KR102124531B1 - Apparatus for providing optical intergrated wired and wireless service at in-building and apparatus for processing wired optical signal - Google Patents

Abstract

An in-building wired/wireless optical integration device and a wired optical signal processing device are provided. This apparatus is a wired optical signal and a digital unit connected to at least one remote node (RN) that distributes an optical signal to a subscriber terminal and an optical line with the at least one remote node and received from the optical line terminal. And an optical mux (MUX) for concentrating to transmit the optical signal combined with the wireless optical signal received from the at least one remote node, wherein the at least one remote node demultiplexes the optical signal received from the optical line. The optical demux for a remote node outputting the wired optical signal and the wireless optical signal, a wired optical signal processing device for distributing the wired optical signal to a plurality of optical communication devices connected to a subscriber terminal, and the wireless optical signal. And a radio optical signal processing device that converts the radio frequency signal into a radio frequency signal and outputs the radio frequency signal to and from a subscriber terminal.

Description

In-building wired/wireless optical integrated device and wired optical signal processing device TECHNICAL FIELD

The present invention relates to a wired/wireless optical integration device and a wired optical signal processing device.

In-building networks are largely composed of wired and wireless networks. Currently, the wired network and the wireless network are constructed separately, so the landlord and the telecommunications operator must establish separate networks. By establishing separate wired/wireless equipment for each peer-to-peer environment based on copper wire, unshielded twisted pair cable (UTP), fiber, local area network (LAN), telephone line, coaxial, and radio frequency (RF) This results in high investment costs. As such, since wiring and equipment in a building cannot be shared by wired/wireless traffic, the cost of building an inbuilding infrastructure increases. Therefore, the in-building network needs to integrate wired and wireless networks.

Meanwhile, with the rapid increase in Internet traffic and the establishment of a wired/wireless integrated network, the development of optical subscriber technology represented by FTTH (Fiber-to-thehome) 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 branch device that does not require power supply as a remote node (RN).

Conventionally, an optical distribution box in which an optical line is introduced and distributed is composed of passive elements, and there is no separate operating program. Therefore, when a failure occurs in the optical line, there is a method to grasp the failure in real time. Since the operator can recognize the failure of the optical line only after confirming the failure in the equipment connected to the optical distribution box, it is impossible to monitor the state of the optical line in real time, which takes a lot of time to handle the optical line failure. have.

In addition, unlike the home network, the in-building network has a central control need at a remote location, such as a communication room. However, in the conventional in-building network, since data transmission and power supply are made separately, there is no way to control them collectively. Since a separate control system is required for batch control, this also increases the cost of building an inbuilding infrastructure.

An in-building wired/wireless optical integrated device that simplifies the inbuilding network structure by integrating all-fiber-based premises wiring to be solved by the present invention and enables real-time monitoring of optical lines and collective control of optical signals and power signals. It is to provide a wired optical signal processing device.

According to one feature of the present invention, the in-building wired/wireless optical integration device is connected to at least one remote node (RN) that distributes an optical signal to a subscriber terminal, and is connected to the at least one remote node through an optical line. And a converging optical mux (MUX) for transmitting an optical signal combining the wired optical signal received from the optical line terminal and the wireless optical signal received from the digital unit to the at least one remote node, and the at least one remote node. Is, optical demux for a remote node outputting a wired optical signal and a wireless optical signal by demultiplexing the optical signal received from the optical line, and distributing the wired optical signal to a plurality of optical communication devices connected to a subscriber terminal, respectively And a wireless optical signal processing device that converts the wireless optical signal into a radio frequency signal and outputs the wireless optical signal to a wireless signal processing device that transmits and receives the radio frequency signal to and from a subscriber terminal.

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

The wired optical signal processing apparatus may include: an optical splitter for separating wired optical signals received from the optical demux for the remote node into a plurality of wired optical signals; and a plurality of optical communications for outputting the plurality of wired optical signals to connected optical communication devices, respectively. Interface, a first for measuring and outputting light intensity of an optical line connecting the optical splitter for the remote node and the optical splitter using at least one optical sensor installed between the optical demux for the remote node and the optical splitter By measuring the optical intensity of a plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces by using a plurality of optical sensors respectively installed between the optical path management unit and the optical splitter and the plurality of optical communication interfaces, It may include a second optical path management unit to output.

The wired optical signal processing apparatus receives optical intensities from the first optical path management unit and the second optical path management unit, respectively, and when the received optical intensity falls outside an intensity within a predetermined threshold range, the corresponding optical line A control unit for transmitting information and light intensity information to a server device, and an optical module connected to the optical splitter and transmitting an optical signal including information received from the control unit to the server device may be further included.

The wired optical signal processing apparatus further includes a power supply control unit that outputs a plurality of power signals supplied from a power supply to the plurality of optical communication interfaces, and the plurality of optical communication interfaces hybridizes the wired optical signal and the power signal. Transmitting to an optical communication device connected through a cable, 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 signal.

The wired optical signal processing apparatus further includes a control unit outputting a power-on command or a power-off command to the power supply control unit, wherein the power supply control unit is respectively connected to the plurality of optical communication interfaces, and the power-on command or the power supply It may include a plurality of power switch IC that is 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 it to the control unit.

The wired optical signal processing apparatus is connected to each of the plurality of power switch ICs, and converts AC power into DC power and outputs the AC-DC converter to output the power switch IC, and receives the external AC power, and the AC- An external power port output to the DC converter may be further included.

The converging optical mux multiplexes a wired optical signal of the 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 be different from the second wavelength. The optical signal of the third wavelength is output to the optical line, and the optical demux for the remote node receives the optical signal of the third wavelength, and the wired optical signal of the first wavelength and the wireless optical signal of the second wavelength. Demultiplexing can be performed.

The third wavelength includes a plurality of different wavelengths, and the optical demux for the remote node is a plurality of optical demuxes that are selected from the different plurality of wavelengths and receive optical signals multiplexed at different wavelengths. It may include.

The optical node for the remote node is connected to at least two optical line terminals, receives the wired optical signal of the first wavelength from the optical line terminal in an active state, and one of the at least two optical line terminals The optical line terminal of the active state, the remaining optical line terminal may be in a standby (Standby) state.

According to another aspect of the present invention, the in-building wired/wireless optical integrated device includes a downlink wired optical signal of a first wavelength received from an optical line terminal and downlink wireless optical of a second wavelength different from the first wavelength received from a digital unit. The signals are multiplexed to output a downlink optical signal of a third wavelength different from the second wavelength, and the uplink optical signal of the third wavelength is an uplink wired optical signal of the first wavelength and an uplink wireless optical signal of the second wavelength. Separated by the optical line terminal and the digital unit for outputting to each of the optical mux (Mux) / demux (Demux), and the optical mux / demux for the convergence is connected through an optical line, remote in the building And at least one remote node (RN) installed in the at least one remote node to demultiplex the downlink optical signal to output a downlink wired optical signal and a downlink wireless optical signal, Optical demux/mux for a remote node outputting an uplink optical signal multiplexed with an uplink wired optical signal and an uplink wireless optical signal to the optical line, and the downlink wired optical signal with the subscriber station. Wired optical signal processing for distributing to a plurality of connected optical communication devices, and transmitting an uplink wired optical signal combining a plurality of uplink wired optical signals respectively received from the plurality of optical communication devices to the optical demux/mux for the remote node. The apparatus converts the downlink radio optical signal into a downlink radio frequency signal, transmits it to a radio signal processing device that transmits and receives radio frequency signals to and from a subscriber station, and transmits an uplink radio frequency signal received from the radio signal processing device. And a wireless optical signal processing device for converting the uplink wireless optical signal.

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

The third wavelength includes a plurality of different wavelengths, and the at least one remote node includes optical demux/mux for a remote node selected from the different plurality of wavelengths and using different wavelengths, respectively. can do.

According to another feature of the present invention, the wired optical signal processing apparatus outputs an optical splitter for separating a wired optical signal received from an optical line terminal into a plurality of wired optical signals, and respectively outputting the plurality of wired optical signals to a connected optical communication device. A first optical path management unit measuring and outputting light intensity of an optical line connecting the optical line terminal and the optical splitter using a plurality of optical communication interfaces and at least one optical sensor installed between the optical line terminal and the optical splitter And, by using a plurality of optical sensors that are respectively installed between the optical splitter and the plurality of optical communication interfaces, the optical intensity of a plurality of optical lines connecting the optical splitter and the plurality of optical communication interfaces is measured and output, respectively. It includes a two-beam management unit, and the light intensity of the optical line is used to monitor the condition and performance of the optical line.

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

The wired optical signal processing apparatus compares each light intensity output from the first optical path management unit and the second optical path management unit with a predetermined threshold, and corresponds to an optical intensity less than the predefined threshold. Further comprising a control unit for transmitting the optical line information to the server device, and an optical module connected to the optical splitter to transmit an optical signal including information received from the control unit to the server device, the light intensity and the Optical line information may be used to monitor the state and performance of the optical line in the server device.

The wired optical signal processing apparatus further includes a power supply control unit that outputs a plurality of power signals supplied from a power supply to the plurality of optical communication interfaces, and the plurality of optical communication interfaces hybridizes the wired optical signal and the power signal. Transmitting to an optical communication device connected through a cable, 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 signal.

The wired optical signal processing apparatus further includes an optical module that receives a power-on command or a power-off command from a server device, and a control unit that outputs the power-on command or the power-off command received from the optical module to the power supply control unit. The power supply control unit may include a plurality of power switch ICs that are respectively connected to the plurality of optical communication interfaces and are switched according to the power-on command or the power-off command.

The wired optical signal processing apparatus is connected to each of the plurality of power switch ICs, and converts AC power into DC power and outputs the AC-DC converter to output the power switch IC, and receives the external AC power, and the AC- An external power port output to the DC converter may be further included.

According to the exemplary embodiment of the present invention, the structure can be simplified and the scalability can be increased by integrating the all-fiber-based premises wiring, and the construction cost and OPEX (operational expenditure) can be reduced by applying the passive network method (POL). In addition, it is easy to accommodate 10G Internet and wireless 5G, which were difficult to implement with UTP and telephone lines in the past.

In addition, it is possible to provide a low-cost wired/wireless integrated infrastructure in an in-building environment through a structure optimized for a building premises environment requiring dense and short-distance transmission.

1 shows a configuration of an in-building wired/wireless integrated network according to an embodiment of the present invention.
2 is a diagram illustrating an example of wiring in a premises to which an in-building wired/wireless optical integration device according to an embodiment of the present invention is applied.
3 illustrates a dual 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 showing a detailed configuration of a wired optical signal processing apparatus according to another embodiment of the present invention.
7 shows a connection relationship between a control device according to the embodiment of FIG. 6 and a plurality of wired optical signal processing devices.
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 a method for managing an in-building line according to an embodiment of the present invention.
10 is a flowchart illustrating a method for managing an in-building line according to another embodiment of the present invention.
11 illustrates a configuration of an in-building wired/wireless integrated network according to another embodiment of the present invention.
12 is an example of wiring in a premises to which an in-building wired/wireless optical integration device according to another embodiment of the present invention is applied.
13 is a hardware block diagram of a server device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part “includes” a certain component, this means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

In addition, terms such as “…unit”, “…group”, and “…module” described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. Can be.

In this specification, expressions expressed in singular may be interpreted as singular or plural unless explicit expressions such as “one” or “single” are used.

In this specification, the wireless communication system is a CCC (Cloud Communication) that separates a base station into a digital unit (hereinafter referred to as'DU') and a radio frequency unit (hereinafter referred to as'RFU'). Center) technology.

Here, the DU is a configuration for processing a digital signal of a base station, and is composed of a channel card that encrypts and decrypts wireless digital signals such as 3G and Long Term Evolution (LTE), and is mainly implemented as a DU concentration center in a telecommunications company. The RFU is installed in the service area, amplifies the RF signal and transmits the amplified RF signal through the antenna.

1 is a diagram showing the configuration of an in-building wired/wireless integrated network according to an embodiment of the present invention, and FIG. 2 is an exemplary wiring diagram applied to an in-building wired/wireless optical integrated device according to an embodiment of the present invention. It shows a duplex structure of an optical line terminal (hereinafter referred to as'OLT') according to an embodiment of the present invention.

First, referring to FIG. 1, the in-building wired/wireless optical integration device 100 is a device for integrating all-fiber-based premises wiring in in-building, and combines wireless communication signals and wired communication signals based on light. And dispense. At this time, the in-building wired/wireless optical integration device 100 monitors the optical line in the in-building and simultaneously controls transmission of a wired optical signal and supply of a power signal.

The in-building wired/wireless optical integration device 100 includes an optical mux (MUX)/demux (DEMUX) 110 and at least one remote node (hereinafter referred to as'RN') 120.

The optical mux/demux 110 and the at least one RN 120 are spaced apart from each other and connected through an optical line. The optical mux/demux 110 is mainly installed in an in-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 mux/demux 110 performs aggregation functions of downlink optical signals and uplink optical signals of subscriber terminals 600 in the in-building. At least one RN 120 distributes the downlink optical signal and the uplink optical signal of the subscriber stations 600 in the in-building for each subscriber.

The optical mux/demux 110 is connected to the OLT 200 through an optical line. The optical mux/demux 110 is connected to the main hub unit (hereinafter referred to as'MHU') 300 through an optical line.

The RN 120 includes an optical demux/mux 130, a wired optical signal processing apparatus 150, and a wireless optical signal processing apparatus 170. Each of these components (110, 130, 140, 150) is implemented to be detachable in a modular manner, and can be installed spaced apart from each other at a remote location.

The optical demux/mux 130 is connected to the optical mux/demux 110 through an optical line. The optical demux/mux 130 is connected to the wired optical signal processing apparatus 150 and the wireless optical signal processing apparatus 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 may be used as the optical line. The optical line leads to the building unit.

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

The OLT 200 is installed in the in-building communication room, and is connected to the aggregation switch 700 by 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. A service provider server 1100 and an in-building line management server 1200 are connected to the network 1000.

The optical mux/demux 110 may be installed in a communication terminal box or a main distribution frame (MDF) in the in-building communication room. The RN 120 may be installed at an intermediate point in the inbuilding, for example, a partial layer (eg, an intermediate layer) of the entire floor, or a communication terminal box or a main distribution panel in units of every floor.

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

For example, RNs 120-1 and 120-2 may be implemented as many as the number of building floors. That is, in a 10-story building, 10 RNs 120-1 and 120-2 can be implemented.

Further, the RNs 120-1 and 120-2 may be implemented in traffic load balancing units. For example, assuming that 10G passive optical network (PON) service is possible with one wavelength, 100G PON service with 10 wavelengths can be considered. At this time, when the wavelength of the wired optical signal output by the OLT 200 is λ ₁ and the wavelength of the wireless optical signal output by the MHU 300 is λ ₂ , the integrated light output by the optical mux/demux 110 is output. The wavelength of the signal can be defined as a total of 10 wavelengths. Then, since the optical demux/mux 130 of the RNs 120-1 and 120-2 is implemented as many as 10 wavelengths, the total number of 10 RNs 120-1 and 120-2 is implemented. do. At this time, if the wavelength of the integrated optical signal generated by the MUX/Dmux 110 is controlled, each of the RNs 120 is configured such that wired data and wireless data in the in-building are not concentrated in a specific optical communication device 400 or RFU 500. -1, 120-2) can be evenly distributed to the optical demux/mux 130.

Therefore, if 1G PON service was previously provided by one RN 120, 10G PON service can be implemented by 10 RNs 120-1 and 120-2. According to this embodiment, when a large amount of traffic flows into the in-building, it is possible to achieve the effect of load balancing by distributing and transmitting the traffic with different wavelengths.

Referring to FIG. 1 again, the optical mux/demux 110 multiplexes downlink optical signals having different wavelengths into one downlink optical signal. The optical mux/demux 110 receives the downlink wired optical signal of the first wavelength λ ₁ from the OLT 200. The downlink wired optical signal includes downlink data provided through an Internet operator network. The optical mux/demux 110 receives the downlink wireless optical signal of the second wavelength λ ₂ different from the first wavelength λ ₁ from the MHU 300. The downlink wireless optical signal includes downlink data provided through a mobile communication service provider 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 ( Multiplexed with the downlink optical signal of λ ₃ ) and transmitted to the optical demux/mux 130 through the optical line.

The optical mux/demux 110 demultiplexes one uplink optical signal into uplink optical signals of different wavelengths. The optical mux/demux 110 receives an uplink optical signal of a third wavelength (λ ₃ ) from an optical line connected to the optical demux/mux 130. The optical mux/demux 110 converts an uplink optical signal of the third wavelength (λ ₃ ) into an uplink wired optical signal of the first wavelength (λ ₁ ) and an uplink wireless optical signal of the second wavelength (λ ₂ ). Demultiplex. The optical mux/demux 110 outputs the uplink wired optical signal of the first wavelength λ ₁ to the OLT 200. The optical mux/demux 110 outputs an uplink wireless optical signal of the second wavelength λ ₂ to the MHU 300. The uplink wired optical signal includes uplink data to be provided to the Internet operator network, and the uplink wireless optical signal includes uplink data to be provided to the mobile communication provider network.

The optical demux/mux 130 receives the downlink optical signal of the third wavelength (λ ₃ ) from the optical mux/demux 110, and receives the uplink optical signal of the third wavelength (λ ₃ ) as the optical mux/ Demux 110. The optical demux/mux 130 is connected to the wired optical signal processing apparatus 150 and the wireless optical signal processing apparatus 170.

The optical demux/mux 130 demultiplexes the downlink optical signal into the downlink optical signals of different wavelengths. The optical demux/mux 130 converts the downlink optical signal of the third wavelength (λ ₃ ) into a downlink wired optical signal of the first wavelength (λ ₁ ) and a downlink wireless optical signal of the second wavelength (λ ₂ ). Demultiplex. The optical demux/mux 130 outputs the downlink wired optical signal of the first wavelength λ ₁ to the wired optical signal processing apparatus 150. The optical demux/mux 130 outputs the downlink wireless optical signal of the second wavelength λ ₂ to the wireless optical signal processing device 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 is the uplink wired optical signal of the first wavelength (λ ₁ ) received from the wired optical signal processing apparatus 150 and the second wavelength (λ) received from the wireless optical signal processing apparatus 170. The uplink wireless optical signal of ₂ ) is multiplexed with the uplink optical signal of the third wavelength (λ ₃ ).

Here, the optical mux/demux 110 and the optical demux/mux 130 may be wavelength division multiplexing (WDM) filters.

The wired optical signal processing apparatus 150 combines and distributes wired optical signals transmitted and received 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 demux/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 wireless optical signal processing device 170 is connected to the optical demux/mux 130 through an optical line, and the RFU 500 and a radio frequency (hereinafter referred to as'RF') cable, for example It is connected through a coaxial cable. The wireless optical signal processing device 170 converts the downlink wireless optical signal received from the optical demux/mux 130 into a downlink RF signal and transmits it to the RFU 500. The wireless optical signal processing device 170 converts the uplink RF signal received from the RFU 500 into an uplink wireless optical signal and transmits it to the optical demux/mux 130.

The OLT 200 may be connected to the aggregation switch 700 through an unshielded twisted pair (UTP) cable, a phone line, a power line, a coaxial cable, or a fiber cable. 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 λ ₁ received from the optical line connected to the optical mux/demux 110 into wired data and transmits the wired optical signal to the aggregation switch 700.

At this time, the OLT 200 may be implemented as a dual structure, as shown in FIG. 3. Referring to FIG. 3, the OLT1 201 in the active mode and the OLT2 203 in the standby mode are connected to the optical mux/demux 110.

The optical mux/demux 110 receives a wired optical signal from the OLT1 201 in active mode. When a failure occurs in the OLT1 201, the OLT2 203 in the standby mode is switched to the active mode, and a wired optical signal is transmitted to the optical mux/demux 110. At this time, the inbuilding OLT1 201 and the inbuilding OLT2 203 may use the same wavelength or different wavelengths.

Referring to FIG. 1 again, the MHU 300 accommodates a multi-band wireless service, and receives RF digital data received from the DU 800 as a wireless optical signal of a second wavelength (λ ₂ ). To convert. The MHU 300 photoelectrically converts the wireless optical signal of the second wavelength (λ ₂ ) received from the optical line connected to the optical mux/demux 110 into RF digital data and transmits the RF optical data 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 apparatus 150 into an Ethernet signal, and converts the Ethernet signal into a wired or wireless subscriber terminal 600 ). The optical communication device 400 converts the Ethernet signal received from the subscriber terminal 600 by wire or wirelessly into a wired optical signal of the first wavelength λ ₁ and transmits it to the wired optical signal processing apparatus 150.

The optical communication device 400 provides a PON (Passive Optical Network) subscriber interface, and may perform a one-to-one (1:N) connection with the subscriber terminal 600. The optical communication device 400 includes an optical network unit (ONU), an optical network terminal (ONT), an optical module in the form of a stick or a card. ONU is a small outdoor/indoor optical communication device installed in the center of a residential subscriber dense area. ONT is an optical modem device that can be connected to a PC as a final optical termination 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 in a stick type or a card type.

The RFU 500 amplifies the RF signal received from the wireless optical signal processing device 170 to match the transmission output, and amplifies the RF signal to transmit it to the subscriber terminal 600 by radiating it through the air through the transmission antenna TX Ant. Then, the RF signal received from the subscriber terminal 600 through the reception antenna (RX Ant) is amplified and output to the wireless optical signal processing device 170.

The subscriber terminal 600 is a terminal that receives data services, telephone services, etc., for example, an Internet telephone terminal, IPTV, PC, Internet of things (IoT) device, electronic devices in the home, mobile phones, PDAs, smart phones, etc. Mobile devices, notebooks, and the like.

The aggregation switch 700 is installed in the company, 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 company, and outputs uplink data received from the MHU 300 to the backbone switch 900 and transmits downlink data received from the backbone switch 900 to the MHU 300.

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

The network 1000 may include a broadband network such as the Internet or Fiber To The x (FTTx) including FTTH (Fiber To The Home).

The service provider server 1100 is a server that provides data services to subscribers, and may include, for example, a server that provides Internet Protocol Television (IPTV) service, an Internet Portal server, and a broadcast content server. It may be a service provider server that performs subscriber's Internet service policy and network management.

The in-building line management server 1200 is installed in the government office and controls information from the wired/wireless optical integration device 100 through a path formed by the network 1000-backbone switch 900-aggregation switch 700-OLT 200. To receive. Here, the control information includes optical line/power monitoring information, digital diagnostic monitoring information (hereinafter referred to as DDMI), and PON OAM (Operations, Administration and Maintenance) information.

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

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

In addition, the in-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 Can be. At this time, the wired optical signal processing apparatus 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 a power-on command or a power-off command. Can decide. Therefore, it is possible to control the optical communication device 400 without going to the field from a remote location.

In addition, the in-building line management server 1200 compares and checks the line number sheet input from the wired optical signal processing apparatus 150 and the stored line number sheet. Here, the line number is a document for allocating and managing line numbers of optical lines, and means a document for managing line usage history allocated in each system. The information on the number of ships is manually checked and collected by the operator and managed in the form of electronic documents (for example, Excel documents). Information on the number of ships is classified and stored by region/equipment, and it is possible to search or modify the number of ships at the request of the operator's computer.

The in-building line management server 1200 may manage the line number remotely by comparing the line number received from the wired optical signal processing apparatus 150 with the stored line number. Accordingly, unlike the conventional method in which a worker labels an optical cable and manually inputs a document in the field, it is possible to automatically manage a ship number management at a remote location through the wired optical signal processing device 150.

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

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

Referring to FIG. 4, the wired optical signal processing apparatus 150 includes an optical splitter 141, a plurality of optical communication interfaces 152, an upper optical path management unit 153, a subscriber optical path management unit 154, and power feeding. It includes a control unit 155.

The optical splitter 151 branches or couples the optical signal to 1:N. The optical splitter 151 branches 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 N optical communication interfaces 152 and outputs one wired optical signal to the optical demux/mux 130.

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

At this time, the plurality of optical communication interfaces 152 are respectively connected to the plurality of optical communication devices 400 through a hybrid cable. 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 signal. Accordingly, the wired optical signal and the power signal are simultaneously transmitted to the optical communication device 400. At this time, a method of transmitting the wired optical signal and the power signal at the same time may be a POE (Power Over Ethernet) method. As such, by simultaneously transmitting the wired optical signal and the power signal through a single cable, it is possible to reduce the cost of installing a separate power supply.

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 is a photo diode (photo diode) is used. The photodiode measures the intensity (Power) of the optical signal and converts the measurement intensity into an electrical signal.

The upper optical path management unit 153 outputs the light intensity of the upper optical path connecting the optical demux/mux 130 and the optical splitter 151 measured through at least one optical sensor 156 to the control unit 157. .

At this time, the upper optical path management unit 153, as shown in Figure 5, the optical sensor installed in the upper optical line connected to the active state of the OLT (201), and is installed in the upper optical path connected to the standby state of the OLT (203) It may include a light sensor.

The subscriber optical path management unit 154 includes a plurality of optical sensors 156 respectively installed between the optical splitter 151 and the plurality of optical communication interfaces 152.

The subscriber optical path management unit 154 sets the light intensity of the 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 a plurality of power signals to the plurality of optical communication interfaces 152, respectively.

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

The plurality of power switch ICs 158 are switched to the off state according to a power off command. Then, the power signal is not supplied to the optical communication interface 152. Here, the power-on command and the power-off command may be received for each optical communication interface 152 or collectively.

The control unit 157 receives the light intensity of the upper optical path from the upper optical path management unit 153, and receives the light intensity of the subscriber optical path from the subscriber optical path management unit 154. When the intensity of the received optical line exceeds the intensity within a predetermined threshold range, the controller 157 transmits the corresponding optical line information and optical intensity information to the inbuilding line management server 1200 through the optical module 161. send.

The inbuilding line management server 1200 may monitor the upper optical line control section and the subscriber optical line control section, respectively, based on the received optical line information and light intensity information.

At this time, the control unit 157 may check the optical line information using the line number information stored in the memory 159. Line number information is input from the operator through the input unit 160. The line number information may be transmitted to the in-building line management server 1200 and compared to the line number information stored in the in-building line management server 1200.

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

In addition, the control unit 157 may transmit power control information to the inbuilding line management server 1200 according to a request of the inbuilding line management server 1200 or according to a cycle stored in the memory 159. That is, the state in which power is supplied may be reported to the in-building line management server 1200. For example, the control unit 157 may report whether the power is stabilized, information of the optical communication device 400 that is supplying power, power consumption 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 control unit 157 in addition to the line number information.

At this time, as shown in FIG. 6, the control unit 157, the memory 159, and the input unit 160 may be implemented as a control device 164 which is a separate physical device from the wired optical signal processing device 150. Referring to FIG. 7, one control device 164 may be connected to a plurality of wired optical signal processing devices 150 to control operations 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 control unit 157 in an optical signal to thereby include an optical splitter 151-optical demux/mux 130-optical mux/demux ( 110)-OLT 200-converged switch 700-backbone switch 900-transmits to the in-building line management server 1200 through the path of the network 1000.

The optical module 161 is a network 1000-backbone switch 900-aggregation switch 700-OLT 200-optical mux/demux 110-optical demux/mux 130-optical splitter 151 ) Receives a power-on command or a power-off command from the in-building line management server 1200 and outputs it to the control unit 157.

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

The external power port 163 receives external AC power and outputs it to an AC (AC)-to-DC (DC) converter 162.

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

Referring to FIG. 8, the wireless optical signal processing device 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 wireless optical signal received from the optical demux/mux 130 into a downlink digital signal through photoelectric conversion. The digital processing unit 171 converts an uplink digital signal into an uplink wireless optical signal through all-optical conversion and outputs it to the optical demux/mux 130.

The RF processing unit 173 converts and outputs the downlink digital signal output from the digital processing unit 171 into an RF signal in a frequency form used by the RFU 500 connected through the coaxial socket 175. The RF processing unit 173 converts the uplink RF signal received from the RFU 500 through the coaxial socket 175 into an uplink digital signal and outputs it to the digital processing unit 171.

The RF processing unit 501 of the RFU 500 amplifies the RF signal received from the wireless optical signal processing device 170 through the coaxial socket 503 to match the transmission output and amplifies the RF signal to the air through the antenna 505. . The RF processing unit 501 of the RFU 500 amplifies the RF signal received through the antenna 505 and transmits it to the wireless optical signal processing device 170 through the coaxial socket 503.

9 is a flowchart illustrating a method for managing an inbuilding line according to an embodiment of the present invention, and shows a method for monitoring an optical line.

Referring to FIG. 9, the control unit 157 receives a detection signal including the light intensity of the upper optical line from the upper optical path management unit 153 and includes the light intensity of the subscriber optical line from the subscriber optical path management unit 154. Receiving a detection signal (S101).

The controller 157 determines whether there is an optical line that is less than a preset threshold among the light intensities of the received optical lines (S101) (S103). If not, start again from step S101.

On the other hand, if an optical line having a light intensity less than a threshold exists, the optical line information is checked 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 inbuilding 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 in-building line management server 1200 receives optical intensity and subscriber optical line information of the subscriber optical lines measured by the plurality of optical communication devices 400 from the plurality of optical communication devices 400 (S111, S113).

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

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

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

The in-building line management server 1200 transmits a power-on command to the control unit 157 according to the determination (S201) (S203). The control unit 157 controls to output a power signal to the corresponding optical communication device 400 according to a power-on command (S205). That is, a power signal is output 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 in-building line management server 1200 transmits a power-off command to the control unit 157 according to the determination (S201) (S207). The control unit 157 controls to block the power signal of the corresponding optical communication device 400 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 cut off the supply of the power signal.

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

11 is a diagram illustrating a configuration of an in-building wired/wireless integrated network according to another embodiment of the present invention, and FIG. 12 is an exemplary wiring diagram applying an in-building wired/wireless optical integrated device according to another embodiment of the present invention.

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

The optical mux/demux 111 multiplexes a downlink wired optical signal of a plurality of first wavelengths (λ ₁ ) from the OLT 200 toward a plurality of subscriber terminals 600 to down the third wavelength (λ ₃ ). Generate a link optical signal. The optical mux/demux 111 outputs the downlink optical signal of the third wavelength λ ₃ to at least one wired optical signal processing apparatus 150. And the uplink optical signal of the third wavelength (λ ₃ ) received from the plurality of subscriber terminals 600 through at least one wired optical signal processing apparatus 150 is uplink wired of the plurality of first wavelengths (λ ₁ ). It is separated into optical signals and output 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, and the inbuilding line management server 1200 is shown in FIGS. This is the same as the configuration described in FIG. 10.

Referring to FIG. 12, one optical mux/demux 111 may be connected to a plurality of (n) 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 light wavelength used in the optical line connected between the optical mux/demux 111 and RN1 (120-3) and the light used in the optical line connected between the optical mux/demux 111 and RNn (120-4) The wavelengths are different. Each optical filter 190 passes an optical signal of an optical wavelength used by the RNs 120-3 and 120-4 and outputs it to the wired optical signal processing apparatus 150.

According to an embodiment, a plurality of (n) RNs 120-3 and 120-4 may be implemented as many as the number of building floors. That is, in a 10-story building, 10 RNs 120-3 and 120-4 may be implemented.

According to another embodiment, the plurality of (n) RNs 120-3 and 120-4 may be implemented in a traffic load balancing unit. For example, assuming that 10G passive optical network (PON) service is possible with one wavelength, 100G PON service with 10 wavelengths can be considered. At this time, when the wavelength of the wired optical signal output by the OLT 200 is λ ₁ , the wavelength of the integrated optical signal output by the optical mux/demux 111 may be defined as a total of 10 wavelengths. Then, each of the plurality of (n) RN (120-3, 120-4) of the optical filter 190 is implemented by the number of filters for 10 wavelengths, so a total of 10 RN (120-3, 120-4) ). At this time, if the wavelength of the integrated optical signal generated by the MUX/Dmux 110 is controlled, the RNs 120-3 and 120-4 of the respective RNs are prevented from being concentrated in a specific optical communication device 400 in the in-building. It can be evenly distributed to the optical filter 190.

Therefore, if 1G PON service was previously provided by one RN 120, 10G PON service can be implemented by 10 RNs 120-3 and 120-4. According to this embodiment, when a large amount of traffic flows into the in-building, it is possible to achieve the effect of load balancing by distributing and transmitting the traffic with different wavelengths.

Meanwhile, FIG. 13 is a hardware block diagram of a server device according to an embodiment of the present invention, and shows the hardware configuration of the in-building line management server 1200 described with reference to FIGS. 1 to 12.

Referring to FIG. 13, the 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 and transmits and/or receives data through the network 1000. The memory 1303 is connected to the at least one processor 1307 and includes an in-building line management program including instructions to execute a configuration and/or method according to the embodiments described with reference to FIGS. 1 to 12. To save. The in-building line management program implements the present invention in combination with hardware such as a memory 1303 and at least one processor 1307.

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

The embodiment of the present invention described above is not implemented only through an apparatus and method, and may be implemented through a program that realizes a function corresponding to the configuration of the embodiment of the present invention or a recording medium in which the program is recorded.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (20)

At least one remote node (RN) that distributes the optical signal to the subscriber terminal, and
An optical mux for convergence connected to the at least one remote node through an optical line and 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. (MUX),
The at least one remote node,
An optical demux for a remote node that demultiplexes the optical signal received from the optical line to output a wired optical signal and a wireless optical signal;
Wired optical signal processing device for distributing each of the wired optical signals to a plurality of optical communication devices connected to a subscriber terminal, and
And a wireless optical signal processing device that converts the wireless optical signal into a radio frequency signal and outputs it to a wireless signal processing device that transmits and receives the radio frequency signal with a subscriber terminal.
The wired optical signal processing device,
Measuring the light intensity of the upper optical line connected to the optical demux for the remote node,
The optical strengths of a plurality of subscriber optical lines connected to the plurality of optical communication devices are respectively measured, and an in-building line managing optical intensity information outside a predetermined threshold range and corresponding optical line information among the measured optical intensities is managed. To the server device,
The light intensity information and the corresponding optical line information outside the predefined threshold range are
An in-building wired/wireless optical integrated device, used by the server device to monitor performance data of optical lines at remote locations and check whether a failure has occurred. In claim 1,
The wired optical signal processing device,
An in-building wired/wireless optical integration device that measures the optical intensity of the optical line and transmits it to a server device, and simultaneously transmits the wired optical signal and power signal to the plurality of optical communication devices. In claim 2,
The wired optical signal processing device,
An optical splitter that separates 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, each outputting the plurality of wired optical signals to a connected optical communication device,
A first optical path measuring and outputting light intensity of an optical line connecting the optical demux for the remote node and the optical splitter using at least one optical sensor installed between the optical demux for the remote node and the optical splitter Management, and
A second light beam that measures and outputs light intensities of a plurality of optical lines respectively connecting the optical splitter and the plurality of optical communication interfaces by using a plurality of optical sensors respectively installed between the optical splitter and the plurality of optical communication interfaces. Furnace management department
Including, in-building wired and wireless optical integration device. In claim 3,
The wired optical signal processing device,
When receiving the light intensity from the first optical path management unit and the second optical path management unit, respectively, and the received light intensity is outside an intensity within a predetermined threshold range, the corresponding optical line information and light intensity information are received from the server device. The control unit to transmit, and
An optical module connected to the optical splitter and transmitting an optical signal including information received from the control unit to the server device
Further comprising, in-building wired and wireless optical integration device. In claim 4,
The wired optical signal processing device,
Further comprising a power supply control unit for outputting a plurality of power signals supplied from the power supply to each of the plurality of optical communication interface,
The plurality of optical communication interfaces,
The wired optical signal and the power signal are transmitted to an optical communication device connected through a hybrid cable,
The hybrid cable,
And an optical signal transmission line for outputting the wired optical signal and a power supply line for outputting the power signal. In claim 5,
The wired optical signal processing device,
Further comprising a control unit for outputting a power-on command or a power-off command to the power supply control unit,
The power supply control unit,
And a plurality of power switch ICs respectively connected to the plurality of optical communication interfaces and switched according to the power-on command or the power-off command. In claim 6,
The wired optical signal processing device,
An optical module that receives the power-on command or the power-off command from the optical splitter and outputs it to the control unit
Further comprising, in-building wired and wireless optical integration device. In claim 7,
The wired optical signal processing device,
An AC-DC converter connected to the plurality of power switch ICs, and converting AC power into DC power to output the power switch IC; and
External power port that receives external AC power and outputs it to the AC-DC converter
Further comprising, in-building wired and wireless optical integration device. In claim 1,
The optical mux for concentrating,
The optical signal of the third wavelength different from the second wavelength is multiplexed by multiplexing the wired optical signal of the first wavelength received from the optical line terminal and the wireless optical signal of the second wavelength different from the first wavelength received from the digital unit. Output to the optical line,
The optical demux for the remote node,
An in-building wired/wireless optical integration device receiving the third wavelength optical signal and performing demultiplexing with the first wavelength wired optical signal and the second wavelength wireless optical signal. In claim 9,
The third wavelength,
It includes a plurality of different wavelengths,
The optical demux for the remote node,
An in-building wired/wireless optical integration device including a plurality of optical demuxes receiving optical signals selected from the plurality of different wavelengths and multiplexed with different wavelengths. In claim 9,
The optical node for the remote node,
It is connected to at least two optical line terminals, and receives a wired optical signal of the first wavelength from an optical line terminal in an active state,
An in-building wired/wireless optical integration device, wherein one of the at least two optical line terminals is in an active state, and the remaining optical line terminals are in a standby state. The downlink wired optical signal of the first wavelength received from the optical line terminal and the downlink wireless optical signal of the second wavelength different from the first wavelength received from the digital unit are multiplexed to down the third wavelength different from the second wavelength. Outputting a link optical signal, separating the uplink optical signal of the third wavelength into an uplink wired optical signal of the first wavelength and an uplink wireless optical signal of the second wavelength, and outputting the optical signal to the optical line terminal and the digital unit, respectively. Concentration optical mux/demux, and
It includes at least one remote node (RN) connected to the convergence optical mux/demux via an optical line and installed at a remote location in the in-building,
The at least one remote node,
A remote that demultiplexes the downlink optical signal to output a downlink wired optical signal and a downlink wireless optical signal, and outputs an uplink optical signal multiplexed with an uplink wired optical signal and an uplink wireless optical signal to the optical line. Optical Demux/Mux for nodes,
Each of the downlink wired optical signals is distributed to a plurality of optical communication devices connected to a subscriber terminal, and an uplink wired optical signal combining a plurality of uplink wired optical signals respectively received from the plurality of optical communication devices is used for the optical node for the remote node. Wired optical signal processing device to transmit to MUX/MUX, and
The downlink radio optical signal is converted into a downlink radio frequency signal, transmitted to a radio signal processing device that transmits and receives radio frequency signals to and from a subscriber station, and uplinks the radio frequency signal received from the radio signal processing device. It includes a wireless optical signal processing apparatus for converting to a wireless optical signal,
The wired optical signal processing device,
Measuring the light intensity of the upper optical line connected to the optical demux for the remote node,
The optical strengths of a plurality of subscriber optical lines respectively connected to the plurality of optical communication devices are measured, and among the measured optical intensities, managing an inbuilding line of light intensity information outside a predetermined threshold range and corresponding optical line information To the server device,
The light intensity information and the corresponding optical line information outside the predefined threshold range are
An in-building wired/wireless optical integrated device, used by the server device to monitor performance data of optical lines at remote locations and to check whether a failure has occurred. In claim 12,
The wired optical signal processing device,
An in-building wired/wireless optical integration device that monitors the optical intensity of the optical line and simultaneously controls downlink optical signal transmission and power supply to the plurality of optical communication devices. In claim 12,
The third wavelength includes a plurality of different wavelengths,
The at least one remote node,
And an optical demux/mux for a remote node each selected from the different plurality of wavelengths and using different wavelengths, respectively. An optical splitter for separating a wired optical signal received from an optical line terminal into a plurality of wired optical signals,
A plurality of optical communication interfaces, each outputting the plurality of wired optical signals to a connected optical communication device,
A first optical path management unit for measuring and outputting light intensity of an optical line connecting the optical line terminal and the optical splitter by using at least one optical sensor installed between the optical line terminal and the optical splitter, and
A second light beam that measures and outputs light intensities of a plurality of optical lines respectively connecting the optical splitter and the plurality of optical communication interfaces by using a plurality of optical sensors respectively installed between the optical splitter and the plurality of optical communication interfaces. Including furnace management department,
The light intensity of the optical line is used to monitor the condition and performance of the optical line, wired optical signal processing apparatus. In claim 15,
The optical splitter,
A wired optical signal processing apparatus connected to an optical filter for filtering a wired optical signal multiplexed with one wavelength among a plurality of wired optical signals multiplexed with different wavelengths output by the optical line terminal. In claim 15,
Each light intensity output from the first optical path management unit and the second optical path management unit is compared with a predefined threshold value, and an optical intensity less than the predefined threshold value and corresponding optical line information are transmitted to a server device. Control unit to transmit, and
It is further connected to the optical splitter, further comprising an optical module for transmitting an optical signal including information received from the control unit to the server device,
The light intensity and the optical line information,
A wired optical signal processing device, which is used to monitor the state and performance of the optical line in the server device. In claim 15,
Further comprising a power supply control unit for outputting a plurality of power signals supplied from the power supply to each of the plurality of optical communication interface,
The plurality of optical communication interfaces,
The wired optical signal and the power signal are transmitted to an optical communication device connected through a hybrid cable,
The hybrid cable,
And an optical signal transmission line for outputting the wired optical signal and a power supply line for outputting the power signal. In claim 18,
An optical module receiving a power-on command or a power-off command from the server device, and
Further comprising a control unit for outputting the power-on command or the power-off command received from the optical module to the power supply control unit,
The power supply control unit,
And a plurality of power switch ICs respectively connected to the plurality of optical communication interfaces and switched according to the power-on command or the power-off command. In claim 19,
An AC-DC converter connected to the plurality of power switch ICs, and converting AC power into DC power to output the power switch IC; and
External power port that receives external AC power and outputs it to the AC-DC converter
Further comprising, a wired optical signal processing apparatus.

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