the optical splitter. It is achieved by the optical signal transmission method using an optical signal transmission system comprising the step of transmitting to each subscriber.

According to the present invention, by combining a plurality of optical signals having different optical wavelengths into one signal and transmitting through one optical fiber, it can be configured cheaper and simpler when configuring the optical signal transmission system. In addition, the λ ₁ optical signal, which is a digital broadcast data signal, and the λ ₂ optical signal, which is an analog broadcast signal, are synthesized and distributed by the number of ONUs, and the λ ₁ , λ ₂ synthesized optical signal is synthesized with the λ ₃ optical signal, a gigabit Ethernet signal. By transmitting λ ₁ , λ ₂ , λ ₃ synthesized optical signal synthesized as one signal to ONU through one optical fiber, it is possible to reduce the cost of constructing optical signal transmission system and to establish the connection relationship between OLT and ONU. It is simple to design.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are represented by the same numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

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

As shown, the optical signal transmission system is divided into an OLT on the service provider side and an ONU on the service subscriber side.

The OLT is comprised of a digital broadcast provider 120, an analog broadcast provider 140, a gigabit Ethernet provider 160, and an optical multiplex unit (OMU) 200.

The digital broadcasting provider 120 provides a service subscriber who subscribes to receive digital broadcasting. The analog broadcast provider 140 provides a service subscriber who subscribes to receive analog broadcast. The gigabit ethernet provider 160 provides a service for communication to a gigabit ethernet subscriber subscribed to receive the communication service. The number of transmission and reception ports of the gigabit Ethernet signal output from the gigabit Ethernet provider 160 is set to the number of ONUs connected to the OLT. In the present embodiment, a case where there are 16 ONUs connected to the OLT will be described as an example.

The optical multiplex unit (OMU) 200 distributes digital broadcast data signals and analog broadcast signals transmitted from the digital broadcast provider 120 and the analog broadcast provider 140 by the number of ONUs connected to the OLT. In addition, the OMU 200 synthesizes each data signal and an analog signal distributed by the number of ONUs, and combines the Gigabit Ethernet signals transmitted from the Gigabit Ethernet provider 160 and transmits them to the ONU through one optical fiber.

Data signals of the digital broadcasting in the present embodiment is a light wavelength to 1570nm, the analog broadcast signal (λ ₁₎ is a light wavelength (λ ₂₎ 1530nm, 1550nm, and Gigabit Ethernet signal is used as a light wavelength (λ _3).

In more detail, the OMU 200 has a first photosynthesis 210, an optical amplifier 220, an optical splitter 230, a second photosynthesis 250, and a coupler 270.

The first photosynthesis unit 210 is a data signal (optical signal) having an optical wavelength of λ ₁ transmitted from the digital broadcasting provider 120 and an analog broadcast signal having an optical wavelength of λ ₂ transmitted from the analog broadcasting provider 140 (optical light). Signal). Here, the first photosynthesis 210 operates as a wavelength division multiplexer.

The optical amplifier 220 amplifies the lambda ₁ , lambda ₂ synthesized optical signal synthesized by the first photosynthesis 210 to a predetermined level in consideration of the power reduction of the optical signal by the optical splitter 230. Preferably, the optical amplifier 220 amplifies the λ ₁ , λ ₂ synthesized optical signal synthesized by the photosynthesis 210 by pumping the erbium-doped optical fiber with a laser.

The optical splitter 230 distributes the λ ₁ and λ ₂ composite optical signals amplified by the optical amplifier 220 by the number of ONUs connected to the OLT. In this embodiment, since 16 ONUs are connected to the OLT, the optical splitter 230 divides the amplified lambda ₁ and lambda ₂ composite optical signals into 16 identical signals.

The second photosynthesis unit 250 synthesizes the λ ₁ , λ ₂ synthesized optical signal distributed by the optical splitter 230 and a gigabit Ethernet optical signal having an optical wavelength λ ₃ transmitted from the gigabit Ethernet provider 160. In this case, since the second photosynthesis unit 250 has 16 λ ₁ and λ ₂ composite optical signals distributed by the optical splitter 230, 16 units having the same function are provided in the OMU. Here, the second photosynthesis unit 250 operates as a wavelength division multiplexer.

The coupler 270 transmits the λ ₁ , λ ₂ and λ ₃ synthesized optical signals synthesized by the second photosynthesis unit 250 to one ONU through one optical fiber connected to the ONU. In addition, the coupler 270 through the optical fiber when the optical signal received from the ONU λ _3, λ ₃ and transmits the received optical signal into a Gigabit Ethernet provider 160. The

Therefore, the λ ₁ optical signal, which is a digital broadcast data signal, and the λ ₂ optical signal, which is an analog broadcast signal, are synthesized and distributed to the number of ONUs, and the λ ₁ , λ ₂ synthesized optical signal is synthesized with the λ ₃ optical signal, which is a gigabit Ethernet signal. By transmitting λ ₁ , λ ₂ , λ ₃ synthesized optical signal synthesized as one signal to ONU through one optical fiber, it is possible to reduce the cost of constructing optical signal transmission system and to establish the connection relationship between OLT and ONU. It is simple to design.

The ONU includes an optical demultiplex unit (ODU) 300, a digital broadcast port 420, an analog broadcast port 440, and a gigabit Ethernet port port 460.

The ODU 300 distributes the λ ₁ , λ ₂ , λ ₃ composite optical signals transmitted from the OLT to service subscribers subscribing to the corresponding service, respectively. Accordingly, the digital broadcasting port 420 receives the λ ₁ optical signal provided from the ODU 300. The analog broadcast port 440 receives the λ ₂ optical signal provided from the ODU 300. The gigabit Ethernet port 460 receives the λ ₃ optical signal provided from the ODU 300 and transmits the corresponding gigabit Ethernet signal to the ODU 300. As such, each optical signal received at the digital broadcasting port 420, the analog broadcasting port 440, and the gigabit Ethernet port 460 is signal processed according to the respective signal characteristics, and each optical signal processed is signal processed. Is transmitted to the subscriber via one transmission line.

The ODU 300 includes a coupler 320, an optical splitter 340, and an optical amplifier 360 in more detail.

Coupler 320 is the λ _1, λ _2, λ ₃ Synthesis when optical signals are received, the received λ _1, λ _2, λ ₃ a composite optical signal optical splitter 340, transmitted from the coupler 270 of the OMU (200) To send. In addition, the coupler 320 transmits an uplink gigabit Ethernet signal transmitted from the gigabit Ethernet port 460 to the OLT through the optical fiber. In this case, the optical wavelength of the uplink Gigabit Ethernet signal is used in the 1300nm band. Accordingly, the coupler 320 is preferably applied to the 1300/1550 WDM coupler.

The optical splitter 340 divides the λ ₁ , λ ₂ and λ ₃ composite optical signals transmitted from the coupler 320 into λ ₁ optical signals, λ ₂ optical signals, and λ ₃ optical signals, respectively, according to the signal types. At this time, the optical splitter 340 transmits the λ ₁ optical signal to the digital broadcasting port 420 and the λ ₂ optical signal to the optical amplifier 360 among the λ ₁ optical signal, λ ₂ optical signal, and λ ₃ optical signal. , And λ ₃ optical signals are sent to the gigabit Ethernet port 460, respectively. Here, the optical splitter 340 operates as a wavelength division demultiplexer.

When the optical amplifier 360 receives a call of λ ₂ optical signal transmitted from the optical splitter 340, the received λ ₂ light signal proportional to the number of analog broadcast subscriber subscription service optical amplifier to the respective analog broadcasting port 440 To send.

On the other hand, the first photosynthesis 210 and the second photosynthesis 250 according to the present embodiment is preferably applied to the CWDM (Coarse Wavelength Division Multiplexer) MUX applied to the CWDM (Coarse Wavelength Division Multiplexing) method. In addition, the optical splitter 340 of the present embodiment is preferably a CWDM (Coarse Wavelength Division Multiplexer) DEMUX to which a CWDM (Coarse Wavelength Division Multiplexing) method is applied.

CWDM is the same concept as DWDM, but the spacing between WDM channels is relatively wide and low in cost as 20 nm. Laser diodes used in CWDM also do not need to take into account wavelength changes due to temperature changes, making it possible to use low-cost light sources. Accordingly, the optical signal transmission system of the present invention can be configured at a low cost in the system configuration.

3 is a flowchart illustrating an optical signal transmission process in the OLT of FIG. 2 according to the present invention.

First, the first photosynthesis unit 210 receives an optical signal having a λ ₁ optical wavelength, which is a digital broadcasting signal provided from the digital broadcasting provider 120, and an optical signal having a λ ₂ optical wavelength, which is an analog broadcasting signal provided from the analog broadcasting provider 140. Synthesize (S120). Here, the synthesis of the optical signal means wavelength division multiplexing.

The optical amplifier 220 amplifies the synthesized λ ₁ , λ ₂ synthesized optical signal (S140). The optical splitter 230 distributes the amplified λ ₁ and λ ₂ composite optical signals in a number proportional to the number of ONUs connected to the OLT (S160).

The second photosynthesis unit 250 synthesizes the distributed lambda ₁ , lambda ₂ synthesized optical signal and an optical signal having a lambda ₃ optical wavelength that is a gigabit Ethernet signal provided from the gigabit Ethernet provider 160 (S170). Here, the synthesis of the optical signal means wavelength division multiplexing. The coupler 270 transmits the synthesized λ ₁ , λ ₂ , λ ₃ synthesized optical signals to the ONU through one optical fiber (S190).

Therefore, by combining a plurality of optical signals having different optical wavelengths into a single signal and transmitting through one optical fiber, it is possible to configure the optical signal transmission system cheaper and simpler.

4 is a flowchart illustrating an optical signal transmission process in the ONU of FIG. 2 according to the present invention.

First, the coupler 320 when the λ _1, λ _2, λ ₃ composite optical signal received transmitted from the OLT coupler 270, received λ _1, λ _2, the λ ₃ composite optical signal and an uplink Gigabit Ethernet optical signal The output is divided to each transmission path (S220). That is, the coupler 320 is output to the λ _1, λ _2, λ ₃ Synthesis when optical signals are received, the received λ _1, λ _2, λ ₃ a composite optical signal optical splitter (340). In addition, when the uplink Gigabit Ethernet optical signal for transmission to the OLT is received, the coupler 320 transmits the received uplink Gigabit Ethernet optical signal to the OLT through the optical fiber.

The optical splitter 340 separately outputs λ ₁ , λ ₂ , and λ ₃ composite optical signals output from the coupler 320 according to the type of the signal (S240). That is, the optical splitter 340 generates a λ ₁ , λ ₂ , λ ₃ composite optical signal, a digital broadcasting optical signal having an optical wavelength of λ ₁ , an analog broadcasting optical signal having an optical wavelength of λ ₂ , and a gigabit having an optical wavelength of λ ₃ . Each output is divided into Ethernet optical signals. Here, it can be seen that the division of the optical signal means wavelength division inverse multiplexing.

On the other hand, the optical amplifier 360 optically amplifies the λ ₂ optical signal output from the optical splitter 340 in proportion to the number of analog broadcast subscribers (S260).

Therefore, it is possible to construct an optical signal transmission system capable of transmitting a digital broadcast signal, an analog broadcast signal, and a gigabit Ethernet signal from an OLT to an ONU through a single optical fiber.

According to the present invention, by combining a plurality of optical signals having different optical wavelengths into one signal and transmitting through one optical fiber, it can be configured cheaper and simpler when configuring the optical signal transmission system.

In addition, the λ ₁ optical signal, which is a digital broadcast data signal, and the λ ₂ optical signal, which is an analog broadcast signal, are synthesized and distributed by the number of ONUs, and the λ ₁ , λ ₂ synthesized optical signal is synthesized with the λ ₃ optical signal, a gigabit Ethernet signal. By transmitting λ ₁ , λ ₂ , λ ₃ synthesized optical signal synthesized as one signal to ONU through one optical fiber, it is possible to reduce the cost of constructing optical signal transmission system and to establish the connection relationship between OLT and ONU. It is simple to design.

In the above, specific preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiment, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention attached to the claims. will be.

Claims (22)

In the optical signal transmission system for transmitting a plurality of optical signals having different optical wavelengths between the optical line terminal (OLT) and the optical network unit (ONU) of the fiber to the home (FTTH), It is provided on the OLT side, and synthesizes different types of broadcast optical signals having different optical wavelengths and distributes the synthesized broadcast synthesized optical signals in proportion to the number of ONUs connected to the OLT, and communicates with each of the distributed broadcast synthesized optical signals. An optical multiplex unit (OMU) for synthesizing an optical signal and transmitting the synthesized broadcast / communication synthesized optical signal to the ONU through one optical fiber; And And an optical demultiplex unit (ODU) provided at the ONU side and classifying and outputting the broadcast / communication composite optical signal transmitted from the OMU according to the type of the signal. The method of claim 1, The OMU is, A first photosynthesis unit for synthesizing the first broadcast optical signal and the second broadcast optical signal, which are heterogeneous broadcast optical signals having different wavelengths, into one signal; A broadcast optical amplifier for amplifying the broadcast synthesized optical signal synthesized by the first photosynthesis to a predetermined level; A broadcast optical splitter for distributing the broadcast synthesized optical signal amplified by the broadcast optical amplifier in a number proportional to the number of the ONUs connected to the OLT; A second photosynthesizer for synthesizing each of the broadcast synthesized optical signals and the communication optical signals distributed by the broadcast optical splitter into one signal; And And a transmission coupler configured to transmit the broadcast / communication synthesized optical signal synthesized by the second optical synthesizer to the ONU through one optical fiber. The method of claim 2, The ODU, A reception coupler for distinguishing the broadcast / communication composite optical signal received from the transmission coupler of the OMU and an uplink optical signal for transmission to the OLT and transmitting the divided optical signal to each transmission path; An optical splitter for dividing the broadcast / communication combined optical signal transmitted by the receiving coupler into the first broadcast optical signal, the second broadcast optical signal, and the communication optical signal for each type of signal; And And an optical amplifier for optically amplifying and outputting the second broadcast optical signal among the optical signals output from the optical splitter in a number proportional to the number of subscribers subscribed to receive the service. And the optical signals output from the optical splitter and the optical amplifier are signal processed according to the set signal processing, and the optical signals processed by the optical splitter are transmitted to the corresponding subscriber through one transmission line. The method of claim 3, wherein And the first broadcast optical signal is a digital broadcast optical signal having an optical wavelength of λ ₁ provided from a digital broadcast provider. The method of claim 4, wherein The optical wavelength of λ ₁ is 1570nm band, characterized in that the optical signal transmission system. The method of claim 3, wherein And the second broadcast optical signal is an analog broadcast optical signal having an optical wavelength of λ ₂ provided from an analog broadcast provider. The method of claim 6, The optical wavelength of λ ₂ is 1530nm band, characterized in that the optical signal transmission system. The method of claim 3, wherein And said communication optical signal is a gigabit Ethernet optical signal having an optical wavelength of λ ₃ provided from a gigabit Ethernet provider. The method of claim 8, The optical wavelength of λ ₃ is 1550nm band, characterized in that the optical signal transmission system. The method of claim 9, The uplink optical signal is an optical signal having an optical wavelength of 1300nm band for transmitting from the subscriber subscribed to receive the Gigabit Ethernet service to the Gigabit Ethernet provider. The method of claim 10, And the receiving coupler is a 1300/1550 WDM coupler. In an optical signal transmission method using an optical signal transmission system for transmitting a plurality of optical signals having different optical wavelengths between an optical line terminal (OLT) and an optical network unit (ONU) of a fiber to the home (FTTH), a) an optical multiplex unit (OMU) provided on the OLT side synthesizes heterogeneous broadcast optical signals having different optical wavelengths, and distributes the synthesized broadcast synthesized optical signal in proportion to the number of ONUs connected to the OLT; Synthesizing each broadcast composite optical signal and a communication optical signal and transmitting the synthesized broadcast / communication optical signal to the ONU through one optical fiber; And b) the optical demultiplex unit (ODU) provided on the ONU side to separate and output the broadcast / communication composite optical signal transmitted from the OMU according to the type of the signal; Optical signal transmission method. The method of claim 12, Step a) is Synthesizing a first broadcast optical signal and a second broadcast optical signal, which are heterogeneous broadcast optical signals having different wavelengths, into a single signal by a first photosynthesis unit; Amplifying, by a broadcast amplifier, the broadcast synthesized optical signal synthesized by the first photosynthesis to a predetermined level; Distributing a broadcast synthesized optical signal amplified by the broadcast optical amplifier in a number proportional to the number of the ONUs connected to the OLT; Synthesizing each of the broadcast synthesized optical signals and the communication optical signal distributed by the broadcast optical splitter into one signal; And And transmitting, by the transmission coupler, the broadcast / communication composite optical signal synthesized by the second optical synthesizer to the ONU through one optical fiber. The method of claim 13, B), A receiving coupler for distinguishing the broadcast / communication composite optical signal transmitted from the transmission coupler of the OMU and an uplink optical signal for transmission to the OLT and transmitting them to respective transmission paths; An optical splitter for dividing and outputting the broadcast / communication combined optical signal transmitted by the receiving coupler into the first broadcast optical signal, the second broadcast optical signal, and the communication optical signal according to signal types; And Using an optical signal transmission system, wherein the optical amplifier amplifies the second broadcast optical signal among the optical signals classified by the optical splitter in a number proportional to the number of subscribers subscribed to receive the service. Optical signal transmission method. The method of claim 14, And the first broadcast optical signal is a digital broadcast optical signal having an optical wavelength of λ ₁ provided from a digital broadcast provider. The method of claim 15, The optical wavelength of λ ₁ is 1570nm band optical signal transmission method using an optical signal transmission system, characterized in that. The method of claim 14, The second broadcast optical signal is an analog broadcast optical signal having an optical wavelength of λ ₂ provided from an analog broadcast provider. The method of claim 17, The optical wavelength of λ ₂ is 1530nm band optical signal transmission method using an optical signal transmission system, characterized in that. The method of claim 14, And said communication optical signal is a gigabit Ethernet optical signal having an optical wavelength of λ ₃ provided from a gigabit Ethernet provider. The method of claim 19, The optical wavelength of λ ₃ is 1550nm band optical signal transmission method using an optical signal transmission system, characterized in that. The method of claim 20, The uplink optical signal is an optical signal transmission system using an optical signal transmission system, characterized in that the optical signal having a wavelength of 1300nm band for transmitting from the subscriber subscribed to receive the gigabit Ethernet service to the gigabit Ethernet provider. The method of claim 14, The receiving coupler is an optical signal transmission method using an optical signal transmission system, characterized in that 1300/1550 WDM coupler.

Images