KR20190002277A - Apparatus for providing optical intergrated wired and wireless service at in-building and apparatus for processing wired optical signal - Google Patents

Abstract

The present invention provides an in-building wired and wireless optical integration device and a wired optical signal treating device. The in-building wired and wireless optical integration device includes: at least a remote node (RN) dividing an optical signal into a subscriber terminal; and an optical MUX for line concentration, which is connected to at least a remote node by an optical line and transmits the optical signal in which a wired optical signal received from an optical link terminal and a wireless optical signal received from a digital unit are combined to at least an RN. The RN includes: an optical Demux for the RN, outputting the wired optical signal and wireless optical signal by reversely multiplexing the optical signal received from the optical line; the wired optical signal treating device individually distributing the wired optical signal to multiple optical communication devices connected to a subscriber′s terminal; and a wireless optical signal treating device converting the wireless optical signal to a wireless frequency signal and outputting the wireless optical signal to a wireless signal treating device transmitting and receiving the wireless frequency signal to and from a subscriber′s terminal.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an integrated optical wired / wireless optical integrated device and a wired optical signal processing apparatus,

The present invention relates to an in-building wired / wireless optical integrated device and a wired optical signal processing device.

In building networks are largely built into wired and wireless networks. Currently, landline networks and wireless networks are constructed separately, so landlords and telecommunication carriers must establish separate networks. By building wired / wireless equipment separately for copper, unshielded twisted pair cable, fiber, LAN (local area network), telephone line, coaxial and RF (Radio Frequency) based peer to peer environment There are many investment costs. As such, wired and wireless traffic can not share in-building wiring and equipment, thus increasing the cost of building in-building infrastructures. Therefore, it is necessary to integrate wired and wireless networks.

On the other hand, as internet traffic continues to grow rapidly and the wired / wireless integrated network becomes visible, the development of optical subscriber technology represented by FTTH (fiber-to-the-home) is accelerating. PON (Passive Optical Network) technology, which is leading the FTTH market, is a point-to-multipoint based optical subscriber technology that uses a passive branching device that does not require power supply as a remote node (RN).

Conventionally, an optical distributor in which an optical line is drawn and distributed is composed of passive elements, and there is no separate operating program. Therefore, when a fault occurs in the optical line, there is a method of grasping the fault in real time. It is not possible to monitor the state of the optical line in real time because the operator can recognize the failure of the optical line after confirming the failure in the equipment connected to the optical distributor and thus it takes a long time to process the failure of the optical line have.

Also, unlike a home network, an in-building network has a need for central control at a remote location such as a communication room. However, since conventional data transmission and power supply are separately performed in a building network, there is no method for collectively controlling the same. Since a separate control system is required for batch control, this also raises the construction cost of the in-building infrastructure.

The present invention provides an in-building wired / wireless optical integrated device capable of simplifying an in-building network structure by integrating all-fiber based on-premises wiring, real-time monitoring of optical lines, and collectively controlling optical signals and power signals And to provide a wired optical signal processing apparatus.

According to an aspect of the present invention, an in-building wired / wireless optical integrated device includes at least one remote node (RN) for distributing an optical signal to a subscriber terminal, (MUX) for transmitting an optical signal combining a wired optical signal received from an optical line terminal and a wireless optical signal received from a digital unit to the at least one remote node, wherein the at least one remote node (Demux) for a remote node that demultiplexes an optical signal received from the optical line and outputs a wired optical signal and a wireless optical signal, and a plurality of optical communication devices connected to the subscriber terminal, And converting the radio optical signal into a radio frequency signal to transmit and receive the radio frequency signal to and from the subscriber terminal, That includes a wireless optical signal processing apparatus for output to the wireless signal processing apparatus.

The wired optical signal processing apparatus may measure the optical intensity of the optical line, transmit the optical intensity to the server, and simultaneously transmit the wired optical signal and the power signal to the plurality of optical communication devices.

Wherein the wired optical signal processing apparatus includes an optical splitter for dividing a wired optical signal received from the optical demux for the remote node into a plurality of wired optical signals and a plurality of optical communication devices A first optical fiber for measuring the light intensity of the optical line connecting the optical demux for the remote node and the optical splitter using the at least one optical sensor provided between the optical demux for the remote node and the optical splitter, And a plurality of optical sensors respectively provided between the optical splitter and the plurality of optical communication interfaces are used to measure light intensities of a plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces, And a second light path management unit for outputting the second light path management unit.

The wired optical signal processing apparatus receives the optical intensity from the first optical line management unit and the second optical line management unit, and when the received optical intensity deviates from an intensity within a predefined critical range, A controller for transmitting information and optical intensity information to the server device, and an optical module connected to the optical splitter, for transmitting an optical signal including information received from the controller to the server device.

Wherein the wired optical signal processing apparatus further comprises a power supply control section for outputting a plurality of power supply signals supplied from the power supply apparatus to the plurality of optical communication interfaces, respectively, wherein the plurality of optical communication interfaces include a wired optical signal and a power supply signal, And the hybrid cable may include an optical signal transmission line for outputting the wired optical signal and a power supply line for outputting the power supply signal.

Wherein the wired optical signal processing apparatus further comprises a control unit for outputting a power-on command or a power-off command to the power supply control unit, wherein the power supply control unit is connected to each of the plurality of optical communication interfaces, And a plurality of power switch ICs switched according to the off command.

The wired optical signal processing apparatus may further include an optical module that receives the power-on command or the power-off command from the optical splitter and outputs the power-on command or the power-off command to the controller.

The wired optical signal processing apparatus includes an AC-DC converting unit connected to the plurality of power switch ICs, converting AC power into DC power and outputting the DC power to the power switch IC, and an AC- And an external power supply port for outputting the DC power to the DC conversion unit.

The optical multiplexer for multiplexing multiplexes a wired optical signal of a first wavelength received from the optical line terminal and a wireless optical signal of a second wavelength different from the first wavelength received from the digital unit, Wherein the optical demux for the remote node receives the optical signal of the third wavelength and outputs the optical signal of the first wavelength and the optical signal of the second wavelength, To perform demultiplexing.

Wherein the third wavelength includes a plurality of different wavelengths and the optical demultiplexer for the remote node comprises a plurality of optical demultiplexers for receiving optical signals multiplexed at different wavelengths, . ≪ / RTI >

Wherein the optical multiplexer for the remote node is connected to at least two optical line terminals to receive the wired optical signal of the first wavelength from the optical line terminal in an active state and to receive one of the at least two optical line terminals The optical line terminal of the optical line terminal may be in the active state and the remaining optical line terminal may be in the standby state.

According to another aspect of the present invention, an in-building wired / wireless optical integrated device includes a downlink wired optical signal of a first wavelength received from an optical line terminal and a downlink wireless optical signal of a second wavelength different from the first wavelength received from the digital unit, Multiplexes signals to output a downlink optical signal of a third wavelength different from the second wavelength, and outputs the uplink optical signal of the third wavelength to the uplink wired optical signal of the first wavelength and the uplink optical signal of the second wavelength Demux and demux for demultiplexing the optical line terminal and the digital unit and outputting them to the optical line terminal and the digital unit, respectively, and a demultiplexer connected to the demultiplexer / Wherein the at least one remote node demultiplexes the downlink optical signal to generate a downlink wired optical signal and a downlink wired optical signal, A demultiplexer / multiplexer for a remote node for outputting an uplink optical signal obtained by multiplexing an uplink optical signal and an uplink optical signal to the optical line, To an optical communication device connected to a subscriber terminal, and transmits an uplink wired optical signal obtained by combining a plurality of uplink wired optical signals respectively received from the plurality of optical communication devices to an optical demux / mux for the remote node A wired optical signal processing unit for converting the downlink radio optical signal into a downlink radio frequency signal and transmitting the downlink radio optical signal to a radio signal processing device for transmitting and receiving a radio frequency signal to and from a subscriber terminal, And a radio optical signal processing device for converting the radio frequency signal into the uplink radio optical signal.

The wired optical signal processing apparatus can monitor the optical intensity of the optical line and simultaneously control the transmission of the downlink optical signal to the plurality of optical communication devices and the power supply.

Wherein the third wavelength comprises a plurality of different wavelengths and the at least one remote node comprises an optical demultiplexer / mux for a remote node each selected from the plurality of different wavelengths and each using a different wavelength can do.

According to another aspect of the present invention, a wired optical signal processing apparatus includes an optical splitter that divides a wired optical signal received from an optical line terminal into a plurality of wired optical signals, and outputs the plurality of wired optical signals to an optical communication apparatus A first optical line management unit for measuring and outputting an optical intensity of an optical line connecting the optical line terminal and the optical splitter using at least one optical sensor provided between the optical line terminal and the optical splitter, And a plurality of optical sensors respectively provided between the optical splitter and the plurality of optical communication interfaces to measure and output optical intensities of a plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces, 2 optical line management unit, and the optical intensity of the optical line is < RTI ID = 0.0 >Lt; RTI ID = 0.0 > and / or < / RTI >

The optical splitter may be connected to an optical filter for filtering a wired optical signal multiplexed at one wavelength out of a plurality of wired optical signals multiplexed at different wavelengths output from the optical line terminal.

The wired optical signal processing apparatus may further include a comparator for comparing the respective light intensities output from the first light path management section and the second light path management section with a predefined threshold value and comparing the light intensities below the predefined threshold value And an optical module connected to the optical splitter and transmitting an optical signal including information received from the control unit to the server apparatus, The optical line information can be used to monitor the state and performance of the optical line in the server apparatus.

Wherein the wired optical signal processing apparatus further comprises a power supply control section for outputting a plurality of power supply signals supplied from the power supply apparatus to the plurality of optical communication interfaces, respectively, wherein the plurality of optical communication interfaces include a wired optical signal and a power supply signal, And the hybrid cable may include an optical signal transmission line for outputting the wired optical signal and a power supply line for outputting the power supply signal.

The wired optical signal processing apparatus further includes a control unit for receiving the power on command or the power off command from the server device and outputting the power on command or the power off command received from the optical module to the power control unit And the power supply control unit may include a plurality of power switch ICs each connected to the plurality of optical communication interfaces and switched according to the power on command or the power off command.

The wired optical signal processing apparatus includes an AC-DC converting unit connected to the plurality of power switch ICs, converting AC power into DC power and outputting the DC power to the power switch IC, and an AC- And an external power supply port for outputting the DC power to the DC conversion unit.

According to the embodiment of the present invention, it is possible to simplify the structure and increase the expandability by integrating all-fiber-based intra-site wiring, and it is possible to reduce the construction cost and OPEX (operational expenditure) by applying the passive network method (POL). In addition, it is easy to accommodate 10G Internet and wireless 5G, which was conventionally difficult to implement with UTP and telephone lines.

In addition, it can provide a low-cost wired and wireless integrated infrastructure in an in-building environment through a structure that is optimized for the building environment that requires dense and short-distance transmission.

1 illustrates a configuration of an in-building wired / wireless integrated network according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an example of wiring in a premise to which an in-building wired / wireless optical integrated device according to an embodiment of the present invention is applied.
FIG. 3 illustrates a redundancy structure of an optical line terminal (OLT) according to an embodiment of the present invention.
4 is a block diagram showing a detailed configuration of a wired optical signal processing apparatus according to an embodiment of the present invention.
5 is a block diagram showing a detailed configuration of a wired optical signal processing apparatus according to another embodiment of the present invention.
6 is a block diagram illustrating a detailed configuration of a wired optical signal processing apparatus according to another embodiment of the present invention.
FIG. 7 shows a connection relationship between a control apparatus and a plurality of wired optical signal processing apparatuses according to the embodiment of FIG.
8 is a block diagram showing a detailed configuration of a wireless optical signal processing apparatus according to an embodiment of the present invention.
9 is a flowchart illustrating an in-building line management method according to an embodiment of the present invention.
10 is a flowchart illustrating an in-building line management method according to another embodiment of the present invention.
11 shows a configuration of an in-building wired / wireless integrated network according to another embodiment of the present invention.
12 is a diagram illustrating an example of wiring in a premise to which an in-building wired / wireless optical integrated device according to another embodiment of the present invention is applied.
13 is a hardware block diagram of a server apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Also, the terms " part, "" ... "," module ", and the like described in the specification mean a unit for processing at least one function or operation and may be implemented by hardware or software or a combination of hardware and software .

The expressions described in the singular may be interpreted as singular or plural unless an explicit expression such as "a" or "a" is used.

In this specification, a wireless communication system includes a CCC (Cloud Communication) system that separates a base station from a digital unit (hereinafter referred to as 'DU') and a Radio Frequency Unit (hereinafter referred to as 'RFU' Center technology.

Here, DU is a configuration for processing a digital signal of a base station, and is composed of a channel card for encrypting and decrypting a wireless digital signal such as 3G and LTE (Long Term Evolution), and is mainly implemented as a DU concentrated center in the field of communication. The RFU is installed in the service area, amplifies the RF signal, and transmits the amplified RF signal through the antenna.

2 is a diagram illustrating an example of wiring in a premise to which an in-building wired / wireless optical integrated device according to an embodiment of the present invention is applied, and FIG. 3 is a cross- FIG. 2 illustrates a redundancy structure of an optical line terminal (OLT) according to an embodiment of the present invention.

1, an in-building wired / wireless optical integrator 100 is an apparatus for integrating all-fiber-based premises wiring in an in-building, and is a device for integrating wireless communication signals and wired communication signals on an optical basis ≪ / RTI > At this time, the in-building wired / wireless optical integrator 100 monitors the optical line in the building, and simultaneously controls the transmission of the wired optical signal and the supply of the power source signal.

The building wired and wireless optical integrated device 100 includes a MUX / DEMUX 110 and at least one remote node (RN) 120.

The optical multiplexer / demultiplexer 110 and the at least one RN 120 are spaced from each other and connected to each other through an optical line. The optical multiplexer / demultiplexer 110 is installed mainly in a building communication room, and at least one RN 120 is installed in an interlayer terminal box, a communication distribution box, and the like. The optical multiplexer / demultiplexer 110 performs the aggregation function of the downlink optical signal and the uplink optical signal of the subscriber terminals 600 in the building. At least one RN 120 distributes downlink optical signals and uplink optical signals of subscriber terminals 600 in the building to each subscriber.

The optical multiplexer / demultiplexer 110 is connected to the OLT 200 through an optical line. The optical mux / demux 110 is connected to a main hub unit (MHU) 300 through an optical line.

The RN 120 includes an optical demux / mux 130, a wired optical signal processing device 150, and a wireless optical signal processing device 170. Each of the components 110, 130, 140, and 150 may be configured to be removably installed in a modular fashion, and may be spaced apart from each other at a remote place.

The optical DEMUX / MUX (130) is connected to the optical MUX / DEMUX (110) through the optical line. The optical demux / mux 130 is connected to the wired optical signal processing device 150 and the optical wireless signal processing device 170 through optical lines, respectively.

The wired optical signal processing device 150 is connected to the optical communication device 400 through an optical line. The wireless optical signal processing device 170 is connected to the RFU 500 through an optical line.

Here, an optical cable can be used for the optical line. The optical line is connected to the building unit.

The subscriber terminal 600 may be connected to the optical communication device 400 by wire or wirelessly and wirelessly with the RFU 500.

The OLT 200 is installed in an in-building communication room, and is connected to the aggregation switch 700 through a wire. The MHU 300 is installed in the in-building communication room, and is wirelessly connected to the DU 800.

The aggregation switch 700 and the DU 800 are connected to the network 1000 through a backbone switch 900. In the network 1000, a service provider server 1100 and an in-building line management server 1200 are connected.

The optical multiplexer / demultiplexer 110 may be installed in a communication terminal box of a building communication room or a main distribution frame (MDF). The RN 120 may be installed at an intermediate point in the building, for example, in some layers (e.g., an intermediate layer) of the entire layer, or in a communication terminal box or a main distribution board in units of layers.

According to one embodiment, as shown in FIG. 2, a plurality of (n) RNs 120-1 and 120-2 may be connected to one optical MUX / DEMUX 110. Each of the RNs 120-1 and 120-2 uses different wavelengths. That is, the optical wavelength used in the optical line connected between the optical mux / demux 110 and the RN1 120-1 and the optical wavelength used in the optical line connected between the optical mux / demux 110 and the RNn 120-2 Wavelengths are different.

For example, the RNs 120-1 and 120-2 may be implemented by the number of the building layers. That is, if it is a ten-story building, ten RNs 120-1 and 120-2 can be implemented.

In addition, the RNs 120-1 and 120-2 may be implemented as traffic load balancing units. For example, assuming that a 10G PON (passive optical network) service is possible with one wavelength, it can be considered that 100G PON service is possible with 10 wavelengths. When the wavelength of a wired optical signal output from the OLT 200 is λ ₁ and the wavelength of a wireless optical signal output by the MHU 300 is λ ₂ , the integrated optical signal output from the optical multiplexer / demultiplexer 110 The wavelength of the signal can be defined as a total of 10 wavelengths. Since the optical demux / muxes 130 of the RNs 120-1 and 120-2 are implemented by the number of filtering 10 wavelengths, the total number of RNs 120-1 and 120-2 do. In this case, the wavelength of the integrated optical signal generated by the MUX / DEMUX 110 is controlled so that the wired data and the wireless data in the building are not concentrated in the specific optical communication device 400 or the RFU 500, -1, 120-2 to the optical demux / mux 130 of the optical demux / mux 130.

Accordingly, if a 1G PON service is provided by a single RN 120, it is possible to implement a 10G PON service using 10 RNs 120-1 and 120-2. According to this embodiment, when a large amount of traffic flows into an in-building, load balancing can be effected by dispersing and transmitting traffic with different wavelengths.

Referring again to FIG. 1, the optical multiplexer / demultiplexer 110 multiplexes downlink optical signals having different wavelengths into one downlink optical signal. The optical multiplexer / demultiplexer 110 receives the downlink wired optical signal of the first wavelength? ₁ from the OLT 200. The downlink wired optical signal includes downlink data provided through an Internet provider network. The optical multiplexer / demultiplexer 110 receives the downlink radio optical signal of the second wavelength? ₂ different from the first wavelength? ₁ from the MHU 300. The downlink radio optical signal includes downlink data provided through a mobile communication carrier network. Optical mux / demux 110, a first wavelength (λ _1), the downlink wired optical signal and a second down-link wireless optical signal of the second wavelength (λ _2), the second wavelength (λ ₂₎ different from the third wavelength ( ₃ ) and transmits the multiplexed signal to the optical demultiplexer / multiplexer 130 via the optical line.

The optical multiplexer / demultiplexer 110 demultiplexes one uplink optical signal into uplink optical signals of different wavelengths. The optical multiplexer / demultiplexer 110 receives the uplink optical signal of the third wavelength? ₃ from the optical line connected to the optical demultiplexer / multiplexer 130. Optical mux / demux 110 on the uplink wireless optical signal of a third wavelength (λ _3), the uplink optical signal to the first wavelength (λ ₁₎ uplink wired optical signal and the second wavelength (λ ₂₎ of the Demultiplexing. The optical multiplexer / demultiplexer 110 outputs the uplink wired optical signal of the first wavelength? ₁ to the OLT 200. The optical multiplexer / demultiplexer 110 outputs the uplink optical signal of the second wavelength? ₂ to the MHU 300. The uplink wired optical signal includes uplink data to be provided to the Internet carrier network, and the uplink radio optical signal includes uplink data to be provided to the mobile communication network.

The optical demux / mux 130 receives the downlink optical signal of the third wavelength? ₃ from the optical mux / demux 110 and outputs the uplink optical signal of the third wavelength? ₃ to the optical mux / To the demux 110. The optical demux / mux 130 is connected to the wired optical signal processing device 150 and the optical wireless signal processing device 170.

The optical demux / mux 130 demultiplexes the downlink optical signal into downlink optical signals of different wavelengths. Optical demultiplexer / multiplexer 130 is a downlink wireless optical signal of a third wavelength (λ _3), the downlink wired optical signal and the second wavelength (λ _2), a downlink optical signal of a first wavelength (λ ₁₎ Demultiplexing. The optical demux / mux 130 outputs the downlink wired optical signal of the first wavelength λ ₁ to the wired optical signal processing device 150. The optical demux / mux 130 outputs the downlink optical signal of the second wavelength λ ₂ to the optical wireless signal processor 170.

The optical demux / mux 130 multiplexes uplink optical signals of different wavelengths into uplink optical signals of one wavelength. The optical demux / mux 130 receives the uplink wired optical signal of the first wavelength? ₁ received from the wired optical signal processing device 150 and the optical signal of the second wavelength? _{2 on} the uplink optical signal of the third wavelength? ₃ .

Here, the optical mux / demux 110 and the optical demux / mux 130 may be a Wavelength Division Multiplexing (WDM) filter.

The wired optical signal processing device 150 combines and distributes wired optical signals transmitted between the optical demux / mux 130 and the optical communication device 400. The wired optical signal processing device 150 monitors the optical intensity of the optical line connected to the optical demultiplexer / mux 130 and the optical line connected to the optical communication device 400. The wired optical signal processing device 150 simultaneously controls optical signal transmission and power supply to the optical communication device 400.

The RF optical signal processing apparatus 170 is connected to the optical demultiplexer / mux 130 through an optical line and connected to the RFU 500 through a radio frequency (RF) cable, for example, It is connected through a coaxial cable. The wireless optical signal processing apparatus 170 converts the downlink radio optical signal received from the optical demux / mux 130 into a downlink RF signal and transmits the downlink optical signal to the RFU 500. The wireless optical signal processing device 170 converts the uplink RF signal received from the RFU 500 into an uplink radio optical signal and transmits the uplink radio optical signal to the optical demultiplexer / mux 130.

The OLT 200 may be connected to the aggregation switch 700 through a UTP (Unshielded Twisted Pair) cable, a phone line, a power line, a coaxial cable, a fiber cable, or the like. The OLT 200 converts the wired data received from the aggregation switch 700 into a first wavelength (λ ₁ ) wired optical signal. The OLT 200 photoelectrically converts the wired optical signal of the first wavelength? ₁ received from the optical line connected to the optical multiplexer / demultiplexer 110 into wired data and transmits the wired optical signal to the collective switch 700.

At this time, the OLT 200 may be implemented in a redundant structure as shown in FIG. Referring to FIG. 3, an OLT 201 in an active mode and an OLT 2 203 in a standby mode are connected to an optical multiplexer / demultiplexer 110.

The optical multiplexer / demultiplexer 110 receives a wired optical signal from the active mode OLT 201. When a failure occurs in the OLT1 201, the OLT2 203 in the standby mode is switched to the active mode and transmits a wired optical signal to the optical multiplexer / demultiplexer 110. [ At this time, the in-building OLT1 201 and the in-building OLT2 203 may use the same wavelength or different wavelengths.

Referring again to FIG. 1, the MHU 300 receives a multi-band wireless service and transmits RF digital data received from the DU 800 to a wireless optical signal of a second wavelength λ ₂ Conversion. The MHU 300 photoelectrically converts the radio optical signal of the second wavelength? ₂ received from the optical line connected to the optical mux / demux 110 into RF digital data, and transmits the RF optical signal to the DU 800.

The optical communication device 400 converts the wired optical signal of the first wavelength λ ₁ received from the optical line connected to the wired optical signal processing device 150 into an Ethernet signal and transmits the Ethernet signal to the subscriber terminal 600 . The optical communication device 400 converts the Ethernet signal received from the subscriber terminal 600 into a wired optical signal of the first wavelength λ ₁ and transmits the wired optical signal to the wired optical signal processing device 150.

The optical communication device 400 provides a passive optical network (PON) subscriber interface and can perform connection with the subscriber terminal 600 in a 1: N (1: N) manner. The optical communication device 400 includes an optical module in the form of an optical network unit (ONU), an optical network terminal (ONT), a stick, or a card. The ONU is a small-scale outdoor / indoor optical communication device installed at the center of a residential subscriber density area. The ONT is an optical modem device that can be connected to a PC as a final optical terminal device. At this time, the ONT may be an optical modem device including a WiFi AP function. The optical module is a configuration in which the hardware of the PON module that provides the PON function in the OLT is integrated and mounted. The optical communication device is implemented as a stick type or a card type.

The RFU 500 amplifies the RF signal received from the wireless optical signal processing device 170 to high power so as to match the transmission power and transmits the RF signal to the subscriber terminal 600 through the transmission antenna TX Ant. And amplifies the RF signal received from the subscriber terminal 600 through the reception antenna RX Ant and outputs the amplified RF signal to the wireless optical signal processing device 170. [

The subscriber terminal 600 is a terminal for receiving a data service, a telephone service, and the like, for example, an Internet telephone terminal, an IPTV, a PC, an Internet of things Mobile devices and notebooks.

The aggregation switch 700 is installed in the national office and outputs uplink data received from the OLT 200 to the backbone switch 900 and transmits downlink data received from the backbone switch 900 to the OLT 200 .

The DU 800 is installed in the national office and outputs the uplink data received from the MHU 300 to the backbone switch 900 and transmits the downlink data received from the backbone switch 900 to the MHU 300.

The backbone switch 900 is installed in the office and distributes the downlink data received from the service provider server 1100 through the network 1000 to the aggregation switch 700 and the DU 800. And transmits the uplink data received from the aggregation switch 700 and the DU 800 to the service provider server 1100, respectively.

The network 1000 may include the Internet or a broadband network such as Fiber To The X (FTTx), which includes Fiber To The Home (FTTH).

The service provider server 1100 may be a server for providing a data service as a subscriber terminal and may include a server providing an Internet Protocol Television (IPTV) service, an Internet portal server, And may be a provider server that performs Internet service policy and network management at the subscriber terminal.

The building line management server 1200 installed in the office is connected to the network 1000 through the path formed by the network 1000 backbone switch 900 the aggregation switch 700 OLT 200 from the wired / wireless optical integrator 100, . Here, the control information includes optical line / power monitoring information, digital diagnostic monitoring information (DDMI), PON Operations, Administration and Maintenance (OAM) information, and the like.

The building line management server 1200 monitors performance data on the state of the optical line based on the light intensity of the plurality of optical lines in the building. Here, a plurality of optical lines are connected to a first optical line (hereinafter, referred to as an upper optical line) connected to the OLT 200 - optical mux / demux 110 - optical demux / mux 130 - And a second optical line (hereinafter, referred to as a subscriber optical line) connected to the wired optical signal processing device 150 and the optical communication device 400. [ The building line management server 1200 receives the optical intensity of the upper optical line measured by the wired optical signal processing device 150 and the intensity of the subscriber optical line and the optical intensity of the upper optical line measured by the OLT 200, The optical intensity of the subscriber optical line measured by the device 400 may be compared and the performance data of the upper optical line and the subscriber optical line may be monitored based on the comparison result. Therefore, it is possible to confirm at a remote place in real time which optical line failure occurred when a failure occurs.

The building line management server 1200 can receive the DDMI data and the PON OAM information from the OLT 200.

In addition, the building line management server 1200 transmits a power on command for turning on the power for each optical communication device 400 or a power off command for turning off the power for each optical communication device 400 to the wired optical signal processing device 150 . At this time, the wired optical signal processing device 150 simultaneously transmits the wired optical signal and the power signal to the plurality of optical communication devices 400 and determines whether to transmit the power signal to the optical communication device 400 according to the power on command or the power off command You can decide. Therefore, it is possible to control the optical communication device 400 without having to go out in the field at a remote place.

In addition, the building line management server 1200 compares and verifies the stored line number with the line number sheet input from the wired optical signal processing device 150. Here, the pre-number field is a document for assigning and managing the line number of the optical line, and manages the line usage history allocated by each system. Operator information is manually identified and collected by the operator and managed in the form of an electronic document (for example, an Excel document). The information of the pre-loaded number is classified and stored according to the region / equipment, and it is possible to inquire or modify the pre-loaded information according to the request of the operator computer.

The building line management server 1200, which is a building line management server 1200, can compare the received and inputted line numbers inputted from the wired optical signal processing device 150 with the stored line numbers to remotely manage the line numbers. Therefore, unlike the conventional method in which an operator manually labels the optical cable and inputs it into a document, the wired optical signal processing device 150 enables automatic management of the no-run field management from a remote place.

Now, the detailed configurations of the wired / wireless optical integrated device 100 will be described. First, the detailed configuration of the wired optical signal processing apparatus will be described with reference to FIGS. 4 to 6. FIG.

FIG. 4 is a block diagram showing a detailed configuration of a wired optical signal processing apparatus according to an embodiment of the present invention, FIG. 5 is a block diagram showing a detailed configuration of a wired optical signal processing apparatus according to another embodiment of the present invention, FIG. 6 is a block diagram showing a detailed configuration of a wired optical signal processing apparatus according to another embodiment of the present invention. FIG. 7 is a diagram illustrating a connection relationship between a control apparatus according to the embodiment of FIG. 6 and a plurality of wired optical signal processing apparatuses .

4, the wired optical signal processing apparatus 150 includes an optical splitter 141, a plurality of optical communication interfaces 152, an upper optical line management unit 153, a subscriber optical line management unit 154, And a control unit 155.

The optical splitter 151 splits or combines the optical signal into 1: N. The optical splitter 151 splits the wired optical signal received from the optical demux / mux 130 into N wired optical signals and outputs them to the N optical communication interfaces 152, respectively. The optical splitter 151 combines N wired optical signals input from the N optical communication interfaces 152 and outputs one wired optical signal to the optical demux / mux 130.

The plurality of optical communication interfaces 152 output a plurality of wired optical signals output by the optical splitter 151 to the connected optical communication device 400, respectively. And outputs the wired optical signal received from the connected optical communication device 400 to the optical splitter 151.

At this time, the plurality of optical communication interfaces 152 are connected to the plurality of optical communication devices 400 through hybrid cables, respectively. Here, the hybrid cable includes an optical signal transmission line for transmitting and receiving a wired optical signal and a power supply line for outputting a power supply signal. Therefore, the wired optical signal and the power source signal are simultaneously transmitted to the optical communication device 400. At this time, a POE (Power Over Ethernet) method can be used as a method of simultaneously transmitting a wired optical signal and a power source signal. As described above, the wired optical signal and the power signal are simultaneously transmitted through a single cable, thereby reducing the cost of additional power supply installation work.

The upper optical path management unit 153 includes at least one optical sensor 156 installed between the optical demux / mux 130 and the optical splitter 151. The photo sensor 156 uses a photo diode. The photodiode measures the intensity of the optical signal and converts the measured intensity into an electrical signal.

The upper optical path management unit 153 outputs the optical intensity of the upper optical line connecting the optical demultiplexer / multiplexer 130 and the optical splitter 151 measured through the at least one optical sensor 156 to the controller 157 .

As shown in FIG. 5, the upper light-line managing unit 153 includes an optical sensor installed in an upper optical line connected to the active OLT 201 and an upper optical line connected to the OLT 203 in a standby state And may include a light sensor.

The subscriber's optical line management unit 154 includes a plurality of optical sensors 156 installed between an optical splitter 151 and a plurality of optical communication interfaces 152, respectively.

The subscriber's optical line management unit 154 controls the light intensity of a plurality of subscriber optical lines connecting the optical splitter 151 and the plurality of optical communication interfaces 152 measured through the plurality of optical sensors 156 to the control unit 157 Output.

The power supply control unit 155 controls power supply to the optical communication device 400 under the control of the control unit 157. [ The power supply control unit 155 outputs the plurality of power supply signals to the plurality of optical communication interfaces 152, respectively.

The power supply control unit 155 includes a plurality of power switch ICs 158. A plurality of power switch ICs 158 are connected to the plurality of optical communication interfaces 152, respectively. The plurality of power switch ICs 158 are switched to the ON state in accordance with the power ON command received from the controller 157, and output the power signal to the corresponding optical communication interface 152. Here, the power supply signal may be -48V.

The plurality of power switch ICs 158 are switched to the OFF state in accordance with the power OFF command. Then, the power supply signal is not supplied to the optical communication interface 152. Here, the power-on command and the power-off command may be received by the optical communication interface 152 or collectively.

The control unit 157 receives the optical intensity of the upper optical line from the upper optical line management unit 153 and receives the optical intensity of the subscriber optical line from the subscriber optical line management unit 154. [ When the intensity of the received optical line deviates from the intensity within the predetermined threshold range, the controller 157 transmits the optical line information and the optical intensity information to the building line management server 1200 through the optical module 161 send.

The building line management server 1200 can monitor the upper optical line control section and the subscriber optical line control section based on the received optical line information and optical intensity information.

At this time, the control unit 157 can confirm the optical line information using the pre-loaded information stored in the memory 159. [ The number information is input from the operator through the input unit 160. The number information can be transmitted to the in-building line management server 1200 and can be compared with the number information stored in the in-building line management server 1200.

The control unit 157 receives the power-on command or the power-off command from the building line management server 1200 and outputs the power-on command or the power-off command to the corresponding power switch IC 158.

In addition, the controller 157 may transmit the power control information to the in-building line management server 1200 according to a request from the in-building line management server 1200 or according to a period stored in the memory 159. [ That is, a state in which the power is supplied can be reported to the building line management server 1200. For example, the control unit 157 can report whether or not the power supply is stabilized, the information of the optical communication device 400 that is being supplied with power, the amount of power used by each line, and the like. Here, the line means a cable line connecting the optical communication interface 152 and the optical communication device 400.

The memory 159 stores information necessary for the operation of the controller 157 in addition to the pre-load information.

6, the control unit 157, the memory 159, and the input unit 160 may be implemented as a control unit 164, which is a physical device separate from the wired optical signal processing unit 150. FIG. Referring to FIG. 7, one controller 164 may be connected to a plurality of wired optical signal processing devices 150 to control the operation of the plurality of wired optical signal processing devices 150.

The optical module 161 is connected to the optical splitter 151 and includes information received from the controller 157 in the optical signal and outputs the optical signal to the optical splitter 151 through the optical demultiplexer / 110) -OLT 200-aggregation switch 700 -backbone switch 900-to the building line management server 1200 through the path of the network 1000.

The optical module 161 includes a network 1000, a backbone switch 900, an aggregation switch 700, an OLT 200, an optical multiplexer / demultiplexer 110, an optical demultiplexer / multiplexer 130, and an optical splitter 151 Power on command or power off command from the building line management server 1200 through the path of the power management unit 1200 and outputs it to the control unit 157. [

The AC-DC converter 162 is connected to the plurality of power switch ICs 158, respectively. The AC-DC converter 162 converts AC power into DC power and outputs the AC power to a plurality of power switch ICs 158.

The external power supply port 163 receives the external AC power and outputs the AC power to the AC-DC converter 162.

8 is a block diagram showing a detailed configuration of a wireless optical signal processing apparatus according to an embodiment of the present invention.

Referring to FIG. 8, a wireless optical signal processing apparatus 170 includes a digital processing unit 171, an RF processing unit 173, and at least one coaxial socket 175.

The digital processing unit 171 converts the downlink radio optical signal received from the optical demux / mux 130 into a downlink digital signal through photoelectric conversion. The digital processing unit 171 converts the uplink digital signal into an uplink radio optical signal through an electro-optical conversion and outputs it to the optical demux / mux 130.

The RF processor 173 converts the downlink digital signal output from the digital processor 171 into an RF signal of a frequency type used in the RFU 500 connected through the coaxial socket 175 and outputs the RF signal. The RF processor 173 converts the uplink RF signal received from the RFU 500 via the coaxial socket 175 into an uplink digital signal and outputs the uplink digital signal to the digital processor 171.

The RF processing unit 501 of the RFU 500 high-power amplifies the RF signal received from the wireless optical signal processing device 170 through the coaxial socket 503 to match the transmission output and radiates the amplified RF signal to the air through the antenna 505 . The RF processor 501 of the RFU 500 amplifies the RF signal received through the antenna 505 and transmits the amplified RF signal to the RF optical signal processor 170 through the coaxial socket 503. [

9 is a flowchart illustrating an in-building line management method according to an embodiment of the present invention, which shows a method of monitoring an optical line.

9, the control unit 157 receives the detection signal including the light intensity of the upper optical line from the upper optical line management unit 153, and receives the light intensity of the subscriber optical line from the subscriber optical line management unit 154 (S101).

The controller 157 determines whether there is an optical line having a light intensity lower than a predetermined threshold value among the light intensities of the optical lines received (S101) (S103). If not, start from S101 again.

On the other hand, if there is an optical line whose light intensity is lower than the threshold value, the optical line information is confirmed from the memory 159 (S105). Then, the optical line information and the measured light intensity information are transmitted to the in-building line management server 1200 (S107).

The building line management server 1200 receives the upper optical line information and the optical intensity information of the upper optical line measured by the OLT 200 from the OLT 200 (S109).

The building line management server 1200 receives the optical intensity and subscriber optical line information of the subscriber optical line measured by the plurality of optical communication devices 400 from the plurality of optical communication devices 400 at steps S111 and S113.

The building line management server 1200 monitors the states of the upper optical line and the subscriber optical line based on the optical line information and optical intensity information received (S109, S111, S113) (S115). The building line management server 1200 may determine whether the optical line is faulty based on the monitoring result. The building line management server 1200 may configure the monitor screen as a result of comparing the information received in the step S109 and the information received in the steps S111 and S113 and output the monitor screen so that the operator can confirm the monitor screen.

FIG. 10 is a flowchart illustrating an in-building line management method according to another embodiment of the present invention, which shows a power supply control method.

Referring to FIG. 10, the in-building line management server 1200 determines whether to turn on or off the plurality of optical communication devices 400 (S201). At this time, all of the optical communication devices 400 may be turned on or turned off, or some optical communication devices 400 may be selectively turned on or off.

The building line management server 1200 transmits the power-on command to the controller 157 in accordance with the determination (S201) (S203). The control unit 157 controls the optical communication device 400 to output a power signal according to the power-on command (S205). That is, the power supply signal is outputted to the power switch IC 158 of the optical communication interface 152 connected to the optical communication device 400 corresponding to the power on command.

The building line management server 1200 transmits the power off command to the controller 157 in accordance with the determination (S201) (S207). The control unit 157 controls the power supply signal of the corresponding optical communication device 400 to be cut off according to the power off command (S209). That is, the power switch IC 158 of the optical communication interface 152 connected to the optical communication device 400 corresponding to the power off command is turned off to interrupt the supply of the power supply signal.

In addition, according to another embodiment of the present invention, only the wired optical signal processing device 150 may be applied to the in-building. For example, a wireless network in an in-building may be constructed based on an existing RF cable, and a wired network may be additionally constructed based on an optical line.

FIG. 11 illustrates a construction of an in-building wired / wireless integrated network according to another embodiment of the present invention, and FIG. 12 illustrates an example of internal wiring using an in-building wired / wireless optical integrated device according to another embodiment of the present invention.

Referring to FIG. 11, an in-building wired / wireless optical integrated device 100 includes an optical multiplexer / demultiplexer 111 and at least one wired optical signal processor 150, unlike the embodiment of FIG. At this time, at least one wired optical signal processing device 150 is the same as the configuration described with reference to Figs. 1 to 10.

Optical mux / demux 111 is down in the third wavelength (λ ₃₎ for multiplexing a downlink wired optical signals of a plurality of first wavelength (λ ₁₎ toward the plurality of subscriber terminal 600 from the OLT (200) And generates a link optical signal. The optical multiplexer / demultiplexer 111 outputs the downlink optical signal of the third wavelength? ₃ to at least one wired optical signal processor 150. And at least one uplink wire of the third wavelength (λ _3), the first wavelength (λ ₁₎ a plurality of uplink optical signals received from the plurality of subscriber terminal 600 through the wired optical signal processing unit 150 And outputs the optical signal to the OLT 200. [

The configuration of the optical communication device 400, the subscriber terminal 600, the aggregation switch 700, the backbone switch 900, the network 1000, the service provider server 1100, Is the same as the configuration described in Fig.

Referring to FIG. 12, one optical MUX / DEMUX 111 may be connected to a plurality (n) of RNs 120-3 and 120-4.

The plurality of (n) RNs 120-3 and 120-4 include an optical filter 190 and a wired optical signal processing device 150, respectively. Each optical filter 190 filters different wavelengths. That is, the optical wavelengths used in the optical line connected between the optical multiplexer / demultiplexer 111 and the RN1 120-3 and the optical wavelengths used in the optical line connected between the optical multiplexer / demultiplexer 111 and the RNn 120-4 Wavelengths are different. Each of the optical filters 190 passes an optical signal having an optical wavelength used by the RNs 120-3 and 120-4 and outputs the optical signal to the wired optical signal processing device 150. [

According to one embodiment, a plurality (n) of RNs 120-3 and 120-4 may be implemented by the number of building layers. That is, if ten-story building, ten RNs 120-3 and 120-4 can be implemented.

According to another embodiment, a plurality (n) of RNs 120-3 and 120-4 may be implemented as a traffic load balancing unit. For example, assuming that a 10G PON (passive optical network) service is possible with one wavelength, it can be considered that 100G PON service is possible with 10 wavelengths. At this time, when the wavelength of the wired optical signal output from the OLT 200 is λ ₁ , the wavelength of the integrated optical signal output from the optical multiplexer / demultiplexer 111 can be defined as a total of ten wavelengths. Each of the optical filters 190 of the plurality (n) of RNs 120-3 and 120-4 is implemented by the number of filtering 10 wavelengths, so that a total of 10 RNs 120-3 and 120-4 ). In this case, if the wavelength of the integrated optical signal generated by the MUX / DEMUX 110 is controlled, it is possible to prevent the wired data in the building from being concentrated in the specific optical communication device 400, And can be evenly distributed to the optical filter 190.

Accordingly, if a 1G PON service is provided by a single RN 120, 10G PON services can be implemented with 10 RNs 120-3 and 120-4. According to this embodiment, when a large amount of traffic flows into an in-building, load balancing can be effected by dispersing and transmitting traffic with different wavelengths.

13 is a hardware block diagram of a server apparatus according to an embodiment of the present invention, and shows the hardware configuration of the in-building line management server 1200 described in Figs. 1 to 12. Fig.

13, a server device 1300 includes a communication device 1301, a memory 1303, a storage device 1305, and at least one processor 1307. [

The communication device 1301 is connected to at least one processor 1307 to transmit and / or receive data via the network 1000. The memory 1303 may include an in-building line management program coupled to the at least one processor 1307 to include instructions to cause the configuration and / or methods in accordance with the embodiments described in Figs. 1-12 to be executed. . The building line management program, in combination with hardware such as memory 1303 and at least one processor 1307, embodies the present invention.

The storage device 1305 includes information necessary for operation of the server device. The processor 1307 executes the present invention in combination with hardware such as the memory 1303, the storage device 1305, and the like.

The embodiments of the present invention described above are not implemented only by the apparatus and method, but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (20)

At least one remote node (RN) for distributing an optical signal to a subscriber terminal, and
An optical multiplexer connected to the at least one remote node via an optical line and for transmitting an optical signal obtained by combining a wired optical signal received from the optical line terminal and a wireless optical signal received from the digital unit to the at least one remote node; (MUX)
Wherein the at least one remote node comprises:
An optical demux for a remote node for demultiplexing an optical signal received from the optical line and outputting a wired optical signal and a wireless optical signal,
A wired optical signal processing device for distributing the wired optical signal to a plurality of optical communication devices connected to the subscriber terminal, and
A wireless optical signal processing device for converting the wireless optical signal into a radio frequency signal and outputting the radio frequency signal to a wireless signal processing device for transmitting and receiving the radio frequency signal to and from a subscriber terminal
Wherein the optical fiber is a fiber optic cable. The method of claim 1,
The wired optical signal processing apparatus includes:
And transmits the wired optical signal and the power signal to the plurality of optical communication devices at the same time. 3. The method of claim 2,
The wired optical signal processing apparatus includes:
An optical splitter for splitting the wired optical signal received from the optical demux for the remote node into a plurality of wired optical signals,
A plurality of optical communication interfaces for outputting the plurality of wired optical signals to a connected optical communication device,
A first optical line for measuring and outputting an optical intensity of an optical line connecting the optical demux for the remote node and the optical splitter using at least one optical sensor provided between the optical demux for the remote node and the optical splitter, Management department, and
A plurality of optical sensors respectively provided between the optical splitter and the plurality of optical communication interfaces to measure a light intensity of a plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces, Management section
Wherein the optical fiber is a fiber optic cable. 4. The method of claim 3,
The wired optical signal processing apparatus includes:
When receiving the light intensity from the first light path management unit and the second light path management unit and when the received light intensity deviates from an intensity within a predefined threshold range, , And
And an optical module connected to the optical splitter and transmitting an optical signal including information received from the controller to the server device,
Further comprising: an optical fiber connector, 5. The method of claim 4,
The wired optical signal processing apparatus includes:
Further comprising a power supply control unit for outputting a plurality of power supply signals supplied from the power supply unit to the plurality of optical communication interfaces, respectively,
The plurality of optical communication interfaces include:
A wired optical signal and a power signal are transmitted to an optical communication device connected through a hybrid cable,
The hybrid cable includes:
An optical signal transmission line for outputting the wired optical signal, and a power supply line for outputting the power supply signal. The method of claim 5,
The wired optical signal processing apparatus includes:
Further comprising a controller for outputting a power-on command or a power-off command to the power supply controller,
The power-
And a plurality of power switch ICs respectively connected to the plurality of optical communication interfaces and switched in accordance with the power on command or the power off command. The method of claim 6,
The wired optical signal processing apparatus includes:
An optical module for receiving the power-on command or the power-off command from the optical splitter and outputting the power-
Further comprising: an optical fiber connector, 8. The method of claim 7,
The wired optical signal processing apparatus includes:
An AC-DC converting unit connected to the plurality of power switch ICs, for converting the AC power to DC power and outputting the DC power to the power switch IC, and
An external power supply port for receiving external AC power and outputting the AC power to the AC-
Further comprising: an optical fiber connector, The method of claim 1,
The optical multiplexer for line-
Multiplexes a wired optical signal of a first wavelength received from the optical line terminal and a wireless optical signal of a second wavelength different from the first wavelength received from the digital unit to output an optical signal of a third wavelength different from the second wavelength And outputs it to the optical line,
Wherein the optical demultiplexer for the remote node comprises:
And demultiplexes the optical signal of the third wavelength into a wired optical signal of the first wavelength and a wireless optical signal of the second wavelength. The method of claim 9,
The third wavelength is a wavelength,
A plurality of wavelengths different from each other,
Wherein the optical demultiplexer for the remote node comprises:
And a plurality of optical demultiplexers for receiving optical signals selected from the plurality of different wavelengths and multiplexed at different wavelengths. The method of claim 9,
The optical multiplexer for the remote node comprises:
Receiving a wired optical signal of the first wavelength from an optical line terminal in an active state, connected to at least two optical line terminals,
Wherein one optical line terminal among the at least two optical line terminals is in an active state and the remaining optical line terminals are in a standby state. Downlink wired optical signal of the first wavelength received from the optical line terminal and a downlink radio optical signal of the second wavelength different from the first wavelength received from the digital unit to multiplex the downlink radio optical signal of the second wavelength and the downlink radio optical signal of the third wavelength different from the second wavelength Link optical signal and outputs the uplink optical signal of the third wavelength to the optical line terminal and the digital unit by separating the uplink optical signal of the third wavelength into the uplink wired optical signal of the first wavelength and the uplink optical signal of the second wavelength Mux / Demux for collecting, and
And at least one remote node (RN) connected to the optical MUX / DEMUX for demultiplexing through the optical line and installed at a remote place in the building,
Wherein the at least one remote node comprises:
And outputting a downlink optical signal and a downlink optical signal by demultiplexing the downlink optical signal and outputting an uplink optical signal obtained by multiplexing the uplink optical signal and the uplink optical signal to the optical line, Optical demux / mux for a node,
And an optical network unit for distributing the downlink wired optical signal to a plurality of optical communication apparatuses connected to a subscriber terminal and for transmitting an uplink wired optical signal obtained by combining a plurality of uplink wired optical signals respectively received from the plurality of optical communication apparatuses, A wired optical signal processing device for transmitting to a MUX / MUX, and
And transmits the downlink radio optical signal to a downlink radio frequency signal, and transmits the uplink radio frequency signal to a subscriber terminal, which transmits and receives a radio frequency signal to the radio signal processor. A wireless optical signal processing apparatus for converting into a wireless optical signal
Wherein the optical fiber is a fiber optic cable. The method of claim 12,
The wired optical signal processing apparatus includes:
And monitors the optical intensity of the optical line and simultaneously controls transmission and power supply of the downlink optical signal to the plurality of optical communication devices. The method of claim 12,
Wherein the third wavelength includes a plurality of wavelengths different from each other,
Wherein the at least one remote node comprises:
And a remote demultiplexer / demultiplexer for the remote node, each of the remote demultiplexers / demultiplexers being selected from the plurality of different wavelengths and using different wavelengths, respectively. An optical splitter for splitting the wired optical signal received from the optical line terminal into a plurality of wired optical signals,
A plurality of optical communication interfaces for outputting the plurality of wired optical signals to a connected optical communication device,
A first optical line management unit for measuring and outputting optical intensity of an optical line connecting the optical line terminal and the optical splitter using at least one optical sensor provided between the optical line terminal and the optical splitter,
And a plurality of optical sensors respectively provided between the optical splitter and the plurality of optical communication interfaces to measure a light intensity of each of the plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces, And,
Wherein the light intensity of the optical line is used for monitoring the state and performance of the optical line. 16. The method of claim 15,
The optical splitter comprises:
Wherein the optical line terminal is connected to an optical filter for filtering a wired optical signal multiplexed at one wavelength out of a plurality of wired optical signals multiplexed at different wavelengths output from the optical line terminal. 16. The method of claim 15,
And a controller for comparing the respective light intensities output from the first light path management unit and the second light path management unit with a predefined threshold and outputting the light intensity and corresponding optical path information less than the predefined threshold value to the server apparatus A control unit for transmitting, and
And an optical module connected to the optical splitter and transmitting an optical signal including information received from the controller to the server device,
Wherein the light intensity and the optical line information
Wherein the server device is used for monitoring the state and performance of the optical line. 16. The method of claim 15,
Further comprising a power supply control unit for outputting a plurality of power supply signals supplied from the power supply unit to the plurality of optical communication interfaces, respectively,
The plurality of optical communication interfaces include:
A wired optical signal and a power signal are transmitted to an optical communication device connected through a hybrid cable,
The hybrid cable includes:
An optical signal transmission line for outputting the wired optical signal, and a power supply line for outputting the power supply signal. The method of claim 18,
An optical module that receives a power-on command or a power-off command from the server device, and
Further comprising a controller for outputting the power-on command or the power-off command received from the optical module to the power control unit,
The power-
And a plurality of power switch ICs respectively connected to the plurality of optical communication interfaces and switched in accordance with the power-on command or the power-off command. 20. The method of claim 19,
An AC-DC converting unit connected to the plurality of power switch ICs, for converting the AC power to DC power and outputting the DC power to the power switch IC, and
An external power supply port for receiving external AC power and outputting the AC power to the AC-
Further comprising: a second optical signal processing unit for processing the optical signal.

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