JP5492323B1 - Discovery method - Google Patents

Abstract

An object of the present invention is to make it possible to specify the connection position of an ONU on the OSU side when the ONU is connected for the first time in an optical access network using WDM / TDM-PON.
A discovery method according to the present invention is a discovery method in an optical communication system in which wavelength routing means is inserted between a parent node and a plurality of child nodes, from the parent node to a plurality of child nodes. A search signal transmission procedure for transmitting a search signal, a response signal transmission procedure for transmitting a response signal including identification information of the child node from a child node not registered in the parent node to the parent node, And an optical fiber transmission line specifying procedure for specifying which of the plurality of optical fiber transmission line side terminals is connected to the child node via the optical fiber transmission line by receiving the response signal.
[Selection] Figure 3

Description

  The present invention relates to an ONU discovery method in a wavelength tunable WDM / TDM-PON.

  Due to the increasing needs for high-speed access services, FTTH (Fiber To The Home) is spreading worldwide. Most of the FTTH service accommodates a plurality of subscriber side devices (ONU: Optical Network Unit) by time division multiplexing (TDM: Time Division Multiplexing), where one accommodating station side device (OSU: Optical Subscriber Unit) It is provided by a PON (Passive Optical Network) system which is excellent in economy.

  In uplink communication of TDM-PON, the system band is shared between ONUs based on the dynamic band allocation calculation in the OSU, and each ONU 200 is only within the allowable transmission time notified from the OSU 51 as shown in FIG. Intermittent transmission of signal light is prevented by transmitting the signal light intermittently. The current main systems are GE-PON (Gigabit Ethernet (registered trademark) PON) and G-PON (Gigabit-capable PON) whose transmission speed is gigabit class. Due to the appearance of applications to be uploaded / downloaded, the capacity of the PON system 250 is further increased. However, in TDM-PON, because the system bandwidth is expanded by increasing the line rate, the reception characteristics are significantly deteriorated due to the effects of speeding up and chromatic dispersion, and the economics of the burst transmitter / receiver becomes a problem. Large capacity exceeding 10 giga is difficult.

  Application of wavelength division multiplexing (WDM) technology is being studied to increase the capacity beyond 10 Giga. FIG. 2 is an example of WDM / TDM-PON in which WDM technology is combined with TDM-PON. Each ONU 200 is fixedly assigned with a downstream wavelength and an upstream wavelength depending on which terminal of the wavelength multiplexing / demultiplexing means is connected to each ONU 200 via an optical fiber transmission line. Up to the number of OSUs 51 is allowed. Therefore, the system bandwidth can be expanded without increasing the line rate per wavelength by adding the OSU 51.

  Each ONU 200 connected to the same terminal among the terminals of the wavelength multiplexing / demultiplexing means via the optical fiber transmission line is logically connected to the same OSU 51 and shares the upstream and downstream bands. Here, the logical connection between each ONU 200 and the OSU 51 is unchanged, and the bandwidth cannot be shared between the ONUs 200 that are logically connected to different OSUs 51, and the bandwidth fairness is not ensured.

  On the other hand, Non-Patent Document 1 proposes a wavelength tunable WDM / TDM-PON in which an optical transmitter of OSU 51 and ONU 200 in an OLT (Optical Line Terminal) has a wavelength tunable function. FIG. 3 shows a wavelength tunable WDM / TDM-PON proposed by Non-Patent Document 1. Between the OSU 51 and the ONU 200, optical transceiver terminals # 1 to #M (M is an integer of 2 or more) and optical fiber transmission line terminals # 1 to #N (N is an integer of 2 or more), A wavelength routing means 252 having a wavelength distribution function for outputting input light from one terminal determined according to the wavelength is arranged. The optical transceiver side terminals # 1 to #M of the wavelength routing unit 252 are connected to the OSUs # 1 to #M on a one-to-one basis.

  As the wavelength routing means 252, an N × M arrayed waveguide grating (AWG: Arrayed Waveguide Grating) having wavelength recurring properties and input / output characteristics shown in FIGS. 4A and 4B is used. It hits. In this configuration, since the OSU 51 that is logically connected in units of ONUs 200 can be changed by changing the wavelength assigned to the ONUs 200, the system band can be shared among all the ONUs 200. Therefore, the variable wavelength burst transmitter in each ONU 200 is addressed to the logical connection destination OSU 51 determined based on the dynamic bandwidth allocation calculation in the OLT 100 within the notified transmission allowable time at the notified transmission wavelength. By transmitting signal light intermittently, it is possible to ensure bandwidth fairness among all ONUs 200 in upstream communication.

In the wavelength tunable WDM / TDM-PON configuration in which the wavelength routing unit 252 is arranged between the OSU 51 and the ONU 200 as shown in FIG. 3, the wavelength tunable optical transmitter 18 in the OSU 51 is the destination of the input downstream frame. Depending on which optical fiber transmission line side terminal of the wavelength routing means 252 is connected to a certain ONU 200 via the optical fiber transmission line, it is necessary to switch the output optical wavelength in units of frames. For example, when the wavelength routing means 252 has input / output characteristics as shown in FIGS. 4A and 4B, to the wavelength tunable optical transmitter 18 in the OSU # 1 connected to the optical transceiver side terminal # 1. Are connected to optical fiber transmission line side terminals #n (n = 1, 2,..., N) and #n ′ (n ′ = 1, 2,..., N) through optical fiber transmission lines, respectively. Downstream frames addressed to ONU # n-k (k = 1, 2,..., K), # n′-k ′ (k ′ = 1, 2,..., K) are continuously input. In this case, the tunable optical transmitter 18 in the OSU # 1 switches the output optical wavelength in the order of λ _{D_n} and λ _{D_n ′} .

  The OLT 100 reads the destination of the downstream frame input to the OSU 51 for each frame, determines the downstream wavelength by referring to the ONU 200 and downstream wavelength correspondence table, and determines the output optical wavelength of the wavelength tunable optical transmitter 18. By switching to the wavelength, it is possible to realize wavelength switching in units of frames. Here, each OSU 51 is connected one-to-one with the optical transceiver side terminal of the wavelength routing means 252 and is required to transmit a downstream frame addressed to the same ONU 200 at a different wavelength for each OSU 51. On the side, the downstream wavelength corresponding to each ONU 200 needs to be stored for each OSU 51.

  On the other hand, in uplink communication, each ONU 200 refers to an uplink wavelength correspondence table when logically connecting to each OSU 51, and the wavelength is addressed to the logical connection destination OSU determined based on the dynamic bandwidth allocation calculation. It becomes possible to notify each ONU 200 of the upstream wavelength capable of transmitting the upstream signal light via the routing means 252.

  As described above, the wavelength correspondence table of the downstream signal light and upstream signal light when each ONU 200 as shown in FIG. 5 is logically connected to each OSU 51 needs to be held on the OLT 100 side.

H. Nakamura, et al. "40 Gbit / s-class-λ-tunable WDM / TDM-PON using Tunable B-Tx and Cyclic AWG Router for Flexible Aggregation Networks," EcoC2012, Tu. 4). B. 3, 2012

  In order to create the wavelength correspondence table, the ONU 200 is connected to any optical fiber transmission line side terminal of the wavelength routing means 252 through the optical fiber transmission line through a discovery process of registering the unregistered ONU 200 in the OLT 100. It is necessary for the OLT 100 to recognize whether or not However, since the ONU 200 cannot recognize which optical fiber transmission line side terminal it is connected to, it cannot declare the optical fiber transmission line side terminal to be connected from the ONU 200 side. Therefore, the ONU 200 transmits / receives a search signal transmitted from the OLT 100 side in the discovery process and a response signal returned by the unregistered ONU 200 in response to the search signal, so that the ONU 200 transmits any light of the wavelength routing unit 252 via the optical fiber transmission line. A method for autonomously recognizing whether the OLT 100 side is connected to the fiber transmission line side terminal is required.

  In an optical access network using WDM / TDM-PON, when each OSU 51 communicates with the ONU 200, it is necessary to assign a wavelength for performing communication. However, when the ONU 200 is connected for the first time, there is a problem that the connection part of the ONU 200 below the wavelength routing unit 252 cannot be specified on the OLT 100 side.

  Therefore, an object of the present invention is to make it possible to specify the connection position of the ONU on the OLT side when the ONU is connected for the first time in an optical access network using WDM / TDM-PON.

  The invention of the present application is characterized in that ONU identification information is embedded in a response signal returned by the ONU when an ONU search signal is transmitted on the OSU side.

Specifically, the discovery method according to the present invention includes:
One parent node and multiple child nodes are connected via an optical fiber transmission line,
The parent node comprises a plurality of optical transceivers;
Between the parent node and the plurality of child nodes, the downstream signal light from the optical transceiver is output from a different optical fiber transmission line side terminal depending on the wavelength and coupled to the optical fiber transmission line, and the optical fiber Wavelength routing means for inserting the upstream signal light from the optical fiber transmission line inputted from the transmission line side terminal from the optical transceiver side terminal and coupling to the optical transceiver is inserted,
A discovery method in an optical communication system in which the child node is connected to one of a plurality of optical fiber transmission line side terminals of the wavelength routing means via an optical fiber transmission line,
A search signal transmission procedure for transmitting a search signal for searching for an unregistered child node to the parent node from the parent node toward the plurality of child nodes;
The response signal responding to the search signal transmitted from the parent node from the child node not registered in the parent node to the parent node includes the identification information of the child node and the identification information of the wavelength of the response signal. A response signal transmission procedure for transmitting
The parent node compares the combination of the wavelength identification information of the response signal and the optical transceiver side terminal to which the response signal is output with the input / output characteristics of the wavelength routing means, and transmits the response signal. By identifying the optical fiber transmission line side terminal to which the original child node is connected, which of the plurality of optical fiber transmission line terminals is connected to the child node via the optical fiber transmission line An optical fiber transmission line identification procedure for identifying
In order.

In the discovery method according to the present invention,
The search signal in the search signal transmission procedure includes identification information of the wavelength of the response signal,
In the response signal transmission procedure, the child node determines the wavelength of the response signal using identification information of the wavelength of the response signal included in the search signal, and uses the upstream signal light of the determined wavelength. The response signal may be transmitted to the parent node.

In the discovery method according to the present invention,
The child node holds a combination table of the wavelength of the downstream signal light to be received and the wavelength of the upstream signal light to be transmitted,
The search signal in the search signal transmission procedure includes identification information of the wavelength of the search signal,
In the response signal transmission procedure, the child node refers to the combination table, determines the wavelength of the response signal according to the wavelength of the search signal, and uses the uplink signal light of the determined wavelength to transmit the response signal May be transmitted to the parent node.

In the discovery method according to the present invention,
In the response signal transmission procedure, the child node transmits the response signal within a transmission allowable time notified by the search signal,
The transmission allowable time is set so that the arrival time of the response signal transmitted from the child node connected to the different optical fiber transmission line side terminal via the optical fiber transmission line differs from the arrival time of the response signal to the parent node. Determined,
In the optical fiber transmission line identification procedure, the parent node may identify the optical fiber transmission line side terminal to which the child node that is the transmission source of the response signal is connected, based on the time when the response signal arrives.

Specifically, the optical communication system according to the present invention is:
An optical communication system in which one parent node and a plurality of child nodes are connected via an optical fiber transmission line,
The parent node comprises a plurality of optical transceivers;
Between the parent node and the plurality of child nodes, the downstream signal light from the optical transceiver is output from a different optical fiber transmission line side terminal depending on the wavelength and coupled to the optical fiber transmission line, and the optical fiber Wavelength routing means for inserting the upstream signal light from the optical fiber transmission line inputted from the transmission line side terminal from the optical transceiver side terminal and coupling to the optical transceiver is inserted,
The child node is connected to one of a plurality of optical fiber transmission line side terminals of the wavelength routing means via an optical fiber transmission line;
The parent node transmits a search signal for searching for an unregistered child node to the parent node toward the plurality of child nodes ,
When the child node is not registered with the parent node, the child node transmits a response signal responding to the search signal transmitted from the parent node, including identification information of the child node and identification information of the wavelength of the response signal. And
The parent node compares the combination of the wavelength identification information of the response signal and the optical transceiver side terminal from which the response signal is output with the input / output characteristics of the wavelength routing means, and transmits the response signal. By identifying the optical fiber transmission line side terminal to which the original child node is connected, which of the plurality of optical fiber transmission line terminals is connected to the child node via the optical fiber transmission line Is identified .

In the optical communication system according to the present invention,
The child node transmits the response signal within a transmission allowable time notified by the search signal that can be received by the child node,
The parent node determines the allowable transmission time so that arrival times of the response signals transmitted from the child nodes connected to the different optical fiber transmission line side terminals via the optical fiber transmission line are different from each other. Then, the optical fiber transmission line side terminal to which the child node that is the transmission source of the response signal is connected may be specified by the time when the response signal arrives.

  The above inventions can be combined as much as possible.

  According to the present invention, in an optical access network using WDM / TDM-PON, when an ONU is connected for the first time, the connection position of the ONU can be specified on the OLT side.

It is a structural example of TDM-PON. It is an example of WDM / TDM-PON which combined WDM technology with TDM-PON. It is a 1st structural example of wavelength variable type WDM / TDM-PON. An example of the input / output characteristic of the downstream wavelength of a wavelength routing means is shown. An example of the input / output characteristics of the upstream wavelength of the wavelength routing means is shown. An example of the wavelength correspondence table of downstream signal light and upstream signal light is shown. It is a 2nd structural example of wavelength variable type WDM / TDM-PON. It is a 3rd structural example of wavelength variable type WDM / TDM-PON. It is a 4th structural example of wavelength variable type WDM / TDM-PON. The 1st example of the transmission timing of a search signal is shown. The 2nd example of the transmission timing of a search signal is shown. The 1st example of the consultation timing of a response signal is shown. The 2nd example of the consultation timing of a response signal is shown.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are examples of the present invention, and the present invention is not limited to the following embodiments. In the present specification and drawings, the same reference numerals denote the same components.

  The optical communication system according to the present invention includes one OLT 100 that is a parent node, an ONU 200 that is a child node, and wavelength routing means 252. The OLT 100 and the plurality of ONUs 200 are connected via an optical fiber transmission line. The OLT 100 includes a plurality of OSUs 51. The wavelength routing unit 252 is inserted between the OLT 100 and the plurality of ONUs 200.

  Each ONU 200 is connected to one of the plurality of optical fiber transmission line side terminals of the wavelength routing means 252 via the optical fiber transmission line. Each OSU 51 is connected to one of the plurality of optical transceiver side terminals of the wavelength routing means 252. The wavelength routing unit 252 outputs the downstream signal light from the OSU 51 from different optical fiber transmission line side terminals depending on the wavelength, couples it to the optical fiber transmission line, and outputs from the optical fiber transmission line input from the optical fiber transmission line side terminal. The upstream signal light is output from the optical transceiver side terminal and coupled to the optical transceiver.

The ONU 200 discovery method in the wavelength tunable WDM / TDM-PON has a search signal transmission procedure, a response signal transmission procedure, and an optical fiber transmission line identification procedure in this order.
In the search signal transmission procedure, a search signal for searching for an unregistered ONU 200 in the OLT 100 is transmitted from the OLT 100 to a plurality of ONUs 200.
In the response signal transmission procedure, a response signal responding to the search signal transmitted from the OLT 100 is transmitted from the ONU 200 that is not registered in the OLT 100 to the OLT 100, including the identification information of the ONU 200.
In the optical fiber transmission path identification procedure, the OLT 100 uses the identification information of the ONU 200 included in the response signal, and the ONU 200 that is not registered in the OLT 100 determines which of the optical fiber transmission path side terminals and the optical fiber transmission path. To determine if they are connected via

(First embodiment)
In the first embodiment, a wavelength tunable WDM / Wave in which a wavelength routing unit 252 having a wavelength distribution function for outputting input light from one terminal determined according to a wavelength is arranged between the OSU 51 and the ONU 200 is used. Discovery that enables the OLT 100 to autonomously recognize which optical fiber transmission line side terminal of the wavelength routing means 252 is connected to the newly registered ONU 200 via the optical fiber transmission line in the TDM-PON. Is the method.

  The discovery method in the present embodiment will be described by taking the wavelength variable WDM / TDM-PON configuration of FIG. 3 as an example. Note that the wavelength tunable WDM / TDM-PON configuration to which the discovery method according to the present embodiment is applied is not limited to FIG. 3, and the wavelength tunable WDM / TDM-PON in FIG. 3 includes a wavelength tunable filter 22 in the ONU 200 ( 6), or a combination of wavelength multiplexing / demultiplexing means 153 such as AWG or thin film filter, and optical multiplexing / demultiplexing means 151 such as an optical coupler created by an optical fiber or PLC (Planar Lightwave Circuit) (FIG. 7). Application to such as is also possible.

In the wavelength tunable WDM / TDM-PON of FIG. 3, each OSU 51 includes a wavelength tunable optical transmitter 18 that can output wavelengths λ D — ₁ to λ _{D —} N for downlink communication. Downstream signal light from each wavelength tunable optical transmitter 18 is input to the wavelength routing means 252 via a separate optical transmitter / receiver side terminal, and from an optical fiber transmission line side terminal that varies depending on the wavelength to the optical fiber transmission line. Is output. The tunable optical transmitter 18 changes the output optical wavelength according to which optical fiber transmission line side terminal of the wavelength routing means 252 is connected to the ONU 200 that is the destination of the input downstream frame via the optical fiber transmission line. Let

The wavelength tunable optical transmitter 18 is required to have high-speed wavelength tunability that realizes switching of the output wavelength in units of frames. For example, direct modulation lasers having different output light wavelengths are arranged in an array to switch the bias current. This is a configuration in which the laser that emits light is switched. Also, a Mach-Zehnder type modulator using a continuous light from a wavelength tunable light source such as a distributed Bragg reflection type (DBR) laser or an external cavity type laser as a material, a semiconductor or lithium diobate (LiNbO ₃ ). In addition, a configuration in which external modulation is performed using an electroabsorption (EA) modulator, a semiconductor optical amplifier (SOA) modulator, or the like is also possible.

  The ONU 200 is connected to one of the optical fiber transmission line side terminals of the wavelength routing means 252 via the optical fiber transmission line, and receives the downstream signal light output from the optical fiber transmission line side terminal using the optical receiver 29. . Examples of the optical receiver 29 include PIN-PD (Photo-Diode) and APD (Avalanche Photo-Diode). Each ONU 200 uses an ONU identifier such as LLID (Logical Link ID) to determine whether the received frame is addressed to itself, and selects a received frame.

On the other hand, for uplink communication, the ONU 200 includes a wavelength tunable optical transmitter 24 that can output wavelengths λ _U — ₁ to λ _{U_N,} and is within the transmission allowable time notified from the OLT 100 at the uplink wavelength assigned by the OLT 100. Transmit upstream signal light. The allowable transmission time notified from the OLT 100 is determined in consideration of the round trip propagation time (RTT: Round Trip Time) between the OLT 100 and each ONU 200 so that upstream signal lights destined for the same OSU 51 do not collide with each other. Is done. As the wavelength tunable optical transmitter 24, the same configuration as the wavelength tunable optical transmitter 18 in the OSU 51 can be used. Further, when high-speed wavelength tunability is not required, it is possible to change the output light wavelength of a direct modulation laser such as a distributed feedback (DFB) laser by temperature control.

  The upstream signal light transmitted through the optical fiber transmission line is distributed according to the wavelength by the wavelength routing means 252 and input to the OSU 51 through the optical transceiver side terminal. Here, each ONU 200 transmits an upstream signal light including an ONU identifier such as LLID assigned to itself in the transmission frame, so that the OLT 100 can identify the ONU 200 that is the transmission source of the frame by the ONU identifier in the reception frame. .

  As optical receivers in the ONU 200 and the OSU 51, coherent receivers 16 and 27 can be used as shown in FIG. In this case, the output light wavelength of the local light source 28 in the ONU 200 is set near the wavelength of the assigned downstream signal light. On the other hand, the output light wavelength of the local light source 17 in the OSU 51 is changed according to the ONU 200 from which the upstream signal light arriving at the coherent optical receiver 16 is transmitted. By applying coherent reception characterized by high reception sensitivity, the allowable loss in the optical fiber transmission line can be increased. By increasing the transmission loss and branching loss allowed in the optical fiber transmission line, the transmission distance can be lengthened and the number of ONUs to be accommodated can be increased.

In the discovery process, the OLT 100 outputs a search signal in which an instruction for returning a response signal as a registration request to the unregistered ONU 200 is output from all the optical fiber transmission line side terminals of the wavelength routing unit 252. A search signal is transmitted. For example, the wavelength tunable optical transmitter 18 in any one OSU #m (m = 1, 2,..., M) in the OLT 100 transmits the search signals of wavelengths λ _{D —} 1 to λ D — _{N in} a time multiplexed manner. To do. Even if the search signal for each wavelength is intensively transmitted at a predetermined interval Δt ₀ as shown in FIG. 9 (a), the search signal for each wavelength is dispersed and given as shown in FIG. 9 (b). May be transmitted at every interval Δt ₀ .

Search signals of wavelengths λ _{D —} 1 to λ D — _N are distributed according to the wavelength in wavelength routing means 252 and output from different optical fiber transmission line side terminals. When the wavelength routing means 252 has the input / output characteristics as shown in FIG. 4 and the wavelength tunable optical transmitter 18 in the OSU # 1 connected to the optical transceiver side terminal # 1 transmits the search signal, the wavelength λ _{D_1} , lambda _{D_2,} ..., search signal lambda _{d_n} in turn the optical fiber transmission line side terminals # 1, # 2, ..., outputted from the # N. Thus, since search signals are output from all optical fiber transmission line side terminals, unregistered ONUs 200 can reliably search regardless of which optical fiber transmission line side terminal is connected via the optical fiber transmission line. The signal can be received. In the wavelength tunable WDM / TDM-PON configuration of FIG. 6 provided with the wavelength tunable filter 22 in the ONU ₂₀₀ , the transmission wavelength of the wavelength tunable filter 22 is periodically _{unswept in} the range of λ _{D —} 1 to λ D_N, and is not registered. The ONU 200 can reliably receive the search signal regardless of which optical fiber transmission line side terminal is connected via the optical fiber transmission line.

The search signal describes an instruction to transmit a response signal as a registration request within the transmission allowable time when the received ONU 200 is not registered in the OLT 100. The unregistered ONU 200 that has received the search signal transmits a response signal at a wavelength λ _{U —} n (n = 1, 2,..., N) at a random time within the transmission allowable time. Describes the identification information of the wavelength of the response signal in addition to the identification information of the ONU 200 that is the transmission source. As a method of determining the wavelength λ _{U_n of the} response signal in the ONU 200, a method of specifying λ _{U_n} from the OLT 100 side by the search signal, or a combination table of the wavelength of the downstream signal light received by the ONU 200 and the wavelength of the upstream signal light to be transmitted And λ _{U_n} is determined by comparing the identification information of the wavelength of the search signal described in the search signal with the combination table.

  The response signal transmitted through the optical fiber transmission line is distributed according to the wavelength by the wavelength routing means 252 and then received by the optical receiver 19 in the OSU 51. At this time, since the wavelength identification information is described in the response signal, the OLT 100 can recognize the transmission source ONU 200 and the wavelength of the received response signal.

Here, the combination of the wavelength of the recognized response signal and the number of the optical transceiver side terminal of the wavelength routing unit 252 connected to the OSU 51 including the optical receiver 19 is compared with the input / output characteristics of the wavelength routing unit 252. Thus, it is possible to specify the number of the optical fiber transmission line side terminal to which the response signal is input to the wavelength routing unit 252. For example, when the wavelength routing means 252 has the input / output characteristics as shown in FIG. 4 and the optical receiver 19 in the OSU # 1 receives a response signal of the wavelength λ _{U —} 1, the response signal is the optical fiber transmission line side terminal # 1. Can be identified as being input to the wavelength routing means 252. When the optical receiver 19 in the OSU # 1 receives a response signal having the wavelength λ _{U_N} , it can be specified that the response signal is input from the optical fiber transmission line side terminal #N to the wavelength routing unit 252. Therefore, by transmitting and receiving the search signal and the response signal as described above, the ONU 200 that is the transmission source of the response signal can autonomously recognize the optical fiber transmission line side terminal connected through the optical fiber transmission line on the OLT 100 side. It becomes possible. As a result, by comparing the recognized optical fiber transmission line side terminal number with the input / output characteristics of the wavelength routing means 252, the downlink / uplink wavelength when the ONU 200 is logically connected to each OSU 51 is determined, as shown in FIG. Wavelength correspondence table can be created.

The optical receiver 19 that receives the response signal may be the optical receiver 19 in the same OSU 51 as the OSU 51 that includes the tunable optical transmitter 24 that transmitted the search signal, or the optical receiver 19 in a different OSU 51. For example, when the wavelength routing unit 252 has input / output characteristics as shown in FIG. 4 and the wavelength tunable optical transmitter 18 in the OSU # 1 connected to the optical transceiver side terminal # 1 transmits a search signal, the wavelength λ _{D_1, λ D_2, λ D3,} ···, the wavelength of the response signal specified according to search signal lambda _{d_n,} turn _{λ U_1, λ U_2, λ U_3} , ···, when a λ _{U_N,} optical fiber The response signal returned from the ONU 200 connected to the different optical fiber transmission line side terminals of the wavelength routing means 252 via the transmission line is the same OSU # as the OSU # 1 including the wavelength variable optical transmitter 18 that has transmitted the search signal. 1 is received by the optical receiver 19 within the frame 1. Wavelength _{λ D_1, λ D_2, λ D3} , ···, the wavelength of the response signal specified according to search signal lambda _{d_n,} turn _{λ U_N, λ U_1, λ U_2} , ···, λ U_N-1 and Then, the OSU # 1 includes the tunable optical transmitter 18 in which the response signal returned from the ONU 200 connected to the different optical fiber transmission line side terminals of the wavelength routing means 252 via the optical fiber transmission line includes the search signal. Is received by the optical receiver 19 in OSU # 2, which is different from FIG. Even if the wavelength of the response signal is specified so that the response wavelength input from the different optical fiber transmission line side terminals to the wavelength routing means 252 is received by the single optical receiver 19, a plurality of optical receivers 19 are provided. May be specified to be received.

  In the discovery process according to the present embodiment, the ONU 200 performs wavelength routing via the optical fiber transmission line on the OLT 100 side through transmission / reception of a search signal transmitted from the OLT 100 side and a response signal returned by the unregistered ONU 200 in response to the search signal. Since it is possible to autonomously determine which optical fiber transmission line side terminal of the means 252 is connected to, the downlink / uplink wavelength when the ONU 200 is logically connected to each OSU 100 is determined, and the wavelength correspondence table as shown in FIG. Can be created. As a result, the destination of the downstream frame input to the OSU 51 is read for each frame, the downstream wavelength is determined by referring to the wavelength correspondence table, and the output wavelength of the tunable optical transmitter 18 in the OSU 51 is determined as the downstream wavelength. By switching, wavelength switching in units of frames can be realized. Further, by referring to the wavelength correspondence table, the upstream wavelength capable of transmitting the upstream signal light to the logical connection destination OSU 51 determined based on the dynamic bandwidth allocation calculation via the wavelength routing unit 252 is determined. The ONU 200 can be notified.

(Second Embodiment)
In the second embodiment, a wavelength tunable WDM / Wave in which wavelength routing means 252 having a wavelength distribution function for outputting input light from one terminal determined according to the wavelength is arranged between the OSU 51 and the ONU 200 is used. In TDM-PON, the ONU 200 to be newly registered is connected to which optical fiber transmission line side terminal of the wavelength routing means 252 via the optical fiber transmission line by a method different from the discovery method in the first embodiment. Is a discovery method that allows the OLT 100 to autonomously recognize.

  The discovery method in the present embodiment will be described by taking the wavelength variable WDM / TDM-PON configuration of FIG. 3 as an example. Note that the wavelength tunable WDM / TDM-PON configuration to which the discovery method according to the present embodiment is applied is not limited to FIG. 3, and the wavelength tunable WDM / TDM-PON in FIG. 3 includes a wavelength tunable filter 22 in the ONU 200 ( 6), or a combination of wavelength multiplexing / demultiplexing means 153 such as AWG or thin film filter and optical multiplexing / demultiplexing means 151 such as an optical coupler made of optical fiber or PLC (FIG. 7). Is possible.

In the discovery process, the OLT 100 outputs a search signal in which an instruction for returning a response signal as a registration request to the unregistered ONU 200 is output from all the optical fiber transmission line side terminals of the wavelength routing unit 252. A search signal is transmitted. For example, the wavelength tunable optical transmitter 18 in any one OSU #m (m = 1, 2,..., M) in the OLT 100 transmits the search signals of wavelengths λ _{D —} 1 to λ D — _{N in} a time multiplexed manner. To do. Search signal wavelength lambda _{D_1} to [lambda] _{d_n} is distributed according to the wavelength in the wavelength routing means 252, to be outputted from each different optical fiber transmission line side terminal, unregistered ONU200 is one through the optical fiber transmission line The search signal can be reliably received regardless of whether it is connected to the optical fiber transmission line side terminal. In the wavelength tunable WDM / TDM-PON configuration of FIG. 6 provided with the wavelength tunable filter 22 in the ONU ₂₀₀ , the transmission wavelength of the wavelength tunable filter 22 is periodically _{unswept in} the range of λ _{D —} 1 to λ D_N, and is not registered. The ONU 200 can reliably receive the search signal regardless of which optical fiber transmission line side terminal is connected via the optical fiber transmission line.

When the received ONU 200 is not registered in the OLT 100, the search signal having the wavelength λ _{D_n} (n = 1, 2,..., N) is within ΔT _n after Δt _n from the time when the search signal is received. An instruction to transmit a response signal as a registration request is described. The unregistered ONU 200 that has received the search signal transmits a response signal at a wavelength λ _{U — n ′} (n ′ = 1, 2,..., N) at a random time within the transmission allowable time. In the signal, the identification information of the ONU 200 that is the transmission source is described. As a method of determining the wavelength λ _{U_n ′} of the response signal in the ONU 200, a method of specifying λ _{U_n ′} from the OLT 100 side by the search signal, a wavelength of the downstream signal light received by the ONU 200, and a wavelength of the upstream signal light to be transmitted There is a method in which a combination table is held and λ _{U_n ′} is determined by comparing the wavelength identification information of the search signal described in the search signal with the combination table. The response signal transmitted through the optical fiber transmission line is distributed according to the wavelength by the wavelength routing means 252 and then received by the optical receiver 19 in the OSU 51. At this time, since the identification information of the transmission source ONU 200 is described in the response signal, the OLT 100 can identify the transmission source ONU 200 of the received response signal.

_{T rtt_min} the RTT between the ONU 200 and the OLT100 distance to wavelength routing means 252 closest in ONU 200, and _{T RTT_max} the RTT between the wavelength routing means the distance to 252 farthest ONU 200 and OLT100 Then, the OLT 100 receives the response signal having the wavelength λ _{U_n ′} within the response signal reception window #n from the time when the search signal having the wavelength λ _{D_n} is transmitted to Δt _n + T _{RTT_min} to Δt _n + ΔT _n + T _{RTT_max.} To do. That is, the response signal reception window for receiving the response signal can be set by the values of Δt _n and ΔT _n included in the search signal.

Response signal reception windows # 1 to #N that receive response signals for the search signals of wavelengths λ _{D_1 to} λ D_N are _temporally set by setting the allowable transmission time of the response signal for the search signal so as to satisfy a predetermined condition. It can be made not to overlap. For example, when transmitting from time _{T 0} at a predetermined interval Delta] t ₀ the search signal wavelength lambda _{D_1} to [lambda] _{d_n} intensive as in FIG. 10 (a), the response signal reception window to receive a response time with respect to the wavelength lambda _{D_n} end time _T of #n 0 + (n-1) × Δt 0 + Δt n + ΔT n + T RTT_max is, the start of the response signal reception window # n + 1 which receives the response time with respect to the wavelength lambda _{D_n + 1} time _{T 0 + n × Δt 0 +} Δt n + 1 By setting the values of Δt _n , ΔT _n , and Δt _{n + 1} so as to be before + T _{RTT_min} , temporal overlap between the response signal reception windows # 1 to #N can be prevented. Also, as shown in FIG. 10B, when the search signals of the respective wavelengths are dispersed and transmitted at a predetermined interval Δt ₀ , the values of Δt _n , ΔT _n , and Δt _{n + 1} are the same as those in FIG. By setting so as to satisfy, it is possible to prevent temporal overlap between the response signal reception windows # 1 to #N. In this case, the OLT 100 can recognize the response signal for the search signal of which wavelength depending on when the response signal is received within the response signal reception window. Furthermore, as described above, since the OLT 100 can specify the transmission source ONU 200 of the received response signal, the wavelength of the search signal received by the ONU 200 can be recognized.

  Here, the combination of the wavelength of the recognized search signal and the number of the optical transceiver side terminal of the wavelength routing unit 252 connected to the OSU 51 including the wavelength tunable optical transmitter 18 that has transmitted the search signal is determined by the wavelength routing unit 252. By comparing with the input / output characteristics, it is possible to specify the number of the optical fiber transmission line side terminal from which the search signal is output from the wavelength routing means 252. Therefore, by transmitting and receiving the search signal and the response signal as described above, the ONU 200 that is the transmission source of the response signal can autonomously recognize the optical fiber transmission line side terminal connected through the optical fiber transmission line on the OLT 100 side. It becomes possible. As a result, by comparing the recognized optical fiber transmission line side terminal number with the input / output characteristics of the wavelength routing means 252, the downlink / uplink wavelength when the ONU 200 is logically connected to each OSU 51 is determined, as shown in FIG. Wavelength correspondence table can be created.

  As in the first embodiment, the optical receiver 19 that receives the response signal is the same optical receiver 19 in the same OSU 51 as the OSU 51 that includes the variable wavelength optical transmitter 18 that transmitted the search signal. The optical receiver 19 may be used. Even if the wavelength of the response signal is specified so that the response wavelength input from the different optical fiber transmission line side terminals to the wavelength routing means 252 is received by the single optical receiver 19, a plurality of optical receivers 19 are provided. May be specified to be received.

  In the discovery process according to the present embodiment, the ONU 200 performs wavelength routing via the optical fiber transmission line on the OLT 100 side through transmission / reception of a search signal transmitted from the OLT 100 side and a response signal returned by the unregistered ONU 200 in response to the search signal. Since it is possible to autonomously determine which optical fiber transmission line side terminal of the means 252 is connected to, the downlink / uplink wavelength when the ONU 200 is logically connected to each OSU 51 is determined, and a wavelength correspondence table as shown in FIG. Can be created. As a result, the destination of the downstream frame input to the OSU 51 is read for each frame, the downstream wavelength is determined by referring to the wavelength correspondence table, and the output wavelength of the tunable optical transmitter 18 in the OSU 51 is determined as the downstream wavelength. By switching, wavelength switching in units of frames can be realized. Further, by referring to the wavelength correspondence table, the upstream wavelength capable of transmitting the upstream signal light to the logical connection destination OSU 51 determined based on the dynamic bandwidth allocation calculation via the wavelength routing unit 252 is determined. The ONU 200 can be notified.

  The present invention can be applied to the information communication industry.

12: Wavelength multiplexing / demultiplexing means 16: Coherent receiver 17: Local light source 18: Wavelength variable optical transmitter 19: Optical receiver 19a: Wavelength variable optical receiver 21: Light receiver 22: Wavelength variable filter 23: Optical receiver 24: wavelength tunable optical transmitter 26: wavelength multiplexing / demultiplexing means 27: coherent receiver 28: local light source 29: optical receiver 51: OSU
100: OLT
151: Optical multiplexing / demultiplexing unit 153: Wavelength multiplexing / demultiplexing means 200: ONU
250: PON system 252: Wavelength routing means

Claims (6)

One parent node and multiple child nodes are connected via an optical fiber transmission line,
The parent node comprises a plurality of optical transceivers;
Between the parent node and the plurality of child nodes, the downstream signal light from the optical transceiver is output from a different optical fiber transmission line side terminal depending on the wavelength and coupled to the optical fiber transmission line, and the optical fiber Wavelength routing means for inserting the upstream signal light from the optical fiber transmission line inputted from the transmission line side terminal from the optical transceiver side terminal and coupling to the optical transceiver is inserted,
A discovery method in an optical communication system in which the child node is connected to one of a plurality of optical fiber transmission line side terminals of the wavelength routing means via an optical fiber transmission line,
A search signal transmission procedure for transmitting a search signal for searching for an unregistered child node to the parent node from the parent node toward the plurality of child nodes;
The response signal responding to the search signal transmitted from the parent node from the child node not registered in the parent node to the parent node includes the identification information of the child node and the identification information of the wavelength of the response signal. A response signal transmission procedure for transmitting
The parent node compares the combination of the wavelength identification information of the response signal and the optical transceiver side terminal to which the response signal is output with the input / output characteristics of the wavelength routing means, and transmits the response signal. By identifying the optical fiber transmission line side terminal to which the original child node is connected, which of the plurality of optical fiber transmission line terminals is connected to the child node via the optical fiber transmission line An optical fiber transmission line identification procedure for identifying
The discovery method which has in order. The search signal in the search signal transmission procedure includes identification information of the wavelength of the response signal,
In the response signal transmission procedure, the child node determines the wavelength of the response signal using identification information of the wavelength of the response signal included in the search signal, and uses the upstream signal light of the determined wavelength. The discovery method according to claim 1 , wherein the response signal is transmitted to the parent node. The child node holds a combination table of the wavelength of the downstream signal light to be received and the wavelength of the upstream signal light to be transmitted,
The search signal in the search signal transmission procedure includes identification information of the wavelength of the search signal,
In the response signal transmission procedure, the child node refers to the combination table, determines the wavelength of the response signal according to the wavelength of the search signal, and uses the uplink signal light of the determined wavelength to transmit the response signal The discovery method according to claim 1 , further comprising: transmitting to the parent node. In the response signal transmission procedure, the child node transmits the response signal within a transmission allowable time notified by the search signal,
The transmission allowable time is set so that the arrival time of the response signal transmitted from the child node connected to the different optical fiber transmission line side terminal via the optical fiber transmission line differs from the arrival time of the response signal to the parent node. Determined,
In the optical fiber transmission line specifying procedure, the parent node specifies the optical fiber transmission line side terminal to which the child node that is a transmission source of the response signal is connected, based on a time when the response signal arrives. The discovery method according to any one of claims 1 to 3 . An optical communication system in which one parent node and a plurality of child nodes are connected via an optical fiber transmission line,
The parent node comprises a plurality of optical transceivers;
Between the parent node and the plurality of child nodes, the downstream signal light from the optical transceiver is output from a different optical fiber transmission line side terminal depending on the wavelength and coupled to the optical fiber transmission line, and the optical fiber Wavelength routing means for inserting the upstream signal light from the optical fiber transmission line inputted from the transmission line side terminal from the optical transceiver side terminal and coupling to the optical transceiver is inserted,
The child node is connected to one of a plurality of optical fiber transmission line side terminals of the wavelength routing means via an optical fiber transmission line;
The parent node transmits a search signal for searching for an unregistered child node to the parent node toward the plurality of child nodes ,
When the child node is not registered with the parent node, the child node transmits a response signal responding to the search signal transmitted from the parent node, including identification information of the child node and identification information of the wavelength of the response signal. And
The parent node compares the combination of the wavelength identification information of the response signal and the optical transceiver side terminal from which the response signal is output with the input / output characteristics of the wavelength routing means, and transmits the response signal. By identifying the optical fiber transmission line side terminal to which the original child node is connected, which of the plurality of optical fiber transmission line terminals is connected to the child node via the optical fiber transmission line An optical communication system for identifying The child node transmits the response signal within a transmission allowable time notified by the search signal that can be received by the child node,
The parent node determines the allowable transmission time so that arrival times of the response signals transmitted from the child nodes connected to the different optical fiber transmission line side terminals via the optical fiber transmission line are different from each other. Then, by the time when the response signal arrives, the optical fiber transmission line side terminal to which the child node that is the transmission source of the response signal is connected is identified.
The optical communication system according to claim 5 .

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