KR20140068779A - Time and wavelength division multiplexing - passive optical network (TWDN-PON) system and communication connection method in the TWDM-PON system - Google Patents

Abstract

Disclosed is a time and wavelength division multiplexed passive optical network (TWDM-PON) system and a communication connection method thereof. According to an embodiment of the present invention, the communication connection method is a method of communicating with other optical line devices and an optical network unit which is communicatively connected to any one of the optical line devices. The optical network unit receives a wavelength change command on the operating wavelengths which are assigned to an optical line device to be connected and synchronizes to a downlink signal on the operating wavelengths by changing the wavelength in response to a wavelength change order. Furthermore, the optical network unit communicates with the optical line device by receiving an upstream discovery grant signal transmitted from the optical line device to be connected and by transmitting a reception confirmation signal therefor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Time Division Multiplexing (WDM) system and a passive optical network (TWDN)

The present invention relates to a Time and Wavelength Division Multiplexing Passive Optical Network (TWDM-PON) system and a communication connection procedure in the system.

A time division multiplexing (TDM-PON) type optical network (TDM-PON) such as EPON (Ethernet Passive Optical Network) or GPON (Gigabit capable PON) uses optical signals of wavelengths of up and down, And uses an optical splitter that does not require power to connect domestic users with subscribers. Because of this feature, TDM-PON has been widely deployed and successfully deployed around the world. Among them, GPON was distributed in North America and Europe. In 2010, ITU-T issued the G.987 XG-PON standard recommendation, which is 10G-GPON. FSAN (Full Service Access Network), a group consisting of major telecommunication carriers and equipment manufacturers related to optical network technologies, is a standardization group of ITU-T SG15 Q2 group and recently developed a next generation passive optical network (NG- (Time and Wavelength Division Multiplexing (TWDM) passive optical network (TWDM-PON)) is adopted as the main technology of PON2. TWDM-PON is discussed in ITU-T as a G.989.x standard recommendation.

1 shows a configuration of an optical subscriber line system capable of accommodating a plurality of heterogeneous services, such as TDM-PON, P-to-P, and RF video overlay, by applying a wavelength division method to a conventional passive optical network It is a block diagram. In the system configuration of FIG. 1, the NG-PON2 system may have a hybrid mode combining the TDM scheme and the WDM scheme. The NG-PON2 system is a structure that can accommodate a plurality of same service and / or heterogeneous service links by using optical signals of various wavelengths. It can transmit the transmission capacity to the optical wavelength channel without changing the optical distribution network used in the existing TDM network. There is an advantage that it can be expanded in proportion to the number.

Referring to FIG. 1, the NG-PON2 system, that is, the TWDM-PON system is a hybrid passive optical network accommodating a plurality of stations including n Optical Line Terminals (OLT) using different wavelengths . Assuming that each state company accommodates one PON link, one optical distribution network (ODN) accommodates n identical or heterogeneous networks, and each service is divided into wavelength bands of signals to be used . At this time, the optical network unit (ONU), that is, the NG-PON2 ONU, which is a subscriber device of the TWDM-PON system, multiplexes optical signals of different wavelengths transmitted from the plurality of NG- . Also, in order to communicate with the specific NG-PON2 OLT, it is necessary to be able to select the wavelength of the upstream signal corresponding to the downstream signal. Therefore, the NG-PON2 ONU must have a wavelength selectable transceiver, ie a tunable transceiver. A tunable transceiver includes a tunable laser and a tunable receiver.

2 is a conceptual diagram showing a configuration of a TWDM-PON system, which is a main technology of a next generation passive optical network system. In the system of FIG. 2, it is assumed that there are n OLTs having different wavelengths to be used, and each OLT accommodates one PON link. One optical distribution network (ODN) accommodates n TDM-PON links, and each TDM-PON link can be separated according to wavelengths used independently of each other.

In the system of FIG. 2, the OLT to which each of the ONUs is communicatively connected can be classified according to a wavelength (a wavelength of a downstream signal and a wavelength of a corresponding upstream signal) used. For example, one or more ONUs (e.g., ONU A) can communicate with OLT # 1 with a communication wavelength (downward? _D1 , upward? _U1 ) of OLT # 1 and ONU B can communicate with OLT # And can communicate with the OLT # 2 through the communication wavelength (downward lambda _d2 , upward lambda _u2 ). In this case, each ONU transmits an uplink signal to the OLT using a wavelength matched to the downlink signal allocated to the ONU, or the wavelength corresponding to the downlink signal allocated to the ONU. In the ODN, upstream signals for each wavelength are multiplexed and transmitted in the ODN The multiplexed upstream signals are separated into wavelengths by a demultiplexer (WDM MUX located in the shared infrastructure) and transmitted to the corresponding OLT.

On the other hand, the downlink signals from each OLT are multiplexed by a WDM multiplexer (WDM MUX) located in a shared infrastructure and are also divided by a splitter in an optical distribution network (ODN). Therefore, A downstream signal is input or received. In addition, each OUN selectively utilizes only light of a specific wavelength through a tunable receiver among optical signals of all input wavelengths.

In this TWDM-PON system, a plurality of OLTs are included, and there is a possibility that a traffic imbalance occurs depending on whether or not each ONU connected thereto is operating. For example, due to network conditions, time, etc., a certain OLT, for example, ONUs connected to OLT # 1 may generate a lot of traffic, but ONUs connected to other OLTs may experience traffic imbalance between PON links that generate little traffic. In this case, ONUs connected to OLT # 1 generate traffic loads only at the wavelength of PON link used by OLT # 1, that is, OLT # 1, which may cause problems of not receiving high-quality service, There is a limit that can not be utilized efficiently. Also, there is a problem that unnecessary network resources are wasted because all the OLTs always provide the service including the OLT, which has little traffic even in the night time when the total traffic decreases significantly.

One problem to be solved by the present invention is to provide a time and wavelength division multiplexing-passive optical network system and a communication connection method thereof that can achieve load balancing among a plurality of PON links.

Another problem to be solved by the present invention is to provide a wavelength division multiplexing-passive optical network system and a communication connection method thereof, which can prevent unnecessary waste of network resources.

Another problem to be solved by the present invention is to provide a time and wavelength division multiplexing-passive optical network system in which an OLT to which an ONU having a tunable transmission / reception function can be changed, and a communication connection method therefor.

Another problem to be solved by the present invention is to provide a TWDM-PON system in which a plurality of OLTs and a plurality of ONUs communicate using optical signals of a plurality of wavelengths, and a specific ONU can be connected to an OLT other than an OLT Time division multiplexing-passive optical network system and a communication connection method therefor.

In order to solve the above problems, a TWDM-PON system according to an embodiment of the present invention includes a plurality of optical line devices (OLTs) for providing services in time division multiplexing using optical signals of different wavelengths, (OLT) of a plurality of optical line equipments (OLTs) for supporting communication between optical line devices (OLTs) of a plurality of optical line equipments (OLTs) at a wavelength selected according to wavelength control from the service provider device (OLT), and a plurality of optical network units (ONUs) using a service provided from one of the plurality of optical network units (OLT), and a multi-wavelength downlink optical signal transmitted from the service provider apparatus to the subscriber apparatus, (ODN) for transmitting a multi-wavelength upstream optical signal to be transmitted, wherein the plurality of optical line devices OLT) includes a first optical line device and a second optical line device, wherein a first optical network unit (ONU) communicatively coupled to the first optical line device as one of the plurality of optical network units (ONUs) It can be moved to the line device and connected to the communication line.

According to an embodiment of the present invention, the inter-OLT communication unit may transmit the terminal unique information of the first optical network unit to the second optical line terminal. In this case, the terminal specific information may include an identifier and a serial number of the first optical network unit.

According to another aspect of the embodiment, the first optical line terminal transmits a wavelength change command to the first optical network unit requesting to change the wavelength to the operating wavelength assigned to the second optical line terminal, The line device may periodically transmit an upstream discovery grant signal to the first optical network unit. In this case, the wavelength change command may include an identifier of the first optical network unit and information on an operating wavelength allocated to the second optical line terminal. The wavelength change command may further include time information for the first optical network unit to start tuning for wavelength change. Alternatively, the second optical line terminal periodically transmits the upstream discovery grant signal until it receives an acknowledgment message for the upstream discovery grant signal from the first optical network unit, or until a preset predetermined timer expires . Alternatively, the second optical line terminal may start to transmit the upstream discovery grant signal to the first optical line unit after the first optical line terminal transmits the wavelength change command to the first optical network unit . Alternatively, the first optical network unit may perform the wavelength changing procedure to the operating wavelength assigned to the second optical line terminal immediately after receiving the wavelength change command. In this case, the wavelength changing procedure includes preparing a wavelength change, changing the wavelength of the wavelength tunable transceiver of the first optical network unit, and synchronizing to the downstream signal from the second optical line terminal .

According to another aspect of the present invention, there is provided a method of operating a first optical network unit in a time and wavelength division multiple-passive optical network (TWDM-PON) system, The method comprising: receiving from a first optical line terminal a wavelength change command requesting to change a wavelength to an operating wavelength assigned to the second optical line terminal; And a step of receiving an upstream discovery grant signal transmitted from the second optical line terminal and transmitting an acknowledgment signal to the upstream discovery grant signal to the second optical line terminal.

According to an aspect of the embodiment, the second optical line terminal can receive the terminal specific information of the first optical network unit before transmitting the upstream discovery grant signal. In this case, the terminal specific information may include an identifier and a serial number of the first optical network unit.

According to another aspect of the embodiment, the TWDM-PON system may include a communication unit between optical line devices (OLTs) that support communication between a plurality of optical line devices (OLTs).

According to another aspect of the embodiment, the wavelength change command may include an identifier of the first optical network unit and information on an operation wavelength allocated to the second optical line terminal. In this case, the wavelength change command may further include time information for the first optical network unit to start tuning for wavelength change.

According to another aspect of the above-described embodiment, the second optical line terminal is configured to receive the upstream discovery grant signal from the first optical network unit until it receives the acknowledgment message for the upstream discovery grant signal, or until the preset predetermined timer expires, The Discovery Grant signal can be periodically transmitted.

According to another aspect of the embodiment, the second optical line terminal is configured to transmit the upstream discovery grant signal to the first optical network unit after the first optical line terminal transmits the wavelength change command to the first optical network unit, You can start sending to the unit.

According to another aspect of the present invention, the first optical network unit can perform the wavelength changing procedure to the operating wavelength assigned to the second optical line terminal immediately after receiving the wavelength change command. In this case, the wavelength changing procedure includes preparing a wavelength change, changing the wavelength of the wavelength tunable transceiver of the first optical network unit, and synchronizing to the downstream signal from the second optical line terminal .

According to the embodiment of the present invention, in the TWDM-PON system, the ONU can change the OLT to which the communication is connected, thereby achieving load balancing among a plurality of PON links, as well as power saving of the system, Waste of resources can be prevented.

1 is a diagram illustrating a configuration of an optical network system capable of accommodating a plurality of heterogeneous services into one network by applying a wavelength division method to an existing passive optical network.
2 is a diagram showing an example of the configuration of the TWDM-PON system.
3 is a flowchart illustrating a process of establishing a communication connection between an OLT and an ONU in a G-PON system, which is an example of a TDM-PON system.
4 is a diagram illustrating an example of a configuration of a TWDM-PON system according to an embodiment of the present invention.
5 is a flowchart illustrating a communication connection procedure according to an embodiment of the present invention.
6 is a flowchart illustrating a communication connection procedure according to another embodiment of the present invention.
7 is a flowchart illustrating a communication connection procedure according to another embodiment of the present invention.
8 is a flowchart illustrating a communication connection procedure according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or custom of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

As described above, in the TWDM-PON system, each of the plurality of ONUs communicates at any one wavelength selected from among optical signals of different wavelengths provided by a plurality of OLTs. In this TWDM-PON system, the connection between the OLT and the ONU, that is, the connection between the specific ONU and the OLT, is first set or changed, and the load balancing can be performed according to the traffic situation. By efficiently balancing the load, the TWDM-PON system actively responds to changes in the overall traffic situation over time, connecting ONUs communicating with OLTs with high traffic load to other OLTs with low traffic load, Can be prevented from being concentrated. In addition, it is possible to reduce the power consumption of the system by connecting the ONUs connected to the OLT in which the amount of traffic is relatively low in the TWDM-PON system to other OLTs and turning off the power of the OLTs that do not have communication ONUs The management burden on the corresponding PON link can be lowered. According to this, it is also possible to operate only a part of the OLTs of all the OLTs, for example, at nighttime where the amount of traffic is relatively small.

However, in order to implement the load balancing in the TWDM-PON system, the OLT must know the information about the ONU to be newly connected. That is, the OLT must be able to verify whether the corresponding ONU is an ONU registered with the TWDM-PON system or a service provided through the system. Because the currently discussed TWDM-PON system uses the same ONU registration procedure as the existing TDM-PON system, the OLT must know the information of the ONU in order to establish the connection between the OLT and the ONU.

3 is a flowchart illustrating a process of establishing a communication connection between an OLT and an ONU in a G-PON system, which is an example of a TDM-PON system. The flow chart shown in Fig. 3 is shown in a standard (ITU-T G.987.3) for a known G-PON system, and will be briefly described below. Therefore, the contents of the standard specification for the G-PON system can be directly applied to matters not specifically described herein.

Referring to FIG. 3, the ONU first enters an initialization step (O1) to establish a communication connection with the OLT. In the initialization step, the ONU attempts synchronization with a downstream signal from the OLT. When synchronization is established with respect to the downstream signal, the serial number steps O2 to O3 are entered. In the serial number step, the ONU transmits terminal unique information including its own serial number to the OLT in order to indicate the intention to communicate with the OLT. The ONU then collects burst profile information from the OLT. Subsequently, the OLT confirms whether the serial number of the received ONU is the registered ONU, and if the communication connection is allowed, the ONU assigns the ONU unique identifier (ONU ID) to the ONU. Thereafter, the ONU enters the operation state (O5) through the distance measuring step (O4) and receives the service. The operating state (O5) indicates a state in which a communication connection is established between the ONU and the OLT. During the above-described steps, the OLT refuses to register the ONU, or transmits a registration reject message (Disable SN request) to the registered ONU to cancel or suspend the provided service. The ONU Enters the emergency stop state (O7) and waits for reauthorization from the OLT.

In this manner, according to the communication connection procedure between the ONU and the OLT in the G-PON system, the OLT must be able to acquire the terminal-specific information including the serial number of the ONU requesting the communication connection. This is to confirm that the ONU requesting the communication connection is the ONU registered in the corresponding G-PON system. However, in the existing G-PON system, only one OLT is included and it is possible to have terminal specific information of all ONUs registered in the system. However, the TWDM-PON system includes a plurality of OLTs, Specific information of all registered ONUs (in particular, ONUs communicated with other OLTs). In this situation, in order to allow the OLT connected to the specific ONU to be changed, all the OLTs included in the TWDM-PON system have terminal-specific information of the ONUs connected to other OLTs as well as the ONUs connected thereto, It should be able to acquire in real time. Therefore, a means and / or a procedure is required for sharing the terminal-specific information of all the ONUs registered in the TWDM-PON system with each other or acquiring terminal-specific information of ONUs connected to other OLTs, if necessary.

4 is a diagram illustrating an example of a configuration of a TWDM-PON system according to an embodiment of the present invention. 4, the TWDM-PON system 100 includes a service provider apparatus 110, a light distribution network (ODN) 120, and a subscriber apparatus 130, ), The optical distribution network 120, and the subscriber device 130 are merely illustrative. The TWDM-PON system 100 according to the embodiment of the present invention further includes inter-OLT communication units 114a and 114b inserted in the service provider apparatus 110. [

The service provider apparatus 110 may include a plurality of optical line equipments (OLT) 112a and 112b and a wavelength multiplexer / demultiplexer 116. Each of the OLTs 112a and 112b constituting the service provider apparatus 110 is a device for providing a service in a single wavelength band, and the entire OLTs 112a and 112b may constitute one system or may constitute a separate system. In FIG. 4, the service provider apparatus 110 is shown as including four OLTs 112a and 112b, which is only exemplary. Here, the service provider apparatus 110 including a plurality of OLTs, for example, four OLTs, may have a hybrid mode combining the TDM scheme and the WDM scheme. Such a configuration is suitable as a structure for accommodating a plurality of identical services or heterogeneous service links using various optical wavelength signals. In this case, assuming that each OLT accommodates one TDM-PON link, one optical distribution network accommodates n (n = 4 in the case of Fig. 4) identical or heterogeneous networks, And can be divided into wavelength bands of signals to be used. The wavelength multiplexer / demultiplexer 116 multiplexes light (downstream signals) of different wavelengths output from the plurality of OLTs 112a and 112b and transmits the multiplexed light to the subscriber unit 130 through the optical distribution network 120 Multiplexes the wavelength-multiplexed light (upstream signal) transmitted through the optical distribution network 120 and transmits the demultiplexed light to the corresponding OLTs 112a and 112b.

The service provider apparatus 110 may further include communication units 114a and 114b between optical line devices (OLTs). The inter-OLT communication units 114a and 114b are for communication between the OLTs 112a and 112b of each of a plurality of PON links included in the system 100. [ Communication between the OLTs through the inter-OLT communication units 114a and 114b can be utilized in a procedure of discovering the ONUs 132 and also changing the OLT to which the ONUs 132 are connected between the OLTs 112a and 112b .

For example, inter-OLT communication can be utilized for wavelength tuning of an ONU. More specifically, when an ONU is added to the ODN for the first time, this ONU can proceed with the tuning process of the wavelength tunable receiver to the first wavelength at which the system can be found. After tuning the wavelength tunable receiver, the ONU proceeds to tune the wavelength tunable transmitter based on the tuning wavelength of the tunable receiver. In this case, the wavelength tunable transmitter is likely to communicate with the OLT at the wrong wavelength, in which case the OLT will not be able to communicate with the ONU. In this case, the inter-OLT communication protocol enables the OLT to communicate with another OLT, so that the corresponding ONU can not communicate with another OLT wavelength, or the corresponding ONU (transmitter, receiver, or both) The wavelength can be changed.

As another example, inter-OLT communication can be utilized for ONU activation. If the OLT can inform the ONU of the appropriate wavelength, the ONU can discovery the system or distance ranging can proceed more efficiently. When the ONU tunes the wavelength tunable receiver to a predetermined wavelength, the OLT first checks the protocol database, then queries another OLT for the destination wavelength of the ONU, and then transmits the allocated wavelength information to the ONU. This inter-OLT communication protocol helps to more efficiently determine the final wavelength of the ONU.

According to the present embodiment, the inter-OLT communication units 114a and 114b transmit and receive the terminal-specific information of the ONUs 132 between the OLTs 112a and 112b constituting the service provider apparatus 110. [ According to the present embodiment, there is no particular limitation on a method of configuring the inter-OLT communication units 114a and 114b, and an example thereof is shown in Fig. The configuration of the inter-OLT communication units 114a and 114b shown in FIG. 4 may be an example in which one of the OLTs 112a is a master OLT and the other OLTs 112b are slave OLTs.

Referring to FIG. 4, the inter-OLT communication units 114a and 114b include at least one power splitter 114a and an embedded Optical Network Terminal (ONT) 114b. The power splitter 114a may be a means for branching the light output from the master OLT 112a and delivering it to each of the slave OLTs 112b. In Fig. 4, there are two power splitters 114a, which are merely exemplary. And an embedded ONT 114b for communicating with the master OLT 112a and / or another slave OLT 112b. For example, the built-in light network terminal 114b provided in each of the slave OLTs 112b can receive the light diverged from the power splitter 114a.

The optical distribution network (ODN) 122 distributes the multiplexed downlink signals to the respective ONUs 132 by the wavelength multiplexer / demultiplexer 116. At this time, the light distributed to each ONU 132 may include downlink signals of all wavelengths. The optical distribution network 122 may multiplex upstream signals of a predetermined wavelength received from each of the plurality of ONUs 132 and transmit the upstream signals to the wavelength multiplexer / demultiplexer 116 of the service provider apparatus 110.

The user equipment 130 includes a plurality of optical network units (ONUs) 132. Only four ONUs 132 are shown in FIG. 4 for convenience of illustration, which is only exemplary. All or a part of the ONU 132 may be, for example, an NG-PON2 ONU, and the NG-PON2 ONU can receive wavelength multiplexed downstream optical signals transmitted from a plurality of NG-PON2 OLTs. For this purpose, each of the ONUs 132 may include a wavelength selectable transceiver, that is, a tunable transceiver.

Next, the operation in the system configuration shown in Fig. 4 will be described in more detail. The master OLT 112a can communicate with the first ONU group including one or more ONUs 132 with a downstream signal of a predetermined wavelength? 1 and an upstream signal of a wavelength? '1 corresponding thereto. The master OLT 112a can also communicate with the built-in light network terminal 114b of each of the slave OLTs 112b via the power splitter 114a. Each of the slave OLTs 112b is connected to a different second ONU group including one or more ONUs 132 with a downstream signal of a predetermined wavelength? 2,? 3,? 4 and a corresponding wavelength? 3, lambda 4), and may also communicate with the master OLT 112a via the internal light network terminal 114b.

The master OLT 112a transmits terminal unique information about one or more ONUs included in an ONU group communicatively coupled to each slave OLT 112b from a slave OLT 112b connected through a power splitter 114a and an integrated light network terminal 114b, Lt; / RTI > The terminal unique information includes at least information necessary for the ONU to establish a communication connection with a specific OLT. For example, the terminal specific information may include an identifier (ID) of a terminal and a serial number.

The master OLT 112a may further receive traffic situation information for its PON link from the slave OLT 112b connected to the communication. The traffic situation information from each slave OLT 112b can be used as a basis for achieving load balancing by the master OLT 112a. For example, the mast OLT 112a may connect a part or all of the ONUs connected to the OLT having a relatively large traffic load to the OLT having a relatively small traffic load based on the received traffic situation information, so that the communication between the ONU and the OLT The connection may be changed. At this time, the master OLT 112a and / or the slave OLT 112b may operate by receiving signals related to load balancing from the outside.

In order to receive the terminal-specific information, the master OLT 112a can directly request and receive the terminal-specific information of the ONU to the slave OLT 112b, for example, the first slave OLT. Alternatively, the master OLT 112a may receive the terminal-specific information of the corresponding ONU in response to a request from the first slave OLT.

The master OLT 112a can directly perform a communication connection with the corresponding ONU using the received terminal specific information. On the other hand, the master OLT 112a does not directly establish a communication connection with the corresponding ONU but instead transmits the received terminal specific information so that the slave OLT 112b, for example, the second slave OLT can communicate with the corresponding ONU To the second slave OLT. In the latter case, the master OLT 112a may transmit the wavelength information of the optical signal used by the second slave OLT to the first slave OLT. The first slave OLT may transmit the wavelength information of the received optical signal to the corresponding ONU while requesting the wavelength change to the wavelength used by the second slave OLT.

According to an aspect of this embodiment, the master OLT 112a may be one of a plurality of OLTs providing a service by communicating with one or more ONUs as shown in FIG. In this case, the master OLT 112a may or may not have an internal light network unit. Alternatively, the master OLT 112a may be implemented through a separate device that does not establish a communication connection with one or more ONUs via the optical distribution network 120. [ In this case, the master OLT 112a may communicate with the slave OLT 112b via the power splitter 114a, but not via the wavelength multiplexer / demultiplexer 116. [ That is, the master OLT 112a may perform only functions such as management of other OLTs 112b without providing the ONUs 132 with a service.

As described above, load balancing among the OLTs in the TWDM-PON system can be achieved by adaptively changing the OLT to which the ONU is communicatively connected based on the traffic situation on each PON link. Alternatively, after the specific OLT communicates with all other ONTs communicating with the other OLTs, it can turn off the power or perform management tasks such as maintenance and repair. In this case, from the viewpoint of the entire TWDM-PON system, it is possible to save power by operating only some of the OLTs in all OLTs at nighttime in which traffic is relatively small, and / or to perform tasks such as maintenance, Can be efficiently performed.

In addition, the TWDM-PON system of FIG. 4, in which a particular ONU can change the OLT to which it is communicatively connected, can achieve load balancing and / or system power savings as well as improper OLT access of the ONU Is connected to the wrong ODN), it is possible to support the ONU to be connected to the correct OLT. To this end, an OLT with an ONU located at another ODN may query another OLT or the master OLT, or report the location of the corresponding ONU to the ODN. This not only enables faster problem resolution, but also helps administrators solve problems.

Next, the communication connection procedure in the TWDM-PON system will be described. It is apparent to those skilled in the art that the communication connection procedure described below can be equally applied to a TWDM-PON system having a configuration different from that of FIG. 4 in which inter-OLT communication is possible through the inter-OLT communication unit as well as the TWDM-PON system shown in FIG. The communication connection procedure in the below-described TWDM-PON system is contradictory to the procedure in which the ONU registers with the OLT in the existing TDM-PON system, for example, EPON, GPON, XGPON and 10G-EPON But can also be performed to accommodate it.

5 is a flowchart illustrating a communication connection procedure according to an embodiment of the present invention. The flowchart shown in Fig. 5 is an example of a case where an ONU communicatively connected to the first OLT changes a communication connection to the second OLT. That is, this is an example of a case in which the ONU conducts wavelength tuning with the operating wavelength of the second OLT (including both the downstream wavelength and the upstream wavelength). Here, either one of the first OLT and the second OLT may be the master OLT 112a of FIG. 4 and the other may be the slave OLT 112b or both of them may be the slave OLT 112b. In the latter case, the communication between the first OLT and the second OLT may be relayed by the master OLT 112a or directly without relaying. It will be apparent to those skilled in the art that the communication connection method according to an embodiment of the present invention described below can be applied to a TWDM-PON system having a configuration different from that of FIG. 4, that is, a TWDM-PON system capable of communication between OLTs.

Referring to FIG. 5, the first OLT and the second OLT are operating normally (S202). Here, the 'normal operation between two OLTs' means that the first and second OLTs are in a state in which they can communicate with each other through an OLT communication unit (not shown) provided in the system. In FIG. 5, the first OLT and the second OLT may be separate service provider devices or the same service provider device, but only the ports to which they are connected may be different. Alternatively, the first OLT and the second OLT may communicate with each other via an embedded ONT, or may communicate with each other through other communication circuits of the system. In some cases, medium access control (MAC) elements constituting the first and second OLTs may be directly connected to each other. In any case, a first wavelength (up stream and down stream) is assigned to the first OLT, and a second wavelength (up stream and down stream, respectively) different from the first wavelength is allocated to the second OLT.

Also, although not shown in FIG. 5, the ONU may be allocated to the second OLT or communicatively connected at the time of step S202. And the ONU may be determined to change the communication-connected OLT from the second OLT to the first OLT. There is no particular limitation on the subject or cause for determining whether the OLT to which the ONU is connected is changed from the second OLT to the first OLT in this embodiment.

If it is determined that the OLT to which the ONU is connected is changed from the second OLT to the first OLT, the first OLT and the second OLT communicate with each other to exchange necessary information (S204 to S210). The information exchanged in this process (S204 to S210) may include the terminal-specific information of the ONU which changes at least the OLT. According to the present embodiment, the terminal-specific information of the ONU is provided to the first OLT (the OLT to which the second OLT is connected).

FIG. 5 shows an example of such a process. That is, the processes (S204 to S210) may be an arbitrary process, or some processes may be arbitrary processes. In the former case, if the first OLT already knows the information of the ONU to be newly communicated or acquired in advance from another apparatus (for example, the master OLT of the TWDM-PON system), the above steps S204 to S210 are omitted . As an example of the latter, only the step S206 in which the second OLT transmits ONU information to the first OLT is performed, and the remaining steps are omitted.

Referring to FIG. 5, the first OLT requests the ONU information to the second OLT (S204). The second OLT, which has received the request, transmits the requested ONU information to the first OLT (S206). After receiving the ONU information, the first OLT adds the received ONU information to the registered ONU list (S208), and then requests the second OLT to transmit the wavelength change command to the ONU (S210).

Subsequently, the second OLT transmits a wavelength change command to the ONU (S212). The wavelength change command is an instruction to request the ONU to start the process of establishing a communication connection to the first OLT. The transmission step S212 of the wavelength change command may proceed according to the request (S210) from the first OLT, but is not limited thereto. For example, the second OLT can automatically transmit the ONU information to another OLT when the OLT receives a request for another cause, for example, a request from the overall system manager, or after a predetermined time has elapsed since the start of the procedure, The wavelength change command may be transmitted to the ONU.

The wavelength change command transmitted to the ONU in step S212 may include the identifier information (ONU-ID) of the ONU whose wavelength is to be changed and information about the wavelength to be changed by the ONU. Here, the information on the wavelength to be changed may include at least information about the wavelength of the wavelength-changing target wavelength, that is, the wavelength of each of the downstream and upstream signals for which the first OLT provides service. The wavelength change command may further include time information for the ONU to start tuning for wavelength change. According to the present embodiment, there is no particular limitation on the message format of the wavelength change command. For example, the wavelength change command may be a downstream PLOAM (Physical Layer Operation Administration Maintenance) command, but is not limited thereto.

After the wavelength change command is transmitted from the second OLT to the ONU, according to an embodiment, the ONU that received the wavelength change command may transmit an acknowledgment message (Ack) to the second OLT (S214). Then, the second OLT can notify the ONU that the wavelength change command is normally transmitted to the first OLT (S216). However, steps S214 and S216 are not essential, and at least one of steps S214 and S216 may be omitted depending on the system configuration or policy. For example, as described above, the step (S210) of requesting the wavelength change command from the first OLT to the second OLT may not be performed. In this case, the step (S216) May not be performed. In addition, if the ONU is a system that does not have autonomy to make a decision on a request or command received from the OLT, the ONU must perform a step S214 of transmitting an acknowledgment message (Ack) to the received wavelength change command There may be no.

Subsequently, the ONU that receives the wavelength change command from the second OLT performs a process of changing the operating wavelength (S218). That is, the ONU initiates a wavelength tuning procedure. Although FIG. 5 shows that step S218 is performed after steps S214 and S216, this is only exemplary. That is, the ONU can perform step S218 immediately after receiving the wavelength change command in step S212, irrespective of whether or not steps S214 and S216 are performed, or when steps S214 and S216 are not performed.

According to the temporal example, the ONU can perform the wavelength tuning procedure in the following detailed procedure in step S218. That is, the ONU that has received the wavelength change command first prepares for wavelength change preparation, and a predetermined preparation time can be assigned to the ONU. The preparation process involves the ONU setting the parameters required by the ONU before the tunable transceiver proceeds with the actual tuning procedure. Then, the ONU carries out a tuning process for actually tuning (wavelength changing) the wavelength of the tunable transceiver. The ONU may then proceed with the resynchronization process to proceed with frame synchronization from the downstream signal if necessary.

Then, the first OLT transmits a discovery grant signal to the ONU (S220). Where the Discovery Grant signal may be an upstream discovery grant signal, e.g., a grant signal for upstream PLOAM. The first OLT may also transmit a downstream PLOAM acknowledgment signal to the ONU along with the Discovery Grant signal according to an embodiment. According to an aspect of the present embodiment, the first OLT may periodically repeat the Discovery Grant signal and the downstream PLOAM acknowledgment request signal to the ONU after the wavelength change command is transmitted to the ONU (S214). The first OLT can continue to transmit the Discovery Grant signal or the like until the ONU receives a response from the ONU that the ONU has normally received the Discovery Grant signal or until the predetermined timer expires.

If a Discovery Grant signal and a downstream PLOAM acknowledgment request signal are periodically transmitted from the first OLT in step S218, the ONU that has completed the wavelength tuning for wavelength change (i.e., the downstream from the first OLT) ONU) can normally receive the Discovery Grant signal as shown in step S220. That is, step S220 shown in FIG. 5 indicates that the Discovery Grant signal is normally received after wavelength tuning is completed in step S218 among a plurality of Discovery Grant signals periodically transmitted from the first OLT after step S212.

Subsequently, upon receiving the downstream PLOAM confirmation request signal and the discovery grant signal in step S220, the ONU requests a communication connection to the first OLT (S222). The signal requesting the communication connection of this step may be an acknowledgment signal for the received upstream Discovery Grant signal. This acknowledgment signal may be, for example, an upstream PLOAM completion signal, which may be signaling to the first OLT that the ONU has successfully completed wavelength tuning. The first OLT having received the communication connection from the ONU completes the communication connection with the ONU, and the ONU is normally provided with the service through the wavelength pair (upstream signal wavelength and downstream signal wavelength) of the first OLT (S224).

6 is a flowchart illustrating a communication connection procedure according to another embodiment of the present invention. 6 is an example of a case where an ONU communicatively connected to the first OLT changes the communication connection to the second OLT. The communication connection procedure shown in FIG. 6 differs in that the ONU information is transmitted in the request of the ONU, not in the request from the first OLT in transmitting the second OLT to the first OLT, 5 is substantially the same as the communication connection procedure shown in FIG. Therefore, the communication connection procedure shown in FIG. 6 will be briefly described below, and the matters shown in FIG. 5 may be applied to matters not described in detail here.

Referring to FIG. 6, the first OLT and the second OLT are operating normally (S302). Then, the ONU requests to change the connected OLT from the second OLT to the first OLT (S304). The second OLT transmits the unique information of the ONU to the first OLT according to the request of the ONU, and the first and second OLT communicate with each other to exchange necessary information (S306 to S310). More specifically, the second OLT receiving the request from the ONU transmits the ONU information requested to the first OLT (S306). Subsequently, the first OLT receiving the ONU information adds the received ONU information to the registered ONU list (S308), and then requests the second OLT to transmit the wavelength change command to the ONU (S310).

Subsequently, the second OLT transmits a wavelength change command to the ONU (S312). The wavelength change command is an instruction to request the ONU to initiate the process of communicating with the first OLT, and may include the identifier information (ONU-ID) of the ONU whose wavelength is to be changed and information about the wavelength to be changed by the ONU. In addition, the wavelength change command may further include time information at which the ONU starts tuning for wavelength change. After the wavelength change command is transmitted from the second OLT to the ONU, according to an embodiment, the ONU receiving the wavelength change command may transmit an acknowledgment message (Ack) to the second OLT (S314). The second OLT can notify the first OLT that the wavelength change command has been normally transmitted to the ONU (S316).

Subsequently, the ONU receiving the wavelength change command from the second OLT performs a process of changing the operating wavelength (S318). Then, the first OLT transmits a discovery grant signal to the ONU (S320). According to an aspect of the present embodiment, the first OLT can transmit the Discovery Grant signal periodically to the ONU after the wavelength change command is transmitted to the ONU (S314). If the Discovery Grant signal is periodically transmitted from the first OLT, the ONU that has completed wavelength tuning for wavelength change in step S318 can normally receive the Discovery Grant signal (S320). Upon receiving the discovery grant signal in step S320, the ONU requests a communication connection to the first OLT (S322), and the ONU is normally provided with the service through the wavelength pair (upstream signal wavelength and downstream signal wavelength) of the first OLT (S324).

7 is a flowchart illustrating a communication connection procedure according to another embodiment of the present invention. The flowchart shown in Fig. 7 is an example of a case where an ONU communicatively connected to the second OLT changes the communication connection to the third OLT. 7, the first OLT serves as an intermediary relaying the communication between the second OLT and the third OLT, and in that the change of the OLT is initiated by the request of the first OLT, And the communication connection procedure shown in FIG. 6, and the remaining processes are substantially the same. Therefore, the communication connection procedure shown in FIG. 7 will be briefly described below, and the matters shown in FIG. 5 may be applied to matters not described in detail here. In FIG. 7, the first OLT may be the master OLT 112a shown in FIG. 4, and the second and third OLTs may be the slave OLT 112b, but the present invention is not limited thereto.

Referring to FIG. 7, firstly, a normal operation is performed between the first OLT and the second OLT and between the first OLT and the third OLT (S402). Then, the first OLT requests ONU information to the second OLT (S404). In response to the request of the first OLT, the second OLT transmits the unique information of the ONU to the first OLT, One OLT is used as an intermediary to communicate with each other to exchange necessary information (S405 to S410). More specifically, the second OLT that has received the request from the ONU transmits the ONU information requested to the first OLT (S405), and the first OLT transmits the ONU information received to the third OLT (S406). After receiving the ONU information, the third OLT adds the received ONU information to the registered ONU list (S408), and transmits a confirmation message that the ONU information is added to the first OLT (S409). The first OLT requests the second OLT to transmit a wavelength change command to the ONU (S410).

Subsequently, the second OLT transmits a wavelength change command to the ONU (S412). The wavelength change command is an instruction for requesting the ONU to initiate the process of communicating with the third OLT, and may include the identifier information (ONU-ID) of the ONU whose wavelength is to be changed and information about the wavelength to be changed by the ONU. In addition, the wavelength change command may further include time information at which the ONU starts tuning for wavelength change. After the wavelength change command is transmitted from the second OLT to the ONU, according to an embodiment, the ONU that received the wavelength change command may transmit an acknowledgment message (Ack) to the second OLT (S414). The second OLT informs the first OLT that the wavelength change command has been normally transmitted to the ONU (S415). The first OLT also notifies the third OLT that the wavelength change command has been normally transmitted (S416).

Subsequently, the ONU receiving the wavelength change command from the second OLT performs a process of changing the operating wavelength (S418). Then, the third OLT transmits a discovery grant signal to the ONU (S420). According to one aspect of the present embodiment, the third OLT can transmit the Discovery Grant signal periodically to the ONU after the wavelength change command is transmitted to the ONU (S414). If the Discovery Grant signal is periodically transmitted from the third OLT, the ONU that has completed wavelength tuning for wavelength change in step S418 can normally receive the Discovery Grant signal (S420). Upon receiving the discovery grant signal in step S420, the ONU requests a communication connection to the third OLT (S422), and the ONU is normally provided with the service through the wavelength pair (upstream signal wavelength and downstream signal wavelength) of the third OLT (S424).

The communication connection method described above with reference to FIGS. 4 to 7 is a case in which, in the TWDM-PON system, assuming that the ONU is in communication with any one of the OLTs, . However, the communication connection method according to the embodiment of the present invention is also applied to the case where the ONU does not presumably communicate with any OLT, that is, when the ONU newly establishes a communication connection with a specific OLT in the TWDM-PON system . Here, the specific OLT is an OLT that does not have information on the ONU to be connected to the communication.

8 is a flowchart illustrating a communication connection method in a TWDM-PON system according to another embodiment of the present invention. As described above, the communication connection method shown in Fig. 8 is a case in which the ONU does not establish a communication connection with another OLT in the system before making a communication connection with the second OLT. The present embodiment differs from the above-described embodiments only in that the ONU to be communicatively connected to the second OLT is not communicatively connected to another ONU before, so the present embodiment will be briefly described below. Therefore, the matters not described here can be applied equally to those described above with reference to FIG.

Referring to FIG. 8, the first OLT and the second OLT are operating normally (S502). Here, the normal operation means that the first and second OLTs can communicate with each other through the inter-OLT communication unit (not shown) provided in the system. In this embodiment, the ONU newly registered in the system may be determined to preferentially establish a communication connection with the second OLT. There is no particular limitation on the subject or cause of determining the OLT to which the ONU is connected in this embodiment.

If it is determined that the ONU makes a communication connection with the second OLT, the first OLT obtains the ONU information (S504). Here, the first OLT may be the master OLT responsible for managing the TWDM-PON system. The first OLT provides the ONU information, for example, the unique information of the ONU to the second OLT (S506). Subsequently, the second OLT receiving the ONU information adds the received ONU information to the registered ONU list (S508).

Then, the ONU which intends to register in the TWDM-PON system or uses the service of the TWDM-PON system performs a process of setting the operating wavelength (S510). The setting step S510 of this operating wavelength may be started immediately after the start of this procedure. The operating wavelength includes the transmission wavelength for the upstream signal as well as the reception wavelength for the downstream signal. The ONU may change the reception wavelength to another wavelength if the frame synchronization with respect to the downstream signal is not performed in the wavelength setting step of step S510 (in this case, The OLT to be communicated with is changed and accordingly the operating wavelength can also be changed).

In addition, the second OLT transmits a discovery grant signal to the ONU (S512). According to an aspect of the present invention, the second OLT may periodically repeat the Discovery Grant signal after receiving the ONU information and transmit the Discovery Grant signal to the ONU. And the second OLT can continue to transmit the Discovery Grant signal until the ONU normally receives the Discovery Grant signal or until the predetermined timer expires.

As described above, when the Discovery Grant signal is periodically transmitted from the second OLT, the ONU that has completed the wavelength setting or wavelength tuning in step S510 can normally receive the Discovery Grant signal as shown in step S512. That is, step S512 shown in FIG. 8 indicates that the Discovery Grant signal is normally received after completing the wavelength tuning in step S510 among the Discovery Grant signals periodically transmitted from the second OLT after step S508.

When the discovery grant signal is received in step S512, the ONU requests the second OLT to establish a communication connection (S514). The signal requesting the communication connection of this step may be that the ONU informs the second OLT that wavelength tuning has been completed normally. The second OLT that has received the communication connection from the ONU completes the communication connection with the ONU, and the ONU receives the service normally through the wavelength pair (upstream signal wavelength and downstream signal wavelength) of the second OLT (S516).

The above description is only an example of the present invention, and the technical idea of the present invention should not be interpreted as being limited by this embodiment. The technical idea of the present invention should be specified only by the invention described in the claims. Therefore, it is apparent to those skilled in the art that the above-described embodiments may be modified and embodied in various forms without departing from the technical spirit of the present invention.

Claims (20)

A plurality of optical line devices OLT for providing services in time division multiplexing using optical signals of different wavelengths and optical line devices OLT for supporting communication between the optical line devices OLT A service provider apparatus including a communication unit;
A subscriber unit including a plurality of optical network units (ONUs) using a service provided from one of the plurality of optical line units (OLT) at a wavelength selected according to wavelength control from the service provider apparatus; And
And an optical distribution network (ODN) for transmitting a multi-wavelength downlink optical signal transmitted from the service provider apparatus to the subscriber apparatus and a multi-wavelength uplink optical signal transmitted from the subscriber apparatus to the service provider apparatus,
Wherein the plurality of optical line devices (OLTs) comprise a first optical line device and a second optical line device, wherein the first optical line device (OLT) is in communication with the first optical line device as one of the plurality of optical network units ONU) can be moved to the second optical line terminal and can be communicatively connected. ≪ Desc / Clms Page number 19 > The method according to claim 1,
Wherein the inter-OLT communication unit transmits the terminal-specific information of the first optical network unit to the second optical line terminal. 3. The method of claim 2,
Wherein the terminal unique information includes an identifier and a serial number of the first optical network unit. The method according to claim 1,
The first optical line terminal transmits a wavelength change command to the first optical network unit requesting to change the wavelength to an operating wavelength assigned to the second optical line terminal,
Wherein the second optical line device periodically transmits an upstream discovery grant signal to the first optical network unit. 5. The method of claim 4,
Wherein the wavelength change command includes an identifier of the first optical network unit and information on an operating wavelength allocated to the second optical network unit. 6. The method of claim 5,
Wherein the wavelength change command further includes time information for the first optical network unit to start tuning for wavelength change. 5. The method of claim 4,
The second optical line terminal periodically transmits the upstream Discovery Grant signal until it receives an acknowledgment message for the upstream Discovery Grant signal from the first optical network unit or until a predefined predetermined timer expires Time and wavelength division multiplexed passive optical network system. 5. The method of claim 4,
The second optical line apparatus starts to transmit the upstream discovery grant signal to the first optical network unit after the first optical line apparatus transmits the wavelength change command to the first optical network unit Time and wavelength division multiplexed passive optical network system. 5. The method of claim 4,
Wherein the first optical network unit performs a wavelength changing procedure to an operating wavelength assigned to the second optical line terminal immediately after receiving the wavelength change command. 10. The method of claim 9,
Wherein the wavelength changing procedure comprises preparing a wavelength change, modifying a wavelength of the wavelength tunable transceiver of the first optical network unit, and synchronizing to a downstream signal from the second optical line terminal Time and wavelength division multi - passive optical network system. CLAIMS What is claimed is: 1. A method of communicating with a first optical line unit communicating with a first optical line unit in a time and wavelength division multiple-passive optical network (TWDM-PON) system,
Receiving a wavelength change command from the first optical line terminal requesting to change a wavelength to an operating wavelength assigned to the second optical line terminal;
A wavelength changing step of synchronizing the downstream signal at the operating wavelength according to the wavelength change command; And
And receiving an upstream discovery grant signal transmitted from the second optical line terminal and transmitting an acknowledgment signal for the upstream discovery grant signal to the second optical line terminal. 12. The method of claim 11,
Wherein the second optical line terminal receives the terminal specific information of the first optical network unit before transmitting the upstream discovery grant signal. 13. The method of claim 12,
Wherein the terminal specific information includes an identifier and a serial number of the first optical network unit. 12. The method of claim 11,
Wherein the TWDM-PON system includes a communication unit between optical line devices (OLT) supporting communication between a plurality of optical line devices (OLT). 12. The method of claim 11,
Wherein the wavelength change command includes an identifier of the first optical network unit and information on an operating wavelength allocated to the second optical network unit. 16. The method of claim 15,
Wherein the wavelength change command further includes time information for the first optical network unit to start tuning for wavelength change. 12. The method of claim 11,
The second optical line terminal periodically transmits the upstream Discovery Grant signal until it receives an acknowledgment message for the upstream Discovery Grant signal from the first optical network unit or until a predefined predetermined timer expires A communication connection method in a TWDM-PON system. 12. The method of claim 11,
The second optical line apparatus starts to transmit the upstream discovery grant signal to the first optical network unit after the first optical line apparatus transmits the wavelength change command to the first optical network unit A method of communicating in a TWDM-PON system. 12. The method of claim 11,
Wherein the first optical network unit performs a wavelength changing procedure with an operating wavelength allocated to the second optical line terminal immediately after receiving the wavelength change command. 20. The method of claim 19,
Wherein the wavelength changing procedure comprises preparing a wavelength change, modifying a wavelength of the wavelength tunable transceiver of the first optical network unit, and synchronizing to a downstream signal from the second optical line terminal Communication connection method in TWDM-PON system.

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