KR100990780B1 - Wavelength division multiplexing - passive optical network system - Google Patents

Abstract

The present invention multiplexes and splits optical power of a plurality of wavelengths of a constant intensity at a telephone station to supply subscribers with a wavelength division multiplexing passive optical subscriber network (WDM-PON: Wavelength). Division Multiplexing-Passive Optical Network) system.

A passive optical subscriber network system of a wavelength division multiplexing system according to the present invention comprises: a plurality of uplink signal laser diodes for supplying a uplink signal laser light source; A first multiplexer / demultiplexer for wavelength division multiplexing the laser light sources supplied from the plurality of uplink signal laser diodes; A first optical splitter which splits the wavelength division multiplexed uplink laser light source into optical power and transmits the plurality of light beams to each of the terminal devices; A plurality of light beam termination devices for transmitting an uplink signal light source using the light power branched light source, and receiving an uplink optical signal and converting the light signal into an electrical signal; A plurality of light emitting subscriber apparatuses for converting and transmitting the uplink light source into an uplink optical signal; And splitting the uplink signal light source transmitted from the optical fiber termination device for each subscriber and transmitting the optical signal for each subscriber to the optical fiber subscriber terminal, or by performing wavelength division multiplexing of the optical signal for each subscriber transmitted from the optical fiber subscriber device to the optical fiber terminal device. Transmitting multiplexing / demultiplexing means.

Description

Wavelength division multiplexing-passive optical network system

1 is a block diagram of a conventional WDM-PON system.

2 is a block diagram of a first embodiment according to the present invention.

3 is a view showing an example of an optical amplifier used in the present invention.

4 is a block diagram of a second embodiment according to the present invention.

5 is a configuration diagram of a third embodiment according to the present invention.

Figure 6 is a block diagram of a fourth embodiment according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wavelength division multiplexing passive optical network (WDM-PON) system. More specifically, multiplexing and optical power multiplexing laser light of a constant intensity at a telephone station The present invention relates to a passive optical subscriber network system of a wavelength division multiplexing scheme in which multiple subscribers share a light source of the same wavelength by branching and supplying the subscriber to the subscriber.                         

Interest in the so-called WDM-PON, which directly connects the optical fiber to subscribers, is increasing to provide various broadband multimedia services that are rapidly increasing in the information society. WDM-PON connects the optical line terminal (OLT) and optical subscriber unit (ONU: Optical Network Unit) of the central office, a telecommunications service provider, with passive optical elements and multiplexed text and audio. It is a network that distributes / transmits video data to optical signals and distributes them to each ONU. WDM-PON not only provides a large amount of information to subscribers, but also provides excellent security and easy performance.

1 is a block diagram schematically showing the configuration of a conventional WDM-PON system.

As shown in the related art, the conventional WDM-PON system provides a WDM multiplexer / demultiplexer which is provided at a local base station (Remote node) at a subscriber station when a telephone station provides a constant intensity light source (∑λ _is ) of a different wavelength for each subscriber. In the following (hereinafter referred to as WDM MD), each subscriber transmits the wavelength to the ONU. The light source λ _is transmitted by separating the wavelength is incident on the reflective optical amplifier of the ONU and modulated by amplifying or absorbing light according to the input current of the optical amplifier. The modulated subscriber optical signal λ _im is multiplexed in the WDM MD (∑ _im ) and transmitted to the telephone station.

However, such a conventional WDM-PON system does not use a constant intensity of light, but uses a signal light that contains a signal, so that multiple subscribers cannot use a light source having the same wavelength. Therefore, the wavelengths of the light source and the optical signal between the telephone station and the ONU are different for each subscriber, and in an optical subscriber network that needs to accommodate a large number of subscribers, the implementation of such a system requires a lot of resources and is economically expensive.

In order to solve this problem, an object of the present invention is to allow multiple subscribers to share a light source in a WDM-PON system by multiplexing and providing optical power by splitting laser light having a plurality of wavelengths of a constant intensity.

To this end, the passive optical subscriber network system of the wavelength division multiplexing method according to the present invention, a plurality of uplink signal laser diode for supplying the uplink signal laser light source; A first multiplexer / demultiplexer for wavelength division multiplexing the laser light sources supplied from the plurality of uplink signal laser diodes; A first optical splitter which splits the wavelength division multiplexed uplink laser light source into optical power and transmits the plurality of light beams to each of the terminal devices; A plurality of light beam termination devices for transmitting an uplink signal light source using the light power branched light source, and receiving an uplink optical signal and converting the light signal into an electrical signal; A plurality of light emitting subscriber apparatuses for converting and transmitting the uplink light source into an uplink optical signal; And splitting the uplink signal light source transmitted from the optical fiber termination device for each subscriber and transmitting the optical signal for each subscriber to the optical fiber subscriber terminal, or by performing wavelength division multiplexing of the optical signal for each subscriber transmitted from the optical fiber subscriber device to the optical fiber terminal device. Transmitting multiplexing / demultiplexing means.

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

The present invention is characterized by implementing a WDM-PON system by combining a laser diode (LD), a WDM MD, an optical splitter, a photodiode (PD), an optical circulator, and an optical amplifier. And the detailed description of this configuration will be described below with an emphasis on the flow of the signal. First, the first embodiment will be described with reference to FIG. 2.

According to the first embodiment of the present invention, WDM MD1 performs wavelength division multiplexing on a light source λ _ius corresponding to the wavelength of i subscriber supplied from LD1 and another light source for subscriber. The light source is supplied from a single mode LD such as a DFB LD (Distributed FeedBack Laser Diode), and the light source λ _ius is a light source for an uplink signal transmitted from the ONU1 to the telephone station.

The light source Σλ _ius for wavelength division multiplexing in WDM MD1 is branched by optical power in 1 × n optical splitter 1 and supplied to respective OLT 1 to OLT n. Here, the description will be made using OLT j1 which is one of the respective OLTs.

The uplink light source Σλ _ius of each subscriber supplied to the OLT j1 is transmitted to the WDM MD3 of the subscriber via the optical circulator OC1. The uplink signal source Σλ _ius is separated for each subscriber in WDM MD3 and transmitted as λ _ius to the subscriber's ONU1.

The upward signal light source λ _ius transmitted to the ONU1 is transmitted to the optical amplifier 1 included in the ONU1 and converted into an upward optical signal λ _ium having the same wavelength as the upward signal light source λ _ius . Here, the optical amplifier 1 is a reflective semiconductor optical amplifier.

The operation of the optical amplifier 1 will be described in detail with reference to FIG. 3.                     

The light source λ _ius incident on the active waveguide 4 of the optical amplifier 1 through the optical waveguide 2 is reflected by the high reflection coating film 6 and is again output through the active waveguide 4 to the optical waveguide 2. The incident light source λ _ius is amplified according to the signal current (not shown) input to the substrate 8 while traveling along the active waveguide 4. That is, since the upstream optical signal λ _ium reflected and outputted radiates the signal current, the optical amplifier 1 converts the electric signal into an upstream optical signal λ _ium having the same wavelength as the incident upstream light source λ _ius . .

On the other hand, as described above, the uplink optical signal λ _ium generated in the optical amplifier 1 is transmitted to the WDM MD3 through the optical path through which the uplink signal source λ _ius is transmitted, and the WDM MD3 is wavelength-division multiplexed with the uplink optical signals of other subscribers. Sent to OLT j1

The wavelength division multiplexed uplink optical signal Σλ _ium is input to port 2 of the optical circulator OC1 and output to port 3. The output upward optical signal Σλ _ium is separated from each subscriber in WDM MD2 and then incident on PD1 to be converted into an electrical signal.

As described above, according to the first embodiment of the present invention, wavelength division multiplexing and branching of a single mode laser light source having a wavelength assigned to each subscriber are performed by multiple systems, and the wavelength of the optical signal transmitted from the ONU It is determined by the light source to supply.

4 shows a second embodiment of the WDM-PON system according to the present invention, and shows a configuration of a system for simultaneously transmitting a downlink optical signal transmitted from a telephone station to an ONU and an uplink optical signal transmitted from an ONU to a telephone station.

According to the second embodiment of the present invention, WDM MD4 performs wavelength division multiplexing on a light source λ _ius corresponding to the wavelength of i subscriber supplied from LD2 and another light source for subscriber. Here, the light source is supplied from a single mode LD such as DFB LD, and the light source λ _ius is a light source for uplink signal transmitted from ONU2 to the telephone station.

The light source Σλ _ius for wavelength division multiplexing in WDM MD4 is optical power branched at 1 × n optical splitter 2 and supplied to each OLT 1 to OLT n. Here, the description will be made using OLT j2, which is one of the respective OLTs.

The uplink light source Σλ _ius of each subscriber supplied to the OLT j2 is incident to the WDM MD8 via the optical circulator OC2 and is wavelength division multiplexed with the downlink optical signal Σλ _{idm which} will be described later. The WDM MD8 performs wavelength division multiplexing on the uplink light source and the downlink optical signal to be described later.

The downlink optical signal Σλ _{idm to} be described later in WDM MD8 and the multiplexed uplink light source Σλ _ius are transmitted to the WDM MD9 on the subscriber side through the optical path. The transmitted uplink signal source Σλ _ius is separated for each subscriber in WDM MD9 and transmitted to the subscriber's ONU2 as λ _ius . At this time, it is preferable that the uplink light source λ _ius of i subscriber and the downlink optical signal λ _idm to be described later are separated into the same output port.

The uplink light source λ _ius transmitted to ONU2 is transmitted to optical amplifier 3 separately from the downlink optical signal λ _{idm which} will be described later by WDM MD10 in ONU2. Optical amplifier 3 generates an upward optical signal λ _ium as described in FIG. 3.

The uplink optical signal λ _ium generated by the optical amplifier 3 is transmitted to the WDM MD9 through the WDM MD10, and is wavelength-division multiplexed with the uplink optical signals of other subscribers by the WDM MD10 to the OLT j2 of the telephone station.

The wavelength division multiplexed uplink optical signal Σλ _ium is input to port 2 of the optical circulator OC2 through WDM MD8 and output to port 3. The output upward optical signal Σλ _ium is separated for each subscriber in WDM MD5 and then incident on PD2 as λ _ium and converted into an electrical signal.

Meanwhile, according to the second embodiment of the present invention, the downlink light source λ _ids of i subscriber is wavelength division multiplexed in WDM MD6 together with the downlink light source of another subscriber. The light source Σλ _ids for the wavelength division multiplexed downlink signal is split by optical power in the 1 × n optical splitter 3 and then transmitted to the WDM MD7 through the optical circulator OC3. At this time, the wavelength of the downlink signal light source λ _ids is determined such that the uplink signal light source λ _ius of i subscriber and the downlink optical signal λ _idm to be described later are separated into the same output port.

The wavelength-division multiplexed downlink light source Σλ _ids is separated into the light source λ _ids of i subscriber at WDM MD7 and transmitted to optical amplifier 2. Then, the optical amplifier 2 generates the downlink optical signal lambda _idm as described in FIG. 3 and transmits it to the WDM MD7. The WDM MD7 multiplexes the downlink optical signal lambda _idm with the downlink optical signal of another subscriber.

The wavelength division multiplexed downlink optical signal Σλ _idm is incident on the WDM MD8 through the optical circulator OC3 and is wavelength division multiplexed with the above-mentioned upstream signal light source Σλ _ius and then transmitted to the subscriber side WDM MD9.

The WDM MD9 separates the transmitted downlink optical signal Σλ _idm for each subscriber and transmits it to the subscriber's ONU2 as λ _idm .

The downlink optical signal [lambda] _idm transmitted to ONU2 is separated from the above-mentioned upstream signal light source [lambda] _ius by WDM MD10 in ONU2 and transmitted to PD3 to be converted into an electrical signal.

As described above, the second embodiment according to the present invention further includes a configuration for transmitting a downlink light source and a downlink optical signal without changing the configuration of the uplink light source and the uplink optical signal in the first embodiment. It features.

As described above, the second embodiment of the present invention uses two WDM MDs (WDM MD5 and WDM MD7) for multiplexing or demultiplexing optical signals and light sources for each subscriber in the OLT. As a third embodiment, a configuration of a WDM-PON system using one WDM MD (WDM MD14) for multiplexing or demultiplexing an optical signal and a light source for each subscriber is shown. In this third embodiment, the wavelengths for the downlink light source, the downlink light signal, the uplink light source, and the uplink optical signal are determined to be separated into the same port for the same subscriber when separated from the WDM MD14 and the WDM MD17 which will be described later.

According to the third embodiment of the present invention, the WDM MD11 performs wavelength division multiplexing on a light source λ _ius corresponding to the wavelength of i subscriber supplied from LD4 and another light source for subscriber. Here, the light source is supplied from a single mode LD such as DFB LD, and the light source λ _ius is a light source for an uplink signal transmitted from the ONU3 to the telephone station.

The light source Σλ _ius for wavelength division multiplexing in WDM MD11 is optical power branched at 1 × n optical splitter 4 and supplied to each OLT 1 to OLT n. Here, the description will be made using OLT j3, which is one of the respective OLTs.

The uplink light source Σλ _ius of each subscriber supplied to the OLT j3 is incident to the WDM MD16 via the optical circulator OC4 and is wavelength division multiplexed with the downlink optical signal Σλ _{idm which} will be described later. The WDM MD16 performs wavelength division multiplexing on the uplink light source and the downlink optical signal to be described later.

The downlink optical signal Σλ _{idm to} be described later in WDM MD16 and the multiplexed uplink light source Σλ _ius are transmitted to the WDM MD17 on the subscriber side via the optical path. The transmitted uplink signal source Σλ _ius is separated for each subscriber in WDM MD17 and transmitted to subscriber ONU3 as λ _ius . At this time, the uplink light source λ _ius of i subscriber and the downlink optical signal λ _idm to be described later are separated into the same output port.

The uplink light source λ _ius transmitted to ONU3 is transmitted to optical amplifier 5 separately from the downlink optical signal λ _{idm which} will be described later by WDM MD18 in ONU3. The optical amplifier 5 generates the uplink optical signal λ _ium as described with reference to FIG. 3.

The uplink optical signal λ _ium generated by the optical amplifier 5 is transmitted to the WDM MD17 through the WDM MD18, and is wavelength-division multiplexed with the uplink optical signals of other subscribers by the WDM MD17 to the OLT j3 of the telephone station.

The uplink optical signal Σλ _ium transmitted to OLT j3 by wavelength division multiplexing is transmitted to port 2 of the optical circulator OC4 via WDM MD16 and output to port 3. The output uplink optical signal Σλ _ium is wavelength-division multiplexed with the downlink light source Σλ _{ids which} will be described later in WDM MD15 and transmitted to port 2 of the WDM MD14.

The WDM MD14 separates the input uplink optical signal Σλ _ium and the downlink light source Σλ _ids to be described later for each subscriber, so that the uplink optical signal λ _ium for the same subscriber and the downlink light source λ _ids are the same port (here port 1). ) The upstream optical signals λ _ium output as λ _ids downstream signal light source which will be described later in the WDM MD14 is then isolated from the λ _ids downstream signal light source which will be described later in the WDM MD13 is transmitted to PD4 is converted to an electrical signal.

Meanwhile, according to the third embodiment, the downlink light source λ _ids supplied from LD5 is wavelength-division multiplexed in the downlink light source of another subscriber with WDM MD12 and optical power is branched in the 1 × n optical splitter 5, followed by the optical circulator OC5. Is sent to the WDM MD15.

The WDM MD15 transmits the WDM MD14 by wavelength division multiplexing the transmitted downlink light source Σλ _ids with the above-described uplink optical signal Σλ _ium .

As described above, the WDM MD14 classifies and outputs the uplink optical signal λ _ium and the downlink light source λ _ids for each subscriber to the same port (here, port 1). The downstream signal light source output, such as upstream optical signals from the WDM MD14 λ λ _{ium ids} are then sent to a separation and upstream optical signals λ _ium WDM MD13 in the optical amplifier 4. The optical amplifier 4 generates and outputs a downlink optical signal λ _idm as described with reference to FIG. 3.

The downlink optical signal λ _idm generated by the optical amplifier 4 is wavelength-division multiplexed with the downlink optical signal of another subscriber via the WDM MD13 through the WDM MD13, and is transmitted to the WDM MD16 via the WDM MD15 and the optical circulator OC5.

The downlink optical signal Σλ _idm transmitted to the WDM MD16 is wavelength-division multiplexed with the above-described light source Σλ _ius for the upstream signal and transmitted to the WDM MD17 on the subscriber side through the optical path.

The WDM MD17 separates the input downlink optical signal Σλ _idm and the above-mentioned upstream signal light source Σλ _ius into the same port for each subscriber. The downstream optical signals λ _idm separated by each subscriber is after transferred to ONU3 with λ _ius upward signal light source the above-described separation and the upward signal light λ _ius described in the WDM MD18 is transmitted to PD5 are converted into electrical signals.

As described above, the WDM MD13, WMD MD15, WDM MD16, and WDM MD18 according to the third embodiment perform a function of wavelength division multiplexing or demultiplexing the downlink light source or the downlink optical signal with the uplink signal source or the uplink optical signal. WDM MD14 and WDM MD17 multiplex or demultiplex the light source or optical signal for each subscriber.

6 is a configuration diagram of a WDM-PON system according to a fourth embodiment of the present invention.

According to the fourth embodiment of the present invention, the uplink light source λ _ius for supplying to the ONU from the telephone station is optically powered in the 1 × n optical splitter 6 so as to be shared by various systems. The upstream signal source uses DFB LD as a single mode LD of a constant size.

The uplink light source λ _ius for the i subscriber with optical power branching from 1 × n optical splitter 6 to 1 / n is wavelength-division multiplexed with the downlink optical signal λ _idm , which will be described later in WDM MD19, thereby providing a bidirectional arrayed waveguide grating. (I.e. port 4 here) of the BD AWG. The bidirectional waveguide diffraction grating (BD AWG) is a type of WDM MD, and multiplexes multiple wavelengths inputted to different ports and outputs them to one port, or separates multiplexed wavelengths inputted to one port. Outputs to the port.

The uplink signal light source λ _ius transmitted to the bidirectional waveguide diffraction grating (BD AWG) is wavelength-division multiplexed with the uplink signal source of another subscriber and output.

The wavelength division multiplexed uplink signal Σλ _ius is transmitted to the WDM MD20 and separated from the downlink optical signal Σλ _{idm which} will be described later, and then transmitted to the WDM MD22 through the optical circulator OC7.

The uplink light source Σλ _ius transmitted to the WDM MD22 is transmitted to the waveguide diffraction grating (AWG) on the subscriber side, separated by subscriber, and output to port 2 as λ _ius and transmitted to the ONU.

The uplink light source λ _ius transmitted to the ONU is input to port 1 of the WDM MD24 in the ONU, separated from the downlink optical signal λ _idm to be described later, and output to port 2. The uplink light source λ _ius outputted through port 2 of the WDM MD24 is transmitted to the optical amplifier 7 and converted into the uplink optical signal λ _ium .

The uplink optical signal λ _ium generated as described above is inputted to port 2 of the waveguide diffraction grating (AWG) via WDM MD24, and is wavelength-division multiplexed with the uplink optical signal of another subscriber input to the other port and outputted to port 1 do.

The uplink optical signal, Σλ _ium, from multiple subscribers with wavelength division multiplexing is transmitted to the OLT located at the telephone station, and then through the WDM MD22 and the optical circulator (OC7) and WDM MD21 in the OLT to the third waveguide diffraction grating (BD AWG). It is input to the port, and is separated by the wavelength of each subscriber and output to port 1 as λ _ium .

The uplink optical signal λ _ium output to port 1 of the bidirectional waveguide diffraction grating (BD AWG) is transmitted to PD6 via WDM MD23 and converted to an electrical signal at PD6. The WDM MD23 wavelength division multiplexes or demultiplexes the uplink optical signal λ _ium and the downlink light source λ _ids to be described later.

On the other hand, the downlink light source λ _ids supplied from the DFB LD2 is optically branched by the 1 × n optical splitter 7 and transmitted to the WDM MD23. As described above, the WDM MD23 performs wavelength division multiplexing or demultiplexing of the uplink optical signal λ _ium and the downlink light source λ _ids .

The downlink light source λ _ids outputted from the WDM MD23 is inputted to port 1 of the bidirectional waveguide diffraction grating (BD AWG), and is wavelength-division multiplexed with the other subscriber's downlink signal source inputted to another port and outputted to port 3.

Downstream signal light source a wavelength division multiplexed WDM MD21 is Σλ _ids and Guangxi particulate concentrator (OC6) and is input to a port 2 of the two-way waveguide grating (AWG BD) through the WDM MD20 is separated for each subscriber light source λ _ids Output to port 4.

The downlink light source λ _ids of each subscriber, which is output to port 4 of the bidirectional waveguide diffraction grating (BD AWG), is transmitted to the WDM MD19.

The downlink light source [lambda] _ids output from the WDM MD19 is converted into the downlink optical signal [lambda] _idm as described with reference to FIG.

The downlink optical signal λ _idm generated as described above is incident on the WDM MD19 and output by wavelength division multiplexing with the above-described light source λ _ius for the upstream signal, which is inputted to port 4 of the bidirectional waveguide diffraction grating (BD AWG) and is then outputted. Wavelength division multiplexed with the downlink optical signal of another subscriber inputted to the port and outputted to port 2 as Σλ _idm .

The wavelength division multiplexed downlink optical signal Σλ _idm is separated from the upward signal light source Σλ _ius described above by the WDM MD20, and then multiplexed with the uplink signal source Σλ _ius again described in the WDM MD22 via the optical circulator OC6. It is transmitted to the waveguide diffraction grating (AWG) on the side, and is separated for each subscriber and output to port 2 as λ _idm and transmitted to the ONU.

The downlink optical signal λ _idm transmitted to the ONU is input to port 1 of the WDM MD24 in the ONU, and is separated from the above-described light source λ _ius for the upstream signal and output to the port 1. The downlink optical signal λ _idm outputted to port 1 of WDM MD24 is transmitted to PD7 and converted into an electrical signal.

As described above, the fourth embodiment does not sequentially include the WDM MD and the optical splitter at the rear end of the DFB LD as in the first to third embodiments, but has a specific optical splitter at the rear end of the DFB LD. It is characterized in that multiple subscribers can share and use a single laser by optical power branching a signal light source for which a wavelength is allocated for the subscriber.

As in the first to fourth embodiments described above, the present invention is characterized by wavelength division multiplexing a single mode laser light source of a wavelength assigned to each subscriber and splitting the optical power into multiple systems.

As described above, the present invention has the effect of wavelength division multiplexing a single mode laser light source having a wavelength assigned to each subscriber and splitting the optical power to share the multiple systems to reduce resources and costs required for system construction.

In addition, the present invention also provides convenience of management in which the wavelength of the optical signal transmitted from the ONU is determined by the light source supplied from the telephone station.

Claims (16)

delete A plurality of uplink signal laser diodes for supplying uplink signal laser light sources; A first multiplexer / demultiplexer for wavelength division multiplexing the laser light sources supplied from the plurality of uplink signal laser diodes; A first optical splitter which splits the wavelength division multiplexed uplink laser light source into optical power and transmits the plurality of light beams to each of the terminal devices; A plurality of light beam termination devices for transmitting an uplink signal light source using the light power branched light source, and receiving an uplink optical signal and converting the light signal into an electrical signal; A plurality of light emitting subscriber apparatuses for converting and transmitting the uplink light source into an uplink optical signal; And The light source for the uplink signal transmitted from the optical fiber terminator is separated for each subscriber and transmitted to the subscriber device via the optical beam, or the optical signal for each subscriber transmitted from the optical fiber subscriber device is transmitted to the optical fiber terminator by wavelength division multiplexing. Multiplexing / demultiplexing means Passive optical subscriber network system of the wavelength division multiplexing method comprising a. The method of claim 2, The optical fiber terminal device, A second multiplexer / demultiplexer for separating the wavelength division multiplexed uplink optical signal for each subscriber; A plurality of first photodiodes for converting the uplink optical signal separated for each subscriber in the second multiplexer / demultiplexer into the electrical signal; And Transmitting the uplink signal light source transmitted from the first optical splitter to the multiplexing / demultiplexing means, and transmitting the wavelength division multiplexed uplink optical signal transmitted from the multiplexing / demultiplexing means to the second multiplexing / demultiplexer A passive optical subscriber network system of wavelength division multiplexing, comprising a first optical circulator. The method of claim 3, wherein The optical subscriber unit, And a first optical amplifier for converting the uplink signal light source separated for each subscriber transmitted from the multiplexing / demultiplexing means into the uplink optical signal and transmitting the uplink optical signal to the multiplexing / demultiplexing means. Passive optical subscriber network system of wavelength division multiplexing. The method of claim 2, Means for providing a downward signal light source for providing a downward signal light source Passive optical subscriber network system of the wavelength division multiplexing method further comprising. The method of claim 5, The optical fiber terminal device, And a wavelength division multiplexing signal of the uplink signal light source and the downlink optical signal generated from the downlink signal light source to be transmitted to the multiplexing / demultiplexing means. The method of claim 6, The multiplexing / demultiplexing means, Passive optical subscriber network system of the wavelength division multiplexing method characterized in that the downlink optical signal transmitted from the optical fiber terminating device is separated for each subscriber and transmitted to the subscriber optical device. The method of claim 7, wherein The optical subscriber unit, A third multiplexer / demultiplexer for separating and transmitting the uplink signal light source and the downlink optical signal separately for each subscriber transmitted from the multiplexing / demultiplexing means; A second optical amplifier converting the uplink signal light source transmitted from the third multiplexer / demultiplexer into the uplink optical signal according to the input signal current and transmitting the converted uplink optical signal to the third multiplexer / demultiplexer; And And a second photodiode for converting the downlink optical signal transmitted from the third multiplexer / demultiplexer into an electrical signal. The method of claim 8, The optical fiber terminal device, A fourth multiplexer / demultiplexer for wavelength division multiplexing the uplink light source and the downlink optical signal to provide to the multiplexing / demultiplexing means and transmitting the wavelength division multiplexing uplink optical signal transmitted from the multiplexing / demultiplexing means ; A fifth multiplexer / demultiplexer for separating the wavelength division multiplexed uplink optical signal for each subscriber; A plurality of third photodiodes for converting an uplink optical signal separated for each subscriber into the electrical signal in the fifth multiplexer / demultiplexer; A second optical circulator for transmitting the uplink signal light source to the fourth multiplexer / demultiplexer and transmitting the wavelength division multiplexed uplink optical signal received from the fourth multiplexer / demultiplexer to the fifth multiplexer / demultiplexer ; A sixth multiplexer / demultiplexer for separating and transmitting the downlink signal light source for each subscriber or for performing wavelength division multiplexing of the downlink optical signal for each subscriber; A third optical amplifier converting the downlink light source transmitted from the sixth multiplexer / demultiplexer into the downlink optical signal according to an input signal current and transmitting the converted downlink optical signal to the sixth multiplexer / demultiplexer; And The downlink signal source transmitted from the downlink signal source providing means is transmitted to the sixth multiplexer / demultiplexer, and the wavelength division multiplexed downlink optical signal transmitted from the sixth multiplexer / demultiplexer is the fourth multiplexer / demultiplexer. Passive optical subscriber network system of the wavelength division multiplexing method comprising a third optical circulator for transmitting to the device. The method of claim 8, The optical fiber terminal device, A seventh multiplexer / demultiplexer for wavelength division multiplexing the uplink light source and the downlink optical signal to provide to the multiplexing / demultiplexing means and transmitting the wavelength division multiplexing uplink optical signal transmitted from the multiplexing / demultiplexing means ; A fourth optical circulator for transmitting the uplink signal light source to the seventh multiplexer / demultiplexer and transmitting the wavelength division multiplexed uplink optical signal received from the seventh multiplexer / demultiplexer; A fifth optical circulator for transmitting the downlink light source transmitted from the downlink light source providing means and transmitting the wavelength division multiplexed downlink optical signal to the seventh multiplexer / demultiplexer; The wavelength division multiplexed uplink optical signal transmitted from the fourth optical circulator and the downlink light source transmitted from the fifth optical circulator are transmitted by wavelength division multiplexing, and the wavelength division multiplexed downlink optical signal is transmitted. An eighth multiplexer / demultiplexer for transmitting to a 5 optical circulator; A ninth multiplexer / demultiplexer for separating the wavelength-division multiplexed uplink optical signal and the downlink light source for each subscriber, and performing wavelength division multiplexing of the downlink optical signal for each subscriber to the eighth multiplexer / demultiplexer; A tenth multiplexer / demultiplexer for separately transmitting the downlink light source and the uplink optical signal separated by subscribers in the ninth multiplexer / demultiplexer; A fourth optical amplifier converting the downlink light source transmitted from the tenth multiplexer / demultiplexer into the downlink optical signal according to an input signal current and transmitting the converted downlink optical signal to the tenth multiplexer / demultiplexer; And And a fourth photodiode for converting the uplink optical signal transmitted from the tenth multiplexer / demultiplexer into an electrical signal. delete A first DFB laser diode for supplying an upward signal laser light source; A first optical splitter that splits the upstream signal laser light source into optical power and transmits the optical signal to each of a plurality of light beam termination devices; A second DFB laser diode for supplying a downlink signal laser light source; A second optical splitter that optically splits the downlink signal laser light source and transmits the optical signals to the plurality of light beam termination devices; A plurality of optical fiber termination devices for wavelength division multiplexing and transmitting the optical power branched uplink light source and the downlink optical signal generated from the downlink signal light source, and receiving and converting the uplink optical signal into an electrical signal; A plurality of light emitting subscriber apparatuses for converting and transmitting the uplink light source into an uplink optical signal; And The uplink signal light source and the downlink optical signal transmitted from the optical fiber termination device are separated for each subscriber and transmitted to the optical subscriber network, and the optical signal for each subscriber is transmitted by the wavelength division multiplexing. Means for multiplexing / demultiplexing to the network end devices Passive optical subscriber network system of the wavelength division multiplexing method comprising a. 13. The method of claim 12, The optical subscriber unit, A first multiplexer / demultiplexer for separately transmitting the uplink signal laser light source and the downlink optical signal, which are separated for each subscriber transmitted from the multiplexing / demultiplexing means; A first optical amplifier converting the uplink signal light source transmitted from the first multiplexer / demultiplexer into the uplink optical signal according to an input signal current and transmitting the converted uplink optical signal to the first multiplexer / demultiplexer; And And a first photodiode for converting the downlink optical signal transmitted from the first multiplexer / demultiplexer into an electrical signal. The method of claim 13, The optical fiber terminal device, A second optical amplifier converting the downlink light source into a downlink optical signal according to an input signal current; A second multiplexer / demultiplexer configured to perform wavelength division multiplexing on the uplink signal laser light source transmitted from the first optical splitter and the downlink optical signal transmitted from the second optical amplifier; A third multiplexer / demultiplexer for transmitting the downlink laser light source and the uplink optical signal transmitted from the second optical splitter; A second photodiode converting the uplink optical signal transmitted from the third multiplexer / demultiplexer into an electrical signal; The wavelength division multiplexing of the uplink signal laser light source transmitted from the second multiplexer / demultiplexer and the downlink optical signal and the downlink signal laser light source transmitted from the third multiplexer / demultiplexer is performed by wavelength division multiplexing. A fourth multiplexer / demultiplexer for separating and transmitting an optical signal and the downlink light source for each subscriber; A fifth multiplexer / demultiplexer which transmits the laser light source for the wavelength division multiplexed downlink signal transmitted from the fourth multiplexer / demultiplexer and transmits the wavelength division multiplexed uplink optical signal to the fourth multiplexer / demultiplexer; A sixth signal for transmitting the wavelength division multiplexed uplink laser light source and the downlink optical signal transmitted from the fourth multiplexer / demultiplexer, and transmitting the wavelength division multiplexed downlink signal laser light source to the fourth multiplexer / demultiplexer Multiplexer / demultiplexer; A seventh multiplexing / demultiplexing unit performing wavelength division multiplexing on the uplink signal laser light source and the downlink optical signal to provide the multiplexing / demultiplexing means and transmitting the wavelength division multiplexing uplink optical signal transmitted from the multiplexing / demultiplexing means Neutralizer; Transmitting the uplink signal laser light source transmitted from the sixth multiplexer / demultiplexer to the seventh multiplexer / demultiplexer, and transmitting the wavelength division multiplexed uplink optical signal transmitted from the seventh multiplexer / demultiplexer to the fifth multiplexer A first optical circulator for transmitting to the demultiplexer; And The sixth multiplexer transmits the downlink optical signal transmitted from the sixth multiplexer / demultiplexer to the seventh multiplexer / demultiplexer, and transmits the laser light source for the wavelength division multiplexed downlink signal transmitted from the fifth multiplexer / demultiplexer. And a second optical circulator for transmitting to the demultiplexer. 15. The method of claim 14, And said multiplexing / demultiplexing means is a waveguide diffraction grating. The method of claim 15, And said fourth multiplexer / demultiplexer is a bidirectional waveguide type diffraction grating.

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