KR20190070148A - System for identifyimg a structure of network, central office terminal and identifyimg method a structure of network - Google Patents

Abstract

The present invention proposes a system for identifying a structure of a network that a central office device may accurately identify a structure of an optic ring network such as an installation position of a remote node in an optical network system without an operator being manually involved, a central office device applied thereto, and a method for identifying a structure of a network performed in the device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for identifying a network structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication network system, and more particularly, to a technology for grasping the structure of an optical ring network to which a central office terminal (COT) is connected in an optical communication network system of a WDM (Wavelength Division Multiplexing) .

In the LTE communication system, a method of separating a base station into a base band unit (BBU) and a remote radio head (RRH), and installing the base station at a remote location based on a connection using an optical line is generally applied. In such a base station structure, as the BBU is centralized in one place, several RRHs are connected to one BBU.

In this case, a WDM (Wavelength Division Multiplexing) front hole (Fronthaul) equipment is used between the BBU and the RRH to reduce the optical fiber cost, and a line redundancy scheme is applied to stabilize the operation of the equipment.

In the implementation of such a WDM type front hole equipment, a remote node (RN) using a passive optical device, which is easy to install and has fewer obstacles and fewer defects, has been gradually expanded.

However, in the case of the remote node, since the installation position is irregular and diversified due to the installation cost problem or the designation of the installation position of the landmark, it is difficult to grasp the installation position.

In other words, in order to grasp the installation location of the remote node, the user has to know the geographical installation location of the remote node in advance or directly measure the distance to obtain the distance information. Information was manually managed / managed.

Therefore, in case of remote node, in order to maintain the equipment and manage faults, the operator needs to know the installation location of the remote node. Since the reliability of the information manually managed and managed by the operator is degraded, There is a disadvantage in that it is difficult to know and there is a disadvantage that the operator takes a lot of time and money to manually manage the information.

Accordingly, the present invention proposes a new technique for accurately grasping the structure of the optical ring network, such as the installation position of the remote node at the system side.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances and an object of the present invention is to provide a new method for accurately detecting the structure of an optical ring network such as an installation position of a remote node in an optical network system Technology), a network structure identification system, and a method of identifying a network device structure and a network device within the state.

According to a first aspect of the present invention, there is provided a network structure identification system, comprising: a plurality of remote nodes, each of which has a selective reflection unit that reflects only a monitoring optical signal of a predetermined wavelength, ); A monitoring optical signal connected to the plurality of remote nodes through an optical ring network and having a reflection wavelength set in each of the plurality of remote nodes and a passing wavelength passing through each of the plurality of remote nodes, A central office terminal for transmitting in at least one of two directions of the optical ring network; Wherein the optical path switching apparatus comprises an optical path switching unit for switching the optical path between the optical ring network and the optical ring network based on an optical signal received from the remote node through the plurality of remote nodes from one direction, And recognizes the remote node installation structure on the optical ring network.

According to a second aspect of the present invention, there is provided an apparatus within an office of nationalities, comprising: a plurality of remote nodes connected to the apparatus in the state of the art and an optical ring network, A remote node monitoring optical signal processor for generating and transmitting a node monitoring optical signal; A network monitoring unit for generating and transmitting a network monitoring optical signal having a pass wavelength passing through each of the plurality of remote nodes; A transmitting unit for transmitting the remote node monitoring optical signal and the network monitoring optical signal in at least one direction of both directions of the optical ring network; And a network monitoring optical signal received through the plurality of remote nodes from an optical signal for remote node monitoring reflected from and received from a remote node from both directions of the optical ring network, And a control unit for recognizing the optical ring network installation structure.

Specifically, the control unit controls the transmission direction of the optical ring network in both directions by using the time at which the remote node monitoring optical signal is transmitted and the time at which the remote node monitoring reflected by each of the plurality of remote nodes is received. Calculates the total distance of the optical ring network using the time at which the network monitoring optical signal is transmitted and the time at which the network monitoring optical signal is transmitted and calculates the distance between the device and the remote node, It is possible to grasp the remote node installation structure in both directions of the optical ring network based on the distance between the remote node and the calculated total distance.

Specifically, the transmitting unit transmits the remote node-monitoring optical signal of the reflected wavelength set to some remote nodes among the plurality of remote nodes in both directions of the optical ring network in a first direction, The remote node monitoring optical signal having a wavelength of the reflected wave set in the remote node other than the part is transmitted in the second direction, and the network monitoring optical signal can be transmitted in the first direction or the second direction.

Specifically, some of the remote nodes may be remote nodes whose distance from the apparatus within the national office among the plurality of remote nodes is closer to the second direction in the first direction, and the remaining remote nodes may include a plurality of remote nodes May be a remote node closer to the first direction than the first direction in the second direction.

Specifically, the control unit determines whether to change the remote node connection order in both directions of the optical ring network based on the stored remote node connection order information based on the result of grasping the remote node installation structure in both directions of the optical ring network Can be detected.

Specifically, when the remote node monitoring optical signal received from one direction other than the transmission direction in both directions of the optical ring network is identified, the control unit determines whether the reflected wavelength of the optical signal for remote node monitoring The node can be detected as a connection error.

Specifically, the control unit can detect whether or not a connection error related to another optical ring network has occurred in the optical ring network, based on the network monitoring optical signal received in both directions of the optical ring network.

Specifically, the reflected wavelength and the transmitted wavelength may be included in a wavelength band different from the wavelength band used for the communication service.

According to a third aspect of the present invention, there is provided a network structure determination method performed in an intra-office apparatus according to the third aspect of the present invention, comprising the steps of: A remote node monitoring optical signal transmission step of generating and transmitting a remote node monitoring optical signal having a differently set reflection wavelength; A network monitoring optical signal transmission step of generating and transmitting a network monitoring optical signal having a pass wavelength passing through each of the plurality of remote nodes; A network transmission step of transmitting the remote node monitoring optical signal and the network monitoring optical signal in at least one direction of both directions of the optical ring network; And a network monitoring optical signal received through the plurality of remote nodes from an optical signal for remote node monitoring reflected from and received from a remote node from both directions of the optical ring network, And a structure grasping step of grasping the optical ring network installation structure.

In particular, the structure grasping step may include a step of determining whether the optical ring network is transmitted in both directions of the optical ring network, using the time at which the remote node monitoring optical signal is transmitted and the time at which the optical network signal for remote node monitoring reflected by each of the plurality of remote nodes is received. Calculating an overall distance of the optical ring network based on a time at which the network monitoring optical signal is transmitted and a time at which the network monitoring optical signal is transmitted, It is possible to grasp the remote node installation structure in both directions of the optical ring network based on the distance between the apparatus and the remote node and the calculated total distance.

Specifically, in the network transmission step, a remote node monitoring optical signal having a reflection wavelength set in some remote nodes among the plurality of remote nodes in both directions of the optical ring network is transmitted in a first direction, The remote node monitoring optical signal having a wavelength of the reflection wavelength set to the remote node other than the part of the nodes may be transmitted in the second direction and the network monitoring optical signal may be transmitted in the first direction or the second direction.

Specifically, the remote node may be a remote node whose distance from the apparatus within the state of the plurality of remote nodes is closer in the first direction to the second direction than the remote node, May be a remote node closer to the first direction than the first direction in the second direction.

Therefore, according to the system for grasping the network structure of the present invention, and the apparatus and method for grasping the structure of a network applied to the system, the apparatus in the optical network system of the optical network system can be installed in an optical ring Thereby obtaining an effect of accurately grasping the structure of the network.

FIG. 1 is an exemplary diagram illustrating a network structure identification system in an optical network system according to an exemplary embodiment of the present invention. Referring to FIG.
FIG. 2 is a diagram illustrating a configuration of an apparatus in an office and a remote node according to an exemplary embodiment of the present invention. Referring to FIG.
3 is a diagram illustrating a structure of a WDM filter used as a supervisory band filter and a service band filter in an embodiment of the present invention.
4 shows a monitoring frame according to an embodiment of the present invention.
FIG. 5 is a flowchart of a network structure determination method executed in an apparatus within the state of the art according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. Throughout the specification, when an element is referred to as being "comprising" or "comprising", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise . In addition, '... Quot ;, " module ", and " module " refer to a unit for processing at least one function or operation, and may be implemented by hardware, software, or a combination of hardware and software. A preferred embodiment of the present invention will be described.

FIG. 1 illustrates a network structure identification system in an optical network system according to an embodiment of the present invention.

The network structure identification system according to an embodiment of the present invention may include a plurality of remote nodes (RNs) 200 and a central office terminal (COT) 100.

In particular, FIG. 1 illustrates a mobile communication system using a Base Band Unit (BBU) and a Remote Radio Head (RRH) as an example of an optical communication network system to which the present invention is applied.

1, a mobile communication system using a Base Band Unit (BBU) and a Remote Radio Head (RRH) is shown. The BBU is connected to the mobile communication network through a backhaul, the BBU and the RRH are connected to each other through a front hole (Fronthaul), and the RRH is connected to the terminal through radio.

According to an embodiment of the present invention, the device 100 and a plurality of remote nodes 200 are connected to an optical ring network.

Thus, in the mobile communication system according to the embodiment of the present invention, signals transmitted between the BBU and the RRH are relayed through the optical ring network including the device 100 and the plurality of remote nodes 200.

The device 100 is connected to the BBU and transmits signals of the backhaul mobile communication network. The plurality of remote nodes 200 are directly connected to the RRH or connected to the RRH through a sub-RN (SRN) And transmits a signal of RRH.

In the embodiment of the present invention, the apparatus 100 and the plurality of remote nodes 200 are connected in a ring shape via one optical line, and the apparatus 100 is connected to a plurality of remote nodes 200 through bidirectional communication .

A plurality of remote nodes 200 is a passive node composed of passive elements and distributes signals transmitted from the apparatus 100 or RRH in the optical ring network.

That is, the intra-state apparatus 100 transmits a down-link signal to the remote nodes 210, 220, 230 and 240 in both directions, and the remote nodes 210, 220, 230 and 240 transmit the downlink signals up-link signal to the intra-state-space apparatus 100.

Accordingly, the intra-state apparatus 100 can receive the uplink signals from the remote nodes 210, 220, 230, 240 in both directions through the optical line, and can receive the bidirectional remote nodes 210, 220, 230, 240 to detect the distance to each of the remote nodes 210 220, 230, and 240, and the interval in which the failure occurs.

Specifically, in an embodiment of the present invention, the intra-state apparatus 100 may wavelength-division-multiplex signals to be transmitted to the respective remote nodes 210, 220, 230, and 240 and transmit the signals unidirectionally.

More specifically, the intra-state institutional apparatus 100 receives the reflected wave and the plurality of remote nodes 210, 220, 230, and 240, respectively, which are set at the plurality of remote nodes 210, 220, The monitoring optical signal having the passing wavelength can be wavelength division multiplexed and transmitted in at least one direction of both directions of the optical ring network.

Each of the remote nodes 210, 220, 230, and 240 branches the signal of the wavelength assigned to itself among the multiplexed signals and transmits it to the RRH directly connected to the sub remote node (e.g., SRN31, SRN32 in FIG. 1) Distribution.

More specifically, each of the remote nodes 210, 220, 230, and 240 includes a selective reflection unit that reflects only a monitoring optical signal of a predetermined reflection wavelength among the received optical signals, (The SRN 31 and the SRN 32 in FIG. 1) or the RRHs directly connected to the respective remote nodes by branching the signal of the wavelength assigned to them, can do.

The apparatus 100 for internal-office use is configured to transmit an optical signal reflected and received from a node remote from the transmission direction in both directions of the optical ring network and an optical signal received through a plurality of remote nodes 200 from one direction other than the transmission direction The remote node installation structure on the optical ring network is grasped.

On the other hand, in the optical ring network according to the embodiment of the present invention, since the transmission of the uplink or downlink signals is performed in both directions, even if a failure occurs in the optical line of any section of the optical line, The remote node 210, 220, 230, 240 may receive an uplink signal from a plurality of remote nodes 200, and each remote node 210, 220, 230, 240 may receive a downlink signal from the intra-

Although a front-hole network of a mobile communication system is described as an example in the present invention, the present invention can also be applied to an optical network system using a wavelength division multiplexing scheme.

Hereinafter, a method (method) of grasping a remote node installation structure on an optical ring network according to an embodiment of the present invention will be described with reference to FIG. 1, As shown in Fig.

FIG. 2 is a diagram illustrating a configuration of an apparatus in an office and a remote node according to an exemplary embodiment of the present invention. Referring to FIG.

The apparatus 100 for domestic office according to an embodiment of the present invention includes a plurality of remote nodes 210, 220, 230, and 230 for a plurality of remote nodes 200 connected to the apparatus 100, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240) for transmitting and receiving optical signals for remote node monitoring, the remote node monitoring optical signal processing unit A network monitoring unit 180 for generating and transmitting a network monitoring optical signal having a wavelength, and a control unit 180 for transmitting the remote node monitoring optical signal and the network monitoring optical signal in at least one direction of both directions of the optical ring network And a plurality of remote nodes 2 (1, 2, 3, 4) from one direction other than the direction of transmission, 00), and a control unit (not shown) for grasping the optical ring network installation structure based on the network monitoring optical signal received through the network.

Specifically, the control unit (not shown) uses the time at which the remote node monitoring optical signal is transmitted and the time at which the remote node monitoring optical signal reflected by each of the plurality of remote nodes 210, 220, 230, It is possible to calculate the distance between the apparatus in the indoor unit 100 and the remote node based on the transmission direction of both directions of the ring network.

Then, the control unit (not shown) can calculate the total distance of the optical ring network using the time at which the network monitoring optical signal is transmitted and the time at which it is received.

Accordingly, the control unit (not shown) can grasp the remote node installation structure in both directions of the optical ring network based on the previously calculated distance between the ID apparatus 100 and the remote node and the calculated total distance.

The control unit (not shown) may be implemented as a separate hardware module (functional unit) from the remote node monitoring optical signal processing unit 110, the network monitoring unit 180, and the transmitting units 160 and 170, And each software module distributed as a part of the function of the software module may be implemented in the form of a software module for realizing all or part of the functions of the remote node monitoring optical signal processing unit 110 and the network monitoring unit 180 Can be implemented.

According to the first embodiment of the present invention, the intra-territorial device 100 includes a remote node monitoring optical signal having a different reflected wavelength set for each of a plurality of remote nodes 210, 220, 230 and 240, Can be transmitted in the first direction (EAST direction or WEST direction) of both directions of the optical ring network.

In this case, the intra-state apparatus 100 is configured to transmit, from both sides of the optical ring network, the remote nodes 210, 220, 230, 240 reflected from the remote nodes 210, 220, 230, 240 from the transmission direction, And receives a network monitoring optical signal that has passed through a plurality of remote nodes 200 from one direction other than the transmission direction, that is, the second direction (the west direction or the EAST direction). Based on these, You can understand the network installation structure.

According to the second embodiment of the present invention, the intra-territorial device 100 transmits an optical signal for remote node monitoring having a reflection wavelength set differently for a plurality of remote nodes 210, 220, 230, In the first direction (e.g., the EAST direction) of both directions of the optical ring network, and transmits the network monitoring optical signal having the passing wavelength in the second direction (e.g., the WEST direction) of both directions of the optical ring network.

In this case, the intra-state apparatus 100 transmits the optical signal to the remote nodes 210, 220, 230, and 240 from the transmission direction of the remote node monitoring optical signal, that is, the first direction (e.g., EAST direction) (E.g., EAST direction) other than the transmission direction of the network monitoring optical signal, that is, the second direction (e.g., the west direction), and the plurality of It is possible to receive the optical network signal for network monitoring that has passed through the remote node 200 and grasp the optical ring network installation structure based on the optical network signal.

According to the third embodiment of the present invention, the intra-state office apparatus 100 is configured to transmit the optical signal of the reflection wavelength set to some remote nodes among the plurality of remote nodes 210, 220, 230, The remote node monitoring optical signal transmitted in the first direction (e.g., the EAST direction) is transmitted to the remote node monitoring optical signal having the wavelength of the reflected light set to the remaining remote nodes other than the part of the plurality of remote nodes 210, 220, 230, The signal may be transmitted in a second direction (e.g., the WEST direction).

At this time, the apparatus 100 for internal-office use transmits the network monitoring optical signal having the passage wavelength to either one of the two directions of the optical ring network, that is, the first direction (e.g., EAST direction) or the second direction As shown in FIG.

In this case, the intra-state apparatus 100 is configured to detect the remote node monitoring optical signal reflected from some remote nodes from the first direction (e.g., the EAST direction) in both directions of the optical ring network, (For example, the WEST direction) or the first direction (for example, the EAST direction) in the other direction than the transmission direction of the network monitoring optical signal, The network monitoring optical signal passing through the plurality of remote nodes 200 can be received from the remote node 200, and the optical ring network installation structure can be grasped based on these signals.

2, the control unit (not shown) is implemented in the form of a separate hardware module (functional unit), and the control unit (not shown) realizes the function of calculating the distance between the apparatus 100 and the remote node A software module of a control unit (not shown) implemented in the remote node monitoring optical signal processing unit 110 and realizing the function of calculating the total distance of the optical ring network is implemented in the network monitoring unit 180 Respectively.

2, a third embodiment of the first, second, and third embodiments will be described with reference to the drawings.

2 according to an embodiment of the present invention, an intra-state office device 100 is connected to a plurality of remote nodes 200 in a ring-shaped manner and transmits signals in both directions.

The apparatus for in-state service 100 includes a remote node monitoring optical signal processing unit 110, monitoring optical signal filter units 120 and 130, circulators 140 and 150, a wavelength multiplexer / demultiplexer Mux / Demux, 160, and 170, and a network monitoring unit 180.

The remote node monitoring optical signal filter units 120 and 130 include a first remote node monitoring optical signal filter unit 120 and a second remote node monitoring optical signal filtering unit 130 according to a wavelength band of a signal to be filtered, Respectively.

The wavelength multiplexing / demultiplexing apparatuses 160 and 170 include a first wavelength multiplexer / demultiplexer 160 and a second wavelength multiplexer / demultiplexer 160 that transmit signals in a first direction (hereinafter referred to as EAST direction) And a second wavelength multiplexer / demultiplexer 170 for transmitting a signal in a WEST direction).

The optical signal processing unit 110 for remote node monitoring generates an optical signal for remote node monitoring for monitoring the remote node 200 using an electrical signal having a predetermined monitoring frame. Here, the monitoring frame is a frame including signal data for monitoring the remote node 200, and includes a byte (hereinafter, referred to as a distance measurement byte) for indicating that the optical signal for remote node monitoring is a signal for distance measurement ). The optical signal processing unit 110 for remote node monitoring generates an optical signal for remote node monitoring by optically converting electrical signals constituted by such monitoring frames.

As described above, the remote-node monitoring optical-signal processing unit 110 generates a plurality of remote node monitoring optical signals by using an electrical signal having a predetermined monitoring frame. The plurality of remote node monitoring optical signals generated at this time are optical signals having different wavelengths (reflection wavelengths) and are used to calculate the distances to the remote nodes 200 corresponding to the plurality of remote nodes 200 do.

It is preferable that the reflected waves used for the plurality of remote node monitoring optical signals are included in a wavelength band different from the wavelength band used for the communication service.

Accordingly, the optical signal processing unit 110 for remote node monitoring can generate optical signals for remote node monitoring using a wavelength band of 1370 to 1390 nm.

In the WDM system, a wavelength band of 1270 to 1610 nm is used to provide a communication service. Here, in the case of the wavelength band of 1370 to 1390 nm, since water peaks occur, a lot of loss occurs in the signal transmission process and it is not suitable for transmission of the service band signal. Therefore, by transmitting the optical signal for remote node monitoring using the wavelength band of 1370 ~ 1390 nm in which the water peak occurs, the distance between the apparatus and the remote node can be calculated without affecting the service band of the existing WDM system .

In addition, it is preferable that the passing wavelength used for the network monitoring optical signal to be described later is also included in a wavelength band different from the wavelength band (1270 to 1610 nm) used for the communication service. For example, .

On the other hand, in the apparatus 100 for internal-office use, an optical module with high output and high sensitivity is used for transmitting / receiving an optical signal for remote node monitoring in consideration of such loss occurrence.

The optical signal processing unit 110 for remote node monitoring divides a wavelength band of 1370 to 1390 nm corresponding to the number of remote nodes 200 to generate a plurality of remote node monitoring optical signals. Accordingly, the plurality of remote node monitoring optical signals may be optical signals of different wavelengths (reflection wavelengths) generated using the same frame.

That is, since four remote node 200 are used in FIG. 2, the remote node monitoring optical signal processing unit 110 divides the wavelength band of 1370 to 1390 nm into four bands and outputs 1361.5 to 1368.5 nm ), A remote node monitoring optical signal corresponding to a wavelength (reflection wavelength) of 1372 to 1376.5 nm (1370 H band), 1381 to 1388.5 nm (1390 L band), and 1392 to 1396.5 nm have.

The remote node monitoring optical signal processing unit 110 transmits the generated plurality of remote node monitoring optical signals to the remote node monitoring optical signal filter units 110 and 120.

The optical signal processing unit 110 for remote node monitoring ultimately receives a reflected signal of a remote node monitoring optical signal reflected / received from a plurality of remote nodes 200.

The remote node monitoring optical signal processing unit 110 for realizing the function of calculating the distance between the apparatus 100 for the national office and the remote node can calculate the distance between the inside-house apparatus 100 and the plurality of remote nodes 200 ).

Since a plurality of remote node monitoring optical signals are simultaneously transmitted, since the plurality of remote node 200 are located at different distances, the reception time of the reflection signal reflected and received from each remote node 210, 220, 230, Are different.

The optical signal processing unit 110 for remote node monitoring uses the difference between the transmission time of the optical signal for remote node monitoring and the reception time of each reflection signal and the transmission speed (speed of light) of the signal in the optical path, It is possible to calculate the distance between the apparatus in internal office 100 and each remote node 210, 220, 230, 240 based on the transmission direction in both directions.

The reflected signal corresponds to an optical signal similar to an optical signal for remote node monitoring, and the optical signal processor 110 for remote node monitoring can calculate a distance by converting a reflected signal into an electrical signal.

The remote-node monitoring optical-signal processing unit 110 determines whether or not a distance measurement byte is included in the received signal, and judges whether or not the optical signal for monitoring the remote node is reflected from the remote node 200, can do.

When the received signal corresponds to the reflected signal, the remote-node monitoring optical-signal processing unit 110 calculates the distance to the apparatus 100 and the remote nodes 200.

Optical signals for remote node monitoring at different wavelengths (reflected wavelengths) are used to measure distances to different remote nodes 200.

2, the remote node 1 210 has a bandwidth of 1370 L, the remote node 2 220 has a bandwidth of 1370 H, the remote node 3 230 has a bandwidth of 1390 L, the remote node 4 240 has a bandwidth of 1390 H, Optical signals for remote node monitoring are each matched and used to calculate the distance between the device 100 and the plurality of remote nodes 200. The optical signal processing unit 110 for remote node monitoring can identify the remote node based on the wavelength (reflected wavelength) of the received reflected signal and calculate the distance to the corresponding remote node.

The remote node monitoring optical signal filter units 120 and 130 may be configured to control the wavelength band allocated to the remote node monitoring optical signal filter units 120 and 130 in the process of transmitting the remote node monitoring optical signal and receiving the reflected signal, Lt; / RTI >

Specifically, in the first remote node monitoring optical signal filter unit 120, optical signals for remote node monitoring in the 1370 L and 1370 H bands are filtered out from a plurality of remote node monitoring optical signals and sent to the circulator 140 , Filters the 1370 L and 1370 H signals in the reflected signal, and sends the filtered signals to the remote node monitoring optical signal processing unit 110.

Likewise, the second remote node monitoring optical signal filter unit 130 filters the remote node monitoring optical signals of 1390 L and 1390 H bands out of the plurality of remote node monitoring optical signals and sends them to the circulator 150, And filters the 1390 L and 1390 H signals in the reflected signal and sends the filtered signals to the remote node monitoring optical signal processing unit 110.

The circulators 140 and 150 are connected to the remote node monitoring optical signal filter units 120 and 130 to detect the remote node monitoring optical signal processed by the remote node monitoring optical signal filter units 120 and 130, Branch or combine the signal.

That is, the circulator 140 combines the optical signals for remote node monitoring in the 1370 L and 1370 H bands generated by the first remote node monitoring optical signal filter unit 120 and outputs the combined optical signals to the first wavelength multiplexer / demultiplexer 160 1370 L and 1370 H bands, respectively, and sends the split signals to the first remote node monitoring optical signal filter unit 120.

Likewise, the circulator 150 combines the optical signals for remote node monitoring in the 1390 L and 1390 H bands and branches the reflected signals in the 1390 L and 1390 H bands, respectively.

The network monitoring unit 180 generates and transmits a network monitoring optical signal of a pass wavelength in one direction of the optical ring network and receives a network monitoring optical signal in the other direction of the optical ring network, Calculate the total distance of the network.

As described above, the network monitoring optical signal is transmitted by using a wavelength (pass wavelength), for example, 1625 nm band, which is different from the wavelength band (1270 to 1610 nm) used for the communication service so as to pass through the entire optical ring network Lt; / RTI >

The network monitoring optical signal starts from the intra-state apparatus 100, passes through the entire optical ring network, and arrives at the intra-facility apparatus 100 again. That is, the network monitoring optical signal is multiplexed at a frequency of 1625 nm band through the wavelength multiplexers / demultiplexers 160 and 170, and is transmitted in the EAST or WEST direction and is received in the WEST or EAST direction.

The network monitoring unit 180 that realizes the function of calculating the total distance of the optical ring network calculates (calculates) the total (total) distance of the entire optical ring network by using the difference between the transmission time and the reception time of the network monitoring optical signal Calculation). The total distance of the entire optical ring network can be calculated by using the difference between the transmission time and the reception time of the optical flux of the glass medium constituting the optical line and the network monitoring optical signal.

The wavelength multiplexers / demultiplexers 160 and 170 wavelength-division multiplex the downlink signal, the plurality of remote node monitoring optical signals, and the network monitoring optical signal, and transmits the multiplexed signal to a plurality of remote nodes 200 . In addition, a signal received from a plurality of remote nodes 200 is demultiplexed by wavelength band.

That is, the embodiment of the present invention identifies each remote node without affecting the existing service channel by additionally using the wavelength band in which the water peak occurs, while maintaining the wavelength band of the WDM system as it is, The structure of the optical ring network constituted by the device 100 and each remote node can be confirmed.

The network monitoring optical signal generated by the network monitoring unit 180 is transmitted only in one direction of the optical ring network to which the apparatus 100 is connected and in the other direction, The call is received.

The first wavelength multiplexer / demultiplexer 160 multiplexes signals to be transmitted in the EAST direction to a plurality of remote nodes 200 connected in a circular manner. At this time, when the network optical signal is transmitted in the EAST direction, the downlink signal, the optical signal for remote node monitoring in the 1370 nm band, and the optical network signal for network monitoring are multiplexed.

As shown in FIG. 2, the first wavelength multiplexer / demultiplexer 160 multiplexes an optical signal for remote node monitoring in the 1370 nm band and an optical signal for network monitoring with a downlink signal and transmits the optical signal in the EAST direction. The optical signal for remote node monitoring in the 1370 nm band is used to identify the remote node 1 210 and the remote node 2 220 in close proximity in order to reduce line loss.

That is, the optical signal for remote node monitoring in the 1370 nm band transmitted in the first direction, that is, the EAST direction, of both directions of the optical ring network, (210, 220) closer to the WEST direction than the EAST direction.

The second wavelength multiplexer / demultiplexer 170 multiplexes / demultiplexes a signal to be transmitted in a WEST direction to a plurality of remote nodes 200 connected in a circular manner. At this time, when the network monitoring optical signal is transmitted in the WEST direction, the downlink signal, the optical signal for remote node monitoring in the 1390 nm band, and the optical network signal for network monitoring are multiplexed.

Likewise, the second wavelength multiplexer / demultiplexer 170 multiplexes the remote node monitoring optical signal and the network monitoring optical signal in the 1390 nm band with the downlink signal and transmits it in the WEST direction. The optical signal for remote node monitoring in the 1390 nm band is used for identification of the remote node 3 230 and the remote node 4 240 at a close distance.

That is, the remote node monitoring optical signal in the 1390 nm band transmitted in the second direction of the optical ring network in the second direction, that is, the WEST direction, is a distance between the remote node 200 and the apparatus 100 in the EAST direction (230, 240) that are closer to the WEST direction.

The plurality of remote nodes 200 include a plurality of remote nodes installed at a remote location.

The remote node 1 210, the remote node 2 220, the remote node 3 230, and the remote node 4 240, respectively, in the case of relaying signals using four remote nodes .

The remote node 1 210 includes a supervisory band filter 211, a reflector 212, service band filters 213 and 214, and an optical distributor 215. The monitoring band-pass filter 211 and the reflector 212 are separated from the constituent elements of the selective reflection portion that reflects only the optical signal for monitoring at the reflection wavelength set at the corresponding remote node.

Each of the remote nodes 210, 220, 230 and 240 has the same structure only in the wavelength band of the monitoring band-pass filter 211 and the wavelength band of the service band filters 213 and 214 . Also, the monitoring band-pass filter 211 and the service band-pass filters 213 and 214 have a WDM filter structure as shown in Fig. 3 only in a wavelength band to be passed therethrough.

3 is a diagram illustrating a structure of a WDM filter used as a supervisory band filter and a service band filter in an embodiment of the present invention.

As shown in FIG. 3, the WDM filter used in the embodiment of the present invention has a common port, a reflection port, and a pass band port. In FIG. 3, signals are inputted from the passband port and the reflection port. However, each port can pass signals in both directions, and signals can be input from the common port.

The common port passes all wavelength bands used in WDM. The passband port passes only a specific wavelength band designed to pass through the WDM filter. The reflection port passes only the wavelength band not the pass wavelength band.

For example, when a WDM filter is a wavelength bandpass filter of 1470 nm, if a signal of a plurality of wavelength bands is input as a common port, a signal of a wavelength band of 1470 nm passes through a passband port and signals of the remaining wavelength bands are reflected And passes through the reflection port.

Conversely, when a signal is input to the reflection port and the passband port, the signal input to the reflection port is reflected inside the filter, passes through the common port, and the signal input to the passband port does not pass through the reflection port It passes through only the common port.

Hereinafter, a connection relationship and a signal transmission process between the apparatus 100 and the plurality of remote nodes 200 will be described using a WDM filter structure.

The common port of the monitoring band filter 211 of the remote node 1 210 is connected to the apparatus 100 in the indoor unit, the reflection port is connected to the first service band filter 213, The reflective portion 212 is located.

The common port of the first service band filter 213 is connected to the monitoring band filter 211 and the reflection port is connected to the second service band filter 214.

The common filter of the second service band filter 214 is connected to the remote node 2 220, and the reflection port is connected to the first service band filter 213. An optical splitter 215 is connected to the lower end of the first service band filter 213 and the second service band filter 214.

The signal in the EAST direction transmitted from the device 100 in the national office is first received in the monitoring band filter 211 of the remote node 1 210 and the signal in the WEST direction is received at the remote node 4 240, Is received at the second service band filter 214 of the remote node 1 210 via the remote node 2 230 and remote node 2 220.

The port of the internal filter of the remote node 2 (220) has the same connection relationship as the remote node 210 (210). The remote node 3 230 and the remote node 4 240 differ only in that they are connected to receive signals in the WEST direction in the supervisory band filter and have the same connection relationship as the remote node 1 210.

That is, a common port of the monitoring band-pass filter of the remote node 4 240 is connected to the apparatus 100 in the indoor unit, the reflection port is connected to the first service band filter, The common port of the band-pass filter is connected to the remote node 3 230.

The monitoring band filter 211 allows only the remote node monitoring optical signal to pass through among the multiplexed signals received from the apparatus 100 in the indoor unit. Specifically, the monitoring band-pass filter 211 of the remote node 1 210 is designed (set) to filter a signal of a wavelength (reflection wavelength) for measuring the distance of the remote node 1 210, that is, a signal of 1370 L band, It is possible to pass only the optical signal for remote node monitoring in the 1370 L band among the multiplexed signals.

And the signal of the remaining wavelength band is sent to the first service band filter 213 through the reflection port of the monitoring band filter 211.

The reflector 212 reflects the remote node monitoring optical signal that has passed through the monitoring band filter 211. The reflector 212 is composed of a mirror whose optical signal can be reflected. That is, the 1370 L-band remote node monitoring optical signal passed through the monitoring band filter 211 of the remote node 1 210 is reflected by the reflecting portion 212, and the reflected signal is reflected by the common And is transmitted to the intra-state apparatus 100 connected to the port. Since the reflected signal can not pass through the reflection port, it is not transmitted to the service band filter 213, 214 or the remote node 2 220 located in the traveling direction EAST of the signal.

The service band-pass filters 213 and 214 pass a signal of a service wavelength band corresponding to an RRH (not shown) connected to the remote node 1 (210). The remote node 1 210 has two service band filters 213 and 214 corresponding to the signals transmitted and received in both directions. Specifically, the service band filters 213 and 214 pass a signal of a service wavelength band corresponding to the RRH connected to the remote node 1 (210). The remote node 1 210 filters the signal in the 1550 to 1610 nm wavelength band from the multiplexed signal and transmits the filtered signal to the RRH connected to the lower layer.

The optical splitter 215 distributes the signal of the service band. The optical splitter 215 separates the signals according to the wavelengths by the optical filter and operates either one selected from the network monitoring unit 180 among the signals received in the EAST and WEST directions. In FIG. 2, the four wavelength bands are divided into two sub-remote nodes (not shown). The distributed signals are transmitted to a connected passive node (not shown), and are provided as RRHs for service provision in each passive node.

Hereinafter, a process (method) for identifying each remote node and grasping a remote node installation structure on the optical ring network will be described according to an embodiment of the present invention.

The apparatus 100 for internal-office use can receive a plurality of remote node monitoring optical signals reflected from each remote node, identify the wavelength of the signals, and identify which remote node is the reflected signal.

For example, when the reflection signal of 1370 L band is received, the device 100 in the national office can identify that the reflection signal is a signal reflected from the remote node 1 (210).

That is, when receiving the reflection signal of the specific reflection wavelength, the optical signal processing unit 110 for remote monitoring of the apparatus 100 for the national office identifies a certain remote node, and uses the reception time of the reflection signal The distance to the remote node can be calculated.

Specifically, referring to FIG. 2, a plurality of remote node monitoring optical signals and network monitoring optical signals transmitted to the optical ring network are transmitted to the intra-state apparatus 100, A difference occurs in the time of returning to the internal device 100. [ Since each of the signals uses different wavelength bands (reflected wavelengths), it is possible to identify the type of the remote node by using the wavelength band of the reflected / received signal, The distance to the node can be calculated.

In addition, a remote node monitoring optical signal processing unit (not shown) implemented with a control unit (not shown), for example, a software module of a control unit (not shown) for realizing a function of calculating the distance between the apparatus 100 in- When a remote node monitoring optical signal received from one direction other than the transmission direction in both directions of the optical ring network is identified, the controller 110 connects the remote node having the reflected wavelength of the optical signal for monitoring the remote node, It can be detected as an error.

For example, if a remote node monitoring optical signal transmitted in the EAST direction of the optical ring network in the state-of-the-art apparatus 100 is reflected and received in the EAST direction but not in the transmission direction, The remote node having the wavelength of the optical signal for monitoring the remote node is not normally connected to the optical ring network.

In order to detect this, the optical signal processing unit 110 for monitoring the remote node monitors the remote node monitoring optical signals generated and transmitted for each remote node, When an optical signal for node monitoring is identified, a remote node having a reflected wavelength of the optical signal for monitoring the remote node can be detected as a connection error.

That is, the intra-state apparatus 100 of the present invention detects a connection error of a remote node, which may occur in an optical ring network operation process such as an optical ring network establishment process or a light beam change.

The network monitoring unit 180 of the apparatus 100 for the national office can calculate the total distance of the entire optical ring network by using the transmission time and the reception time of the network monitoring optical signal.

2, a network monitoring unit 180 implemented with a software module of a control unit (not shown) for realizing a function of calculating the total distance of the optical ring network, It is possible to detect whether or not a connection error related to another optical ring network has occurred in the optical ring network, based on the network monitoring optical signal received in both directions.

For example, an error that the optical ring is twisted (hereinafter referred to as a network connection error) may occur between the optical ring network composed of the intra-state apparatus 100 and remote nodes and another optical ring network.

In order to detect this, the network monitoring unit 180 detects a connection error related to another optical ring network in the optical ring network in which the apparatus 100 is configured based on the network monitoring optical signal received in both directions of the optical ring network It is possible to detect whether or not a network connection error has occurred.

Specifically, after the network monitoring unit 180 transmits (transmits) the network monitoring optical signal in the transmission direction in both directions of the optical ring network, the network monitoring unit 180 transmits the network monitoring optical signal in both directions of the optical ring network If a network monitoring signal is not received from one direction other than the direction, it can be detected that a network connection error has occurred.

Alternatively, the network monitoring unit 180 can detect that a network connection error has occurred when an optical signal for network monitoring is received from one of the two directions of the optical ring network without transmitting (transmitting) the network monitoring optical signal have.

On the other hand, although not shown in FIG. 4, based on the identifier in the monitoring frame which can be confirmed in the received optical network monitoring signal by adding information (for example, an identifier) about the apparatus in the office to the overhead area of the monitoring frame, It is also possible to detect a network connection error more quickly.

Specifically, after transmitting (transmitting) the network monitoring optical signal in the transmission direction in both directions of the optical ring network, the network monitoring unit 180 transmits the network monitoring optical signal from one direction When the supervisory optical signal is received, the supervisory frame identifier is checked in the received network monitoring optical signal, and if the identified identifier is inconsistent with the identifier of the device in the home office 100, it can be detected that a network connection error has occurred .

That is, the intra-state apparatus 100 of the present invention detects a network connection error, which may occur in the process of establishing an optical ring network or changing an optical ring network, It is.

Therefore, according to the present invention, the distance between the remote nodes can be calculated by using the total (total) distance of the entire optical ring network and the distance between the apparatus in the office and each remote node in the ID apparatus 100, The structure of the remote node installation structure in both directions of the optical ring network, that is, the structure of the entire optical ring network, can be grasped.

For example, when the distance of the entire ring network calculated through the transmission / reception time of the network monitoring optical signal is 15 km, and the distance between the indoor station 100 and the remote node 210 is 3 km, the distance between the remote nodes 2 and 220 is 7 km, the distance between the remote nodes 3 and 230 is 5 km, and the distance between the remote nodes 4 and 240 is 1 km.

Referring to FIG. 2, the distance between the apparatus 100 for domestic office and each remote node is a result calculated according to a direction in which a plurality of remote node monitoring optical signals having different wavelengths are transmitted. Accordingly, , The remote node 1 210 is 3 km in the EAST direction, the remote node 2 220 is 7 km in the EAST direction, the remote node 3 230 is 5 km in the WEST direction, and the remote node 4 240 is 1 km in the WEST direction It can be seen that it is apart. To compute this in one direction, using the total distance of the entire optical ring network (15 km), the remote node 3 230 is 10 km away in the EAST direction and the remote node 4 240 is 14 km away in the EAST direction Can be calculated.

The remote node 1 210 is 3 km long, the remote node 2 220 is 7 km long, the remote node 3 230 is 10 km long, and the remote node 4 240 is 14 km long in the EAST direction from the national office apparatus 100 . The ring network consisting of the apparatus 100 for the national office, the remote node 1 210, the remote node 2 220, the remote node 3 230, the remote node 4 240, and the intra- 3 km, 4 km, 3 km, 4 km, and 1 km, respectively.

In addition, the control unit (not shown) in the apparatus 100 for local office according to an embodiment of the present invention may store the previously stored remote node connection order information It is possible to detect whether or not the remote node connection order is changed in both directions of the optical ring network.

Specifically, the intra-state apparatus 100 calculates the distance between the internal office apparatus 100 and each remote node calculated by the remote node monitoring optical signal processing unit 110 and the distance between each remote node calculated by the network monitoring unit 180 And the remote node installation structure in both directions of the optical ring network is grasped by using the total distance of the optical ring network as shown in the above example, it is possible to know the remote node connection order in the EAST direction and the WEST direction.

2, in the case of the EAST direction, the apparatus 100 in the internal office, the remote node 1 210, the remote node 2 220, the remote node 3 230, the remote node 4 240, The remote node 2 220 and the remote node 1 210 can know the connection order of the internal device 100 in the case of the WEST direction and the internal apparatus 100, the remote node 4 240, the remote node 3 230, the remote node 2 220, ) - It is possible to know the connection order of the apparatus 100 within the national office.

Accordingly, the intra-state apparatus (100, control unit (not shown)) determines whether the remote node connection sequence that can be known based on the remote node installation structure in both directions of the optical ring network If the connection order is not matched, it can be detected that the connection order of the remote node is changed.

That is, the intra-state apparatus 100 of the present invention detects an error (change) in the remote node connection sequence that may occur in the optical ring network operation process such as the construction process of the optical ring network or the change to the optical line.

Here, the pre-stored remote node connection order information can be understood as reference information that is designed / stored for normal remote node connection in the construction process of the optical ring network.

4 shows a monitoring frame according to an embodiment of the present invention.

The monitoring frame according to an embodiment of the present invention includes an overhead area and a payload area as shown in the figure. The overhead area is an area including signal data for monitoring a remote node, and may include a Frame Alignment Signal (FAS), IDLE, BIP-8, LB, and Distance areas. The payload area is originally an area containing actual data. In one embodiment of the present invention, the payload area is filled with arbitrary bits because the monitoring frame does not contain any data.

The FAS field is inserted at the beginning of the frame as a signal frame byte used for segmenting the signal. IDLE is an empty region filled with zeros.

The BIP-8 area is used for performance monitoring of the line with performance monitoring byte. The performance monitoring byte is generated by performing a parity check on the overhead area of the monitoring frame. The optical signal processing unit 110 for remote node monitoring of the apparatus 100 for the national office monitors the performance monitoring bytes included in the remote node monitoring optical signal and the performance monitoring bytes included in the reflected signal to monitor performance. If the line is faulty, there is a mismatch between the transmitted performance monitoring byte and the received performance monitoring byte. The optical signal processing unit 110 for monitoring the remote node can count as many errors as the number of bits in which such inconsistency has occurred and monitor whether or not the transmission performance of the line is abnormal.

The LB field is a byte used to indicate that the remote node can read the monitoring signal when the remote node is an active device rather than a passive device. In the case of monitoring the passive remote node as in the embodiment of the present invention, the LB region may be filled with 0 as in the IDLE region.

The Distance field indicates that the frame is for measuring the distance with a distance measurement byte. It is confirmed that the distance measurement byte is included in the reflection signal received by the optical signal processing unit 110 for remote node monitoring of the apparatus 100 for the national office and the transmission time of the remote node monitoring optical signal and the reception time The distance to the remote node can be calculated.

As described above, according to the present embodiment, in an optical network system of a WDM (Wavelength Division Multiplexing) scheme, without the operator being manually involved, the apparatus in the home office dominates each remote node identification and the distance to each remote node And the distance between the remote nodes, it is possible to accurately grasp the structure of the optical ring network such as the installation position of the remote node.

In addition, by using a wavelength band in which a water peak is generated, which is not suitable for data transmission in the WDM system, a signal for grasping the network structure can be transmitted without affecting channels required for communication service.

Hereinafter, with reference to FIG. 5, a method of grasping a network structure executed in an apparatus within the state of the art according to an embodiment of the present invention will be described in detail.

In the method for grasping a network structure according to an embodiment of the present invention, the apparatus 100 for internal office divides a wavelength band (reflection wavelength) usable for optical signals for remote node monitoring according to the number of remote nodes (S100).

For example, in the case of the embodiment of FIG. 2, since four remote node 200 are used, the apparatus 100 for internal-office use can control the wavelength band (band of reflected wave) (1390 H band), 1381-1388.5 nm (1390 L band), 1392-1396.5 nm (1390 H band), and 1392-1396.5 nm (1390 H band) .

In the method for grasping the network structure according to an embodiment of the present invention, the intra-state apparatus 100 generates an optical signal for remote node monitoring with different reflection wavelengths for each remote node using an electrical signal having a monitoring frame (S110).

For example, the apparatus 100 for internal-office use may be configured such that each of 1361.5 to 1368.5 nm (1370 L band), 1372 to 1376.5 nm (1370 H band), 1381 to 1388.5 nm (1390 L band), 1392 to 1396.5 nm It is possible to generate and transmit a remote node monitoring optical signal corresponding to a wavelength (reflection wavelength) of each remote node 210, 220, 230,

Meanwhile, in the network structure determination method according to an embodiment of the present invention, the intra-state apparatus 100 generates a network monitoring optical signal of a wavelength band (pass wavelength) usable for a network monitoring optical signal (S120) .

For example, the internal-office apparatus 100 can generate an optical signal for network monitoring in the 1625 nm band.

In the method for grasping the network structure according to an embodiment of the present invention, the intra-territorial device 100 includes a remote node monitoring optical signal having a reflection wavelength set differently for each of the plurality of remote nodes 210, 220, 230, The monitoring optical signal is transmitted to the optical ring network (S130).

According to the first embodiment of the present invention, the intra-territorial device 100 includes a remote node monitoring optical signal having a wavelength different from that of the plurality of remote nodes 210, 220, 230, All of the monitoring optical signals can be transmitted in the first direction (EAST direction or WEST direction) of both directions of the optical ring network.

In this case, the intra-state apparatus 100 is configured to transmit, from both sides of the optical ring network, the remote nodes 210, 220, 230, 240 reflected from the remote nodes 210, 220, 230, 240 from the transmission direction, (S140). The network monitoring optical signals are received from a plurality of remote nodes 200 from one direction other than the transmission direction, i.e., the second direction (WEST direction or EAST direction) The structure of the optical ring network, such as the installation position of the remote node, can be grasped (S150) by identifying each remote node, the distance to each remote node, and the distance between the remote nodes.

In addition, in the method for grasping a network structure according to an embodiment of the present invention, the apparatus 100 for internal office monitors, based on the remote node monitoring optical signal received in step S140, It is possible to detect a remote node having a reflected wavelength of an optical signal for monitoring the remote node, which has been confirmed, as a connection error.

In addition, in the method for grasping the network structure according to an embodiment of the present invention, the intra-state office device 100 determines whether the remote node connection sequence that can be known based on the remote node installation structure in both directions of the optical ring network, If the connection order according to the previously stored remote node connection order information is not matched, it can be detected that the remote node connection order has been changed.

According to the second embodiment of the present invention, the intra-territorial device 100 transmits an optical signal for remote node monitoring having a reflection wavelength set differently for a plurality of remote nodes 210, 220, 230, In the first direction (e.g., the EAST direction) of both directions of the optical ring network, and transmits the network monitoring optical signal having the passing wavelength in the second direction (e.g., the WEST direction) of both directions of the optical ring network.

In this case, the intra-state apparatus 100 transmits the optical signal to the remote nodes 210, 220, 230, and 240 from the transmission direction of the remote node monitoring optical signal, that is, the first direction (e.g., EAST direction) (E.g., EAST direction) other than the transmission direction of the network monitoring optical signal, that is, the second direction (e.g., the west direction), and the plurality of (S140). Then, based on the received optical network signal, it is possible to identify each remote node and determine the distance between the remote nodes and the distance between the remote nodes, (S150).

In addition, in the method for grasping a network structure according to an embodiment of the present invention, the apparatus 100 for internal office monitors, based on the remote node monitoring optical signal received in step S140, It is possible to detect a remote node having a reflected wavelength of an optical signal for monitoring the remote node, which has been confirmed, as a connection error.

In addition, in the method for grasping the network structure according to an embodiment of the present invention, the intra-state office device 100 determines whether the remote node connection sequence that can be known based on the remote node installation structure in both directions of the optical ring network, If the connection order according to the previously stored remote node connection order information is not matched, it can be detected that the remote node connection order has been changed.

According to the third embodiment of the present invention, the intra-state office apparatus 100 is configured to transmit the optical signal of the reflection wavelength set to some remote nodes among the plurality of remote nodes 210, 220, 230, The remote node monitoring optical signal transmitted in the first direction (e.g., the EAST direction) is transmitted to the remote node monitoring optical signal having the wavelength of the reflected light set to the remaining remote nodes other than the part of the plurality of remote nodes 210, 220, 230, The signal may be transmitted in a second direction (e.g., the WEST direction).

At this time, the apparatus 100 for internal-office use transmits the network monitoring optical signal having the passage wavelength to either one of the two directions of the optical ring network, that is, the first direction (e.g., EAST direction) or the second direction As shown in FIG.

In this case, the intra-state apparatus 100 is configured to detect the remote node monitoring optical signal reflected from some remote nodes from the first direction (e.g., the EAST direction) in both directions of the optical ring network, (For example, the WEST direction) or the first direction (for example, the EAST direction) in the other direction than the transmission direction of the network monitoring optical signal, (S140). Then, based on the received optical network signal, the distances to the remote nodes and the distances between the remote nodes are determined based on the received optical network signals, The structure of the optical ring network can be grasped (S150).

In addition, in the method for grasping a network structure according to an embodiment of the present invention, the apparatus 100 for internal office monitors, based on the remote node monitoring optical signal received in step S140, It is possible to detect a remote node having a reflected wavelength of an optical signal for monitoring the remote node, which has been confirmed, as a connection error.

In addition, in the method for grasping the network structure according to an embodiment of the present invention, the intra-state office device 100 determines whether the remote node connection sequence that can be known based on the remote node installation structure in both directions of the optical ring network, If the connection order according to the previously stored remote node connection order information is not matched, it can be detected that the remote node connection order has been changed.

The data network structure determination method according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

According to the system for grasping network structure according to the present invention, and the method for grasping the network structure performed in the apparatus and apparatus of the present invention applied thereto, the apparatus in the optical network system in the optical network system can be directly connected to the optical ring network In order to grasp the structure, it is possible to carry out not only the use of the related technology but also the possibility of marketing or operating the device to be applied, as it exceeds the limit of the existing technology, .

100: Local device 200: Multiple remote nodes
110: Optical signal processor for remote node monitoring
120, and 130: an optical signal filter unit for monitoring a remote node
180:
211: Supervisory band filter 212: Reflective portion
213, 214: a service band filter 215: an optical splitter

Claims (13)

A plurality of remote nodes each having a selective reflection part for reflecting only a monitoring optical signal of a predetermined reflection wavelength among the optical signals to be received;
A monitoring optical signal connected to the plurality of remote nodes through an optical ring network and having a reflection wavelength set in each of the plurality of remote nodes and a passing wavelength passing through each of the plurality of remote nodes, A central office terminal for transmitting in at least one of two directions of the optical ring network;
The above-mentioned internal-
A remote node on the optical ring network, based on an optical signal reflected and received by a node remote from the transmission direction in both directions of the optical ring network and an optical signal received through the plurality of remote nodes from one direction other than the transmission direction, And identifying the node installation structure. In the case of an apparatus installed in a national office,
An optical signal processing unit for remote node monitoring for generating and transmitting a remote node monitoring optical signal having a different wavelength set for each of the plurality of remote nodes to a plurality of remote nodes connected to the apparatus within the national office and an optical ring network;
A network monitoring unit for generating and transmitting a network monitoring optical signal having a pass wavelength passing through each of the plurality of remote nodes;
A transmitting unit for transmitting the remote node monitoring optical signal and the network monitoring optical signal in at least one direction of both directions of the optical ring network; And
And an optical signal for network monitoring, which is received through the plurality of remote nodes from one direction other than the optical direction of the remote node and reflected by the remote node from the transmission direction in both directions of the optical ring network And a control unit for recognizing the optical ring network installation structure. 3. The method of claim 2,
Wherein,
Wherein the optical line terminal is connected to the optical line terminal of the optical line terminal by using the transmission direction of the both directions of the optical ring network as a reference based on the time at which the remote node monitoring optical signal is transmitted and the time at which the remote node monitoring reflected by each of the plurality of remote nodes is received. The distance between the remote nodes is calculated,
The total distance of the optical ring network is calculated using the time at which the network monitoring optical signal is transmitted and the time at which the optical network signal is received,
And the remote node installation structure in both directions of the optical ring network is grasped based on the calculated distance between the apparatus and the remote node and the calculated total distance. 3. The method of claim 2,
Wherein the transmission unit comprises:
Wherein a remote node monitoring optical signal having a reflection wavelength set in some remote nodes among the plurality of remote nodes in both directions of the optical ring network is transmitted in a first direction and the rest of the plurality of remote nodes, The remote node monitoring optical signal having the wavelength of the reflected light is transmitted in the second direction,
Wherein the network monitoring optical signal is transmitted in the first direction or the second direction. 5. The method of claim 4,
The remote node,
And a remote node among the plurality of remote nodes is closer to the second direction than the second direction in the first direction,
The remaining remote nodes,
Wherein a distance between the plurality of remote nodes and the apparatus in the indoor unit is a remote node closer to the first direction in the second direction. The method of claim 3,
Wherein,
And detects whether the remote node connection order is changed in both directions of the optical ring network based on the stored remote node connection order information based on a result of understanding the remote node installation structure in both directions of the optical ring network National device. 3. The method of claim 2,
Wherein,
When a remote node monitoring optical signal received from one direction other than the transmission direction in both directions of the optical ring network is identified, a remote node having the reflected wavelength of the optical signal for monitoring the remote node is detected as a connection error (1). 3. The method of claim 2,
Wherein,
And detects whether or not a connection error related to another optical ring network has occurred in the optical ring network, based on a network monitoring optical signal received in both directions of the optical ring network. 3. The method of claim 2,
The reflected wavelength and the transmitted wavelength are,
Is included in a wavelength band different from a wavelength band used for communication service. A method for network structure identification performed in an apparatus within a national office,
A remote node monitoring optical signal transmission step of generating and transmitting a remote node monitoring optical signal having a different reflection wavelength set for each of the plurality of remote nodes to a plurality of remote nodes connected to the apparatus in the office of the state and an optical ring network;
A network monitoring optical signal transmission step of generating and transmitting a network monitoring optical signal having a pass wavelength passing through each of the plurality of remote nodes;
A network transmission step of transmitting the remote node monitoring optical signal and the network monitoring optical signal in at least one direction of both directions of the optical ring network; And
And an optical signal for network monitoring, which is received through the plurality of remote nodes from one direction other than the optical direction of the remote node and reflected by the remote node from the transmission direction in both directions of the optical ring network And a structure grasping step of grasping the optical ring network installation structure. 11. The method of claim 10,
The structure grasping step includes:
Wherein the optical line terminal is connected to the optical line terminal of the optical line terminal by using the transmission direction of the both directions of the optical ring network as a reference based on the time at which the remote node monitoring optical signal is transmitted and the time at which the remote node monitoring reflected by each of the plurality of remote nodes is received. The distance between the remote nodes is calculated,
The total distance of the optical ring network is calculated using the time at which the network monitoring optical signal is transmitted and the time at which the optical network signal is received,
And the remote node installation structure in both directions of the optical ring network is grasped based on the calculated distance between the apparatus and the remote node and the calculated total distance. 11. The method of claim 10,
Wherein the network transmission step comprises:
Wherein a remote node monitoring optical signal having a reflection wavelength set in some remote nodes among the plurality of remote nodes in both directions of the optical ring network is transmitted in a first direction and the rest of the plurality of remote nodes, The remote node monitoring optical signal having the wavelength of the reflected light is transmitted in the second direction,
Wherein the network monitoring optical signal is transmitted in the first direction or the second direction. 13. The method of claim 12,
The remote node,
And a remote node among the plurality of remote nodes is closer to the second direction than the second direction in the first direction,
The remaining remote nodes,
Wherein the remote node is a remote node among the plurality of remote nodes that is closer to the first node in the second direction than the first direction.

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