JP2001358697A - Optical access network, optical network terminating device, and optical subscriber line terminating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To actualize an optical access network which can construct network constitution, especially regarding economical aspects and has high expandability. SOLUTION: This optical access network has a wavelength router, which outputs light inputted to an input port to a different output port according to the wavelength; optical subscriber line terminating means which have functions arranged on a relaying side are placed by services or service groups, and send and receive light signals; and network terminating means which have functions arranged on user sides are placed by users or user groups, and send and receive light signals. Further, the network is constituted by connecting the optical subscriber line terminating means and wavelength router, and the network terminating means and wavelength router by optical fibers having more than one core. The optical fiber between the network terminating means and wavelength router is equipped with a control means which performs service multiplexing for allocating channels that the network terminating means handle to lights of different wavelength, and the optical fiber between the optical subscriber line terminating means and wavelength router is equipped with a control means which performs user multiplexing for allocating different wavelengths by the network terminating means.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical access network for providing a high-speed broadband communication service, and in particular, to realize an access network which can be constructed economically and has high expandability. Optical access network.

[0002]

2. Description of the Related Art A conventional communication network, as shown in FIG.
It has a hierarchical structure composed of a long-distance station 50, a main line station 51, and a branch station 52, and a user 54 is accommodated in a node of the branch station 52 through a subscriber transmission line 53. In such a communication network, the conventional access network is a portion composed of a node of the branch office 52, a subscriber transmission line 53, and a device on the user side.

As a subscriber transmission line in a conventional access network, a twisted-pair copper wire has been used for low-speed services including analog telephone services, and an optical fiber has been used for medium-high speed services. In each case, a single star (SS) configuration is used in which a subscriber line terminal LT (Line Terminal) installed at a branch line node and a network terminal NT (Network Terminal) are connected 1: 1. .

FIG. 16 shows an example of such a configuration. Each service has a corresponding LT56 and NT58
Is used. When a new service is provided, a subscriber transmission line 53 corresponding to the service is set, and LT 56 as the station side device 55 and NT 58 as the user side device are installed at 1: 1 at both ends. The numeral 59 in the figure is
Network Node Interface (NNI)
de Interface).

[0005] At this time, when a plurality of services using the same user network interface (UNI) are simultaneously provided, one subscriber transmission path and one NT are respectively provided. Time division multiplexing (TDM) for signals corresponding to services
May be transmitted. (In the figure, the user / network interface is indicated by numeral code 60)

In recent years, a passive double star (PDS; Passive Double Star) as shown in FIG.
Star) Construction of an optical access network with a configuration is underway. This is because an optical passive branching element 62 is inserted in the middle of an optical subscriber transmission line 61 connecting the optical line terminal 55 and the user side device 57, and one LT 56 is connected to a plurality of NT5s of the user side device 57.
The aim is to make the economy economical by sharing the information with other companies.

In this configuration, since the optical subscriber transmission line 61 can be shared between the LT 56 of the optical line terminal 55 and the optical passive branching element 62, the cost of the optical transmission line can be reduced.
At present, a system using a star coupler (SC) for equally distributing optical power as an optical passive branching element has been put into practical use, and a radius of about 7 km connecting a branch node and a user as in an old access network. Is applicable to the range.

In this system, signals corresponding to a plurality of services are TDM-transmitted to one NT. A method using a wavelength router that can selectively change an output port according to the wavelength of incident light as an optical passive branch element with the same passive double-star configuration has also been proposed.

FIG. 18 shows an example of this configuration. This method uses wavelength division multiplexing (WDM).
xing) WDM-PDS
Called the scheme. The wavelength router 63 used in this method is
Since it is an element that sorts the optical path according to the wavelength, it has a feature that the loss is small as compared with the SC in which the branch loss is unavoidable in principle.

Therefore, it is possible to lengthen the subscriber transmission path as compared with the PDS system using the SC. In this system, the LT 56 and each NT 58 communicate with each other by individually assigned wavelengths. Between the LT 56 and the wavelength router 63, an optical signal having a wavelength corresponding to each of these NTs 58 is subjected to WDM. In other words, this system can be said to be a system for introducing user multiplexing by WDM into a part of the optical subscriber transmission line.

[0011]

SUMMARY OF THE INVENTION A first conventional example, S
The communication network having the S configuration has the following problems because service-compatible LTs are installed in a number of branch offices directly accommodating users. (1) Even when the number of users accommodated in one branch office is small, the LT needs to be installed, so that the equipment cost per user increases. (2) A long period of time is required for nationwide deployment of services because LTs are installed in branch offices, and in some areas, it is difficult to provide services promptly in response to user requests.

[0012] Also in the PDS system using the SC, which is the second conventional example, the applicable transmission path distance is almost the same as that in the SS configuration, and the service which is not supported by this system is required. Has the same problem as described above because it is necessary to install the LT and the NT in the SS configuration.

The third conventional WDM-PDS system uses WDM for user multiplexing, and does not consider the efficient provision of a plurality of services by WDM without using TDM. was there.

An object of the present invention is to construct an optical access network in which facility costs per user are small and service can be quickly deployed in order to solve the conventional problems as described above. Another object of the present invention is to realize a transmission method for efficiently providing a plurality of services by WDM in such an optical access network.

[0015]

According to the present invention, the above-mentioned object is solved by the means described in the claims. That is, the invention of claim 1 has a plurality of optical fiber input ports and a plurality of optical fiber output ports,
A wavelength router that outputs light to different outputs according to the wavelength of the light that enters the input port, and a light that is provided on the relay side of the access network and transmits and receives optical signals that are placed for each service or multiple service groups Subscriber line terminating means (corresponding to OLT in the embodiment);

An optical network terminating means (corresponding to an ONU in the embodiment) which is provided on the user side of the access network and transmits / receives an optical signal placed for each user or for each of a plurality of user groups; Optical access constituted by connecting the subscriber line terminating means and the wavelength router with one or more optical fibers, and connecting the optical network terminating means and the wavelength router with one or more optical fibers. With a net,

In an optical fiber between the optical network terminating means and the wavelength router, service multiplexing for allocating a plurality of channels handled by the optical network terminating means to lights of different wavelengths is performed. The optical fiber between the wavelength routers is an optical access network that performs user multiplexing by assigning different wavelengths to the respective optical network terminating means. In the present invention, the service multiplexing of the first and third embodiments described later is performed by DWDM.
Corresponds to the case of

According to a second aspect of the present invention, there is provided a wavelength router having a plurality of optical fiber input ports and a plurality of optical fiber output ports and outputting light to different outputs according to the wavelength of the light entering the input port, and an access network. The optical subscriber line termination means (corresponding to the OLT in the embodiment) for transmitting and receiving an optical signal placed for each service or for a plurality of service groups, and for the user side of the access network And optical network terminating means (corresponding to the ONU in the embodiment) for transmitting and receiving an optical signal placed for each user or for each of a plurality of user groups, and between the optical subscriber line terminating means and the wavelength router. 1
An optical access network connected by an optical fiber having at least one core, wherein the optical network terminating means and the wavelength router are connected by one or more optical fibers,

The wavelength region that can be transmitted by the optical fiber is divided into a plurality of wavelength bands and assigned to each of the optical network unit terminating means, and a wavelength is assigned to each of the optical network terminating means in each wavelength band. In the optical fiber between the optical network terminating means and the wavelength router, service multiplexing for allocating a plurality of channels handled by the optical network terminating means to different wavelength bands is performed, and the optical subscriber line terminating means and the wavelength router are linked. The optical fiber between them is an optical access network that performs user multiplexing in which different wavelengths are assigned to the respective optical network terminating means. The present invention corresponds to the case where the service multiplexing of the first and third embodiments described later is CWDM.

According to a third aspect of the present invention, there is provided a wavelength router having one or two optical fiber input ports and a plurality of optical fiber output ports, and outputting light to different outputs according to the wavelength of the light entering the input port; Optical subscriber line terminating means (O in the embodiment) which is provided with a function on the relay side of the access network and transmits / receives an optical signal placed for each service or a plurality of service groups.
LT), and multiplexes the optical signals from the plurality of optical subscriber line terminating means and outputs the multiplexed optical signals to the optical fiber. Conversely, it demultiplexes the input light from the optical fiber and demultiplexes the optical subscriber lines. Service demultiplexing means (corresponding to the service multiplexing element in the embodiment) for distributing to the terminating means;

An optical network terminating means (corresponding to the ONU in the embodiment) which is provided on the user side of the access network and transmits / receives an optical signal placed for each user or for each of a plurality of user groups. Service demultiplexing means and the wavelength router are arranged between the subscriber line terminating means and the optical network terminating means, and the optical subscriber line terminating means and the service demultiplexing means are connected by an optical waveguide; An optical access network configured by connecting the service demultiplexing means and the wavelength router with one or more optical fibers, and connecting the optical network terminating means and the wavelength router with one or more optical fibers; And

The wavelength range that can be transmitted by the optical fiber is divided into a plurality of wavelength bands and assigned to each of the optical network unit terminating means, and a wavelength is assigned to each of the optical network terminating means in each wavelength band. In the optical fiber between the optical network terminating means and the wavelength router, a plurality of channels handled by the optical network terminating means are subjected to service multiplexing that allocates different wavelength bands, and a service multiplexing / separating means and the wavelength router are provided. The optical fiber is an optical access network that simultaneously performs service multiplexing for assigning a wavelength band for each service and user multiplexing for assigning different wavelengths to each of the optical network terminating means within the same wavelength band. This invention corresponds to Examples 2 and 4 described below.

According to a fourth aspect of the present invention, in the optical access network according to any one of the first to third aspects, in a section of a two-core optical fiber, the optical network is switched from the optical network unit to the optical network. The optical signal in the direction of the terminating means and the optical signal in the direction from the optical network terminating means to the optical network unit terminating means pass through different optical fiber cores. In the present invention, the two-core section and the one-core section may be mixed,
In the core section, optical fibers are used for up and down.

According to a fifth aspect of the present invention, in the optical access network according to any one of the first to third aspects, in a single optical fiber section, the optical network unit terminates the optical network from the optical network unit. The optical signal in the direction of the optical network and the optical signal in the direction from the optical network terminal to the optical network unit are allocated to different wavelengths or wavelength bands. In the present invention, the two-core section and the one-core section may be mixed,
In the core section, wavelength multiplexing is used for up and down. 2 core section is 1
The wavelength of the core section may be used as it is.

According to a sixth aspect of the present invention, in the optical access network according to any one of the first to third aspects, a direction from the optical network unit terminating unit to the optical network terminating unit by a single optical fiber. Means for allocating the same wavelength to the optical signal of the optical network and the optical signal from the optical network terminating means to the optical subscriber line terminating means and separating the optical signal for each propagation direction (optical circulator in the embodiment). It is configured to be provided in the line terminating means or the service demultiplexing means and the optical network terminating means. In this invention, all sections are single-core optical fibers, and the receiving end device separates upstream and downstream optical signals by a circulator.

According to a seventh aspect of the present invention, in the optical access network according to any one of the first to third aspects, a direction from the optical network unit terminating unit to the optical network terminating unit by a single optical fiber. The same wavelength is assigned to the optical signal and the optical signal from the optical network terminating means to the optical subscriber line terminating means, and the uplink signal and the downlink signal are transmitted in a time-division multiplexed manner. is there. In the present invention, all sections are single-core optical fibers, and the receiving end device separates upstream and downstream optical signals according to time.

The invention according to claim 8 corresponds to each optical network terminating device, corresponds to n optical transmitters for transmitting optical signals of different wavelengths from each other, and corresponds to each optical network terminating device. N optical receivers for receiving optical signals having different wavelengths from each other and an optical subscriber transmission line composed of two-core optical fibers are connected to each other. Multiplexing / demultiplexing element that outputs to the optical fiber for transmission and splits the optical signal from the optical fiber for upstream transmission to each optical receiver, and is connected to each optical transmitter and each optical receiver to transmit the optical subscriber signal. An optical network unit that assembles and disassembles a frame used in a path and includes an interface conversion unit that provides an appropriate network node interface to a higher-level network. The present invention corresponds to the configuration of FIG. 2 described later.

According to a ninth aspect of the present invention, m optical transmitters for transmitting optical signals having mutually different wavelengths correspond to each of the optical network units, and each of the optical network units has an optical transmitter. It is compatible with m optical receivers that receive optical signals of different wavelengths and is connected to an optical subscriber transmission line consisting of two optical fibers, and demultiplexes the signal from the downstream transmission optical fiber. Service multiplexing / demultiplexing device that inputs each optical receiver to each optical receiver, multiplexes the output of each optical transmitter, and outputs it to the upstream transmission optical fiber, and an interface conversion circuit corresponding to m kinds of optical subscriber line transmission systems , And each of the interface conversion circuits is connected to the corresponding optical transmitter and optical receiver, and includes an interface conversion unit for assembling and disassembling a frame used in the optical subscriber transmission line. It is a network termination unit. The present invention corresponds to the configuration of FIG. 3 described later.

According to a tenth aspect of the present invention, each of the optical network terminating devices corresponds to an optical network terminating device, n optical transmitters for transmitting optical signals having mutually different wavelengths, and each of the optical network terminating devices. N optical receivers for receiving optical signals having different wavelengths from each other and an optical subscriber transmission line composed of a single optical fiber are connected to each other. A user / bidirectional demultiplexing element for outputting a signal to the optical subscriber transmission line and demultiplexing an upstream optical signal of the optical subscriber transmission line to each optical receiver; each optical transmitter and each optical receiver; And an interface converter for assembling and disassembling a frame used in the optical subscriber transmission line, and providing an appropriate network node interface for a higher-level network. Line end It is the location. The present invention relates to FIG.
Corresponding to the configuration.

An eleventh aspect of the present invention corresponds to each optical network unit, and includes m optical transmitters for transmitting optical signals having different wavelengths, and an optical network unit for each optical network unit. M optical receivers for receiving optical signals having different wavelengths from each other, and connected to an optical subscriber transmission line composed of a single optical fiber, for demultiplexing a downstream optical signal to each optical receiver. And a service / bidirectional demultiplexing element for multiplexing the output of each optical transmitter and outputting the multiplexed optical signal as an upstream optical signal to the optical subscriber transmission line, and supports m types of optical subscriber line transmission systems. An interface conversion circuit configured with an interface conversion circuit, each of which is connected to an optical transmitter and an optical receiver corresponding thereto, and assembling and disassembling a frame used in the optical subscriber transmission line. Including An optical network unit comprising at. The present invention corresponds to the configuration of FIG. 10 described later.

As described above, the present invention provides a PDS in which an LT is installed at a position equivalent to a trunk station and a wavelength router is installed at a position equivalent to a branch station in a conventional communication network configuration, and the optical subscriber transmission line is lengthened. The present invention is characterized in that a wide-area optical access network that can be configured is configured. Further, the LT and each NT communicate with each other using individual wavelengths, and provide a plurality of services to the same NT by WDM. As a result, the restrictions on the access network in the conventional communication network configuration are eliminated, and efficient service deployment at low cost becomes possible.

[0032]

Embodiments of the present invention will be described below in detail with reference to the drawings. In all the drawings for describing the embodiments, components having the same function will not be described repeatedly. In addition, among the illustrated components, if there are a plurality of the same components, in order to avoid complicating the drawing, only one of the components is denoted by a numeral symbol, and the other components are omitted. ing.

As for the wavelength assignment, LT
And each NT communicate using an individual wavelength, and provide a plurality of services to the same NT by WDM.
A wavelength band having an appropriate wavelength width is allocated to the LT that provides each service, and an individual wavelength is allocated to each NT in the wavelength band. The wavelength band assigned to each LT may be the same or different depending on the LT, but different LTs do not assign the same wavelength to one NT.

[First Embodiment] FIG. 1 shows an entire configuration of a first example (referred to as a first embodiment) of the present embodiment. In the present embodiment, at position 1 corresponding to a trunk station of a conventional communication network,
M types of optical line terminal O on the office side indicated by numeral code 3
An LT (Optical Line Terminal) and a wavelength router 5 are installed at positions corresponding to branch offices. OLT is an apparatus having an LT function in an optical access network, and OLT # 1 to OLT # 1
LT # m provides an optical subscriber line transmission system corresponding to different services.

Each OLT 3 is individually connected to a wavelength router 5 by a two-core optical fiber 4a of an optical subscriber transmission line. Similarly, a plurality of optical network terminating devices (ONUs: Optical Network Units) indicated by reference numeral 6 are individually connected to the wavelength router 5 by two-core optical fibers 4a. An ONU is a device having an NT function in an optical access network. At this time, the number of ONUs 6 connected to one wavelength router 5 is n.

In an optical subscriber transmission path between each OLT and the wavelength router 5, user multiplexing for multiplexing optical signals corresponding to each ONU is performed, and an optical subscriber transmission path between each ONU 6 and the wavelength router 5 is provided. In, service multiplexing for multiplexing optical signals corresponding to each OLT is performed. Each of these
Implemented by WDM. In addition, for transmission of a downlink signal from a station to a user and transmission of an uplink signal from a user to a station,
One of the two-core optical fibers in the optical subscriber transmission line is assigned. That is, bidirectional signals are spatially multiplexed.

The wavelength router 5 used in the present embodiment
For example, an arrayed waveguide diffraction grating (AWG; Arrayed Waveguide Gratin created by a planar lightwave circuit)
g). For example, a configuration in which a two-core optical fiber is connected to one AWG, or two AWs
G is prepared and the optical fiber for up and down is separately AWG
A configuration for connecting to the network is conceivable.

FIG. 2 shows an example of the configuration of the OLT. N optical transmitters (OpticalSender) OS # 11 indicated by numeral code 8
OS # 1n and n optical receivers (Optical Receivers) OR # 11 to OR # 1n indicated by numeral code 9 are connected to the optical subscriber transmission line 4a via the user demultiplexing element 10. OS # 11 to OS # 1n are ONU # respectively
1 to ONU # n, and transmits optical signals having different wavelengths.

These optical signals are multiplexed by the user multiplexing / demultiplexing element, and then output to the downstream transmission optical fiber. Similarly, OR # 11 to OR # 1n are ON respectively.
It corresponds to U # 1 to ONU # n and receives optical signals of different wavelengths. These optical signals are input from the upstream transmission optical fiber to the user demultiplexing element,
Demultiplexed to However, if the user does not want the service provided by the OLT, the OLT corresponding to the ONU
S and OR may not be set.

Each OS and OR is connected to an interface conversion unit IF # 1 indicated by numeral code 11. IF #
1 assembles and disassembles a frame used in an optical subscriber transmission line, and also, for an upper network, an appropriate network node interface (NNI;
Network Node Interface) (NNI is indicated by numeral 2 in the figure).

FIG. 3 shows an example of the configuration of the ONU. M optical receivers OR # 21 to OR # 2m indicated by numeral code 9 and m optical transmitters OS # 21 to OS # 2m indicated by numeral code 8
Is connected to the optical subscriber transmission line 4 via the service demultiplexing element 12. OR # 21 to OR # 2m correspond to OLT # 1 to OLT # m, respectively, and receive optical signals of different wavelengths.

These optical signals are input from the downstream transmission optical fiber to the service multiplexing / demultiplexing element 12, and are demultiplexed to each OR. Similarly, OS # 21 to OS # 2m correspond to OLT # 1 to OLT # m, respectively, and transmit optical signals having mutually different wavelengths. These optical signals are multiplexed in the service multiplexing / demultiplexing element 12, and then output to the upstream transmission optical fiber.

Each OS and OR is connected to an interface conversion unit IF # 2 indicated by numeral 13. IF #
2 assembles and disassembles the frames used in the optical subscriber transmission line, and transmits an appropriate U to the user terminal.
Provide NI. IF # 2 is OLT # 1 to OLT #
m, that is, interface conversion circuits IF # 21 to IF # 2m corresponding to the m types of optical subscriber line transmission systems, and the corresponding OS and OR are connected.

However, the interface conversion circuit and the OS. The OR may not be set. The wavelength of the optical signal transmitted by each OS of the OLT or ONU or the wavelength of the optical signal received by each OR is suitable for the input / output characteristics of the wavelength router. That is, an optical signal transmitted from each OLT is distributed to an optical subscriber transmission line to a predetermined ONU in the wavelength router, and an optical signal transmitted from each ONU is conveyed to the predetermined OLT in the wavelength router. Allocated to the subscriber transmission path.

The user multiplexing performed on the optical subscriber transmission line between the OLT and the wavelength router is a so-called dense wavelength multiplexing (DWDM; Dense).
Wavelength Division Multiplexing).
Specifically, each OLT allocates a wavelength having an interval of several nm or less to each ONU. The wavelength interval is typically 0.8 nm, 1.6 nm, or the like, but may be different from these values as long as it matches the input / output characteristics of the wavelength router.

The user multiplexing / demultiplexing element used in the OLT multiplexes / demultiplexes these wavelengths. In particular, the demultiplexing function is required to have the same or similar performance as the wavelength router. Such a user demultiplexing element is
For example, it can be configured using AWG. In this case, a configuration using separate AWGs for uplink transmission and downlink transmission, or a configuration using a common AWG can be considered.

On the other hand, the service multiplexing performed on the optical subscriber transmission line between the ONU and the wavelength router is so-called coarse wavelength division multiplexing (Coarse Wavelength Division Multiplex) having a wide wavelength interval.
ing) and DWDM. When CWDM is used, a wavelength region that can be transmitted by an optical fiber is divided into a plurality of wavelength bands, and these are allocated to each OLT. Then, the wavelength corresponding to each ONU in the allocated wavelength band is allocated by the above-described DWDM.

FIG. 4 shows this conceptual diagram. However, the wavelength assignment method in FIG. 4 is an example. The width of one wavelength band is almost equal to the free spectral range (FSR) of the wavelength router used, and does not overlap with another wavelength band. The FSR gives the wavelength cycle of the input / output characteristics of the wavelength router, and its value is usually several tens nm or more. In the case of a two-core optical fiber, there is no need to distinguish between up and down.

In this case, the wavelength handled by each ONU is several tens of nm.
Because of the above separation, the wavelength demultiplexing function required for the element for service demultiplexing becomes looser than that of the wavelength router.
Such a service demultiplexing element can be constituted by, for example, a dielectric multilayer filter or a fiber grating.

When service multiplexing is performed by DWDM, a plurality of OLTs share a wavelength using the reciprocity of input / output characteristics of a wavelength router. In order to explain the circularity of the input / output characteristics of the wavelength router, FIG.
4 shows input / output characteristics of a wavelength router having four input / output ports. Now, it is assumed that the wavelengths that give the peak of the optical power transmittance to each right port when light enters the left port # 1 are given by λ1, λ2, λ3, λ4 in order from port # 1.

The intervals between these wavelengths are all equal. At this time, when the wavelength multiplexed light of the four wavelengths λ1, λ2, λ3, and λ4 is input to one of the left and right ports, the wavelength output to the opposite port is given as shown in FIG.
In the present embodiment, since the OLTs are connected to different ports by individual optical fibers, if such a property is used, even if a plurality of OLTs use the same wavelength, the wavelength router to the ONU The same wavelengths do not overlap in the optical fiber between them, thus enabling WDM.

FIG. 6 shows a conceptual diagram of wavelength assignment. However, the wavelength assignment method in FIG. 6 is an example. Each O
A wavelength having an interval of several nm or less is assigned to the LT and each ONU. This wavelength interval is dense and 0.8 to
1.6 nm, which is the same as the case of user multiplexing by DWDM described above. Also, the service demultiplexing element in the ONU must have the same demultiplexing characteristics as the user demultiplexing element in the OLT 1, and this can be realized by, for example, an AWG.

Since the wavelength router used in this embodiment has a small loss, it is possible to extend the optical subscriber transmission path, that is, to widen the optical access network, as compared with a PDS configuration using an existing SC. is there. In addition, even when a new service is added, there is no need to set up a new subscriber transmission path between the wavelength router and the ONU, or to construct a new frame by TDM, and to interface with optical components of the corresponding wavelength. The service can be provided only by adding the conversion unit.

Further, in the present embodiment, since the downstream signal and the upstream signal are transmitted using different optical fibers, there is no need to consider these multiplexing methods, and the transmission system design is highly flexible. Further, since each OLT and the wavelength router are connected by an individual optical fiber, it is also suitable for a network configuration in which the OLT is distributed and arranged in a plurality of stations.

[Embodiment 2] FIG. 7 shows a second embodiment of the present invention.
(The second embodiment) is shown. In the present embodiment, a service multiplexing element 14 and a service separating element 1 are provided in the middle of a two-core optical fiber 4a connecting between each OLT and a wavelength router with respect to upstream and downstream optical fibers.
5 is different from the first example of the embodiment.
That is, in the example of the present embodiment, a plurality of OLTs 3 are aggregated by these elements and connected to the wavelength router 5.

The wavelength router and each ONU are connected by an individual two-core optical fiber 4a as in the first embodiment. The service separating element 15 is configured by, for example, a dielectric multilayer filter or a fiber grating.
It is for CWDM applications where the wavelength interval is several tens of nm or more.
That is, in the present embodiment, the wavelength router to each O
Service multiplexing on optical subscriber transmission lines between NUs is CWD
M.

The service multiplexing is performed not only between the ONU and the wavelength router but also in the optical subscriber transmission line between the service multiplexing element and the wavelength router or between the service separating element and the wavelength router. On the other hand, user multiplexing is performed between the OLT and the wavelength router as in the first embodiment.
Performed by DM. The concept of wavelength assignment is shown in FIG.
E Same as described. OLT. The configuration of the ONU is the same as that in the first embodiment. However, the service demultiplexing element provided in the ONU is CWD.
Limited to those corresponding to M.

In the present embodiment, as in the first embodiment, it is possible to widen the area of the optical access network and easily add services. Further, between the OLT and the wavelength router, it is possible to cope with a plurality of services by using a two-core optical fiber, so that transmission line costs can be reduced.

[Embodiment 3] FIG. 8 shows a third embodiment of the present invention.
(Referred to as Embodiment 3) is shown. In the present embodiment, the communication between the OLT and the wavelength router and between the wavelength router and the O
This embodiment differs from the first embodiment in that a single-core optical fiber 4b is used for an optical subscriber transmission line between NUs. Each OLT and each ONU are individually connected to a wavelength router.

In the optical subscriber transmission path between the OLT and the wavelength router, user multiplexing for multiplexing optical signals corresponding to each ONU is performed. In the optical subscriber transmission path between the ONU and the wavelength router, each OLT is The point of performing service multiplexing for multiplexing corresponding optical signals is the same as in the first embodiment. DWDM for user multiplexing and CW for service multiplexing
The same applies to the case of performing by DM or DWDM.

The transmission of the downlink signal from the station to the user and the transmission of the uplink signal from the user to the station are performed by multiplexing on the same optical fiber core. This includes time axis compression multiplexing (TCM; Time
Compression Multiplexing), Direction multiplexing (DDM; Direct
ional Division Multiplexing), CWDM. DWDM
Can be considered.

FIG. 9 shows an example of the configuration of the OLT. The OSs and ORs indicated by numerals 8 and 9 are connected via a user / bidirectional demultiplexing element 16 to a single-core optical fiber 4b as an optical subscriber transmission line. The upper network has an interface converter IF # indicated by numeral code 11.
1 are connected. Each 0S. The functions of OR and IF # 1 are the same as in the first embodiment. The user / bidirectional multiplexing / demultiplexing element 16 performs a multiplexing / demultiplexing of bidirectional transmission and has a function suitable for DWDM performed as user multiplexing.

FIG. 10 shows an example of the configuration of the ONU. Each OS. The OR is connected via a service / bidirectional demultiplexing element 17 to a single-core optical fiber which is an optical subscriber transmission line. The user terminal is connected via an interface conversion unit IF # 2 indicated by numeral code 13. The functions of each OS, OR and IF # 2 are as follows:
This is the same as in the first embodiment. service/
The bidirectional demultiplexing element 17 performs demultiplexing of bidirectional transmission and has a function suitable for CWDM or DWDM performed as service multiplexing.

The concept of wavelength assignment when bidirectional multiplexing is performed by TCM or DDM is the same as in FIG. 4 or FIG. FIG. 4 corresponds to the case where service multiplexing is performed by CWDM, and FIG. 6 corresponds to the case of performing service multiplexing by DWDM. Element 1 for user / bidirectional demultiplexing in OLT
6 can be composed of, for example, a combination of a 3 dB coupler in the case of TCM, a circulator in the case of DDM, and an AWG.

The service / bidirectional demultiplexing element 17 in the ONU can have the same configuration. However, in the case where service multiplexing is performed by CWDM, a combination of a dielectric multilayer filter, a fiber grating, and a 3 dB coupler or a circulator can be used instead of AWG.

On the other hand, the concept of wavelength assignment when bidirectional transmission multiplexing is performed by CWDM is as shown in FIG. 11 or FIG. However, the wavelength allocation method in FIGS. 11 and 12 is an example. FIG. 11 corresponds to the case where service multiplexing is performed by CWDM, and FIG. 12 corresponds to the case of performing service multiplexing by DWDM. In either case, different wavelength bands are assigned to downstream signal transmission and upstream signal transmission, but there is no distinction of wavelength bands for OLT in FIG.

In these cases, the user / bidirectional demultiplexing element in the OLT can be realized by, for example, a dielectric multilayer filter or a combination of a fiber grating and an AWG. The element for service / bidirectional demultiplexing in the ONU can have the same configuration. However,
When service multiplexing is performed by CWDM, it can be configured by a dielectric multilayer filter or a fiber grating.

When multiplexing of bidirectional transmission is performed by DWDM, it is appropriate that service multiplexing is also performed by DWDM. The concept of wavelength assignment in this case is as shown in FIG. However, the wavelength assignment method in FIG. 13 is an example. For a certain ONU, different wavelengths are assigned to the upstream signal transmission and the downstream signal transmission, and these wavelengths are different ports in the user / bidirectional demultiplexing element in the OLT and the service / bidirectional demultiplexing element in the ONU. However, when passing through a wavelength router, they are distributed to the same route.

In order to realize this, it is necessary to set the wavelength resolution of the user / bidirectional demultiplexing element and the service / bidirectional demultiplexing element more finely than those of the wavelength router. These elements can be constituted by AWG, for example. The present embodiment enables widening of the optical access network and easy addition of services as in the first embodiment, and is also suitable for a network configuration in which OLTs are distributed and arranged in a plurality of stations. I have. Furthermore, since the number of optical fiber cores of the optical subscriber transmission line can be reduced to half that of the first embodiment, the transmission line cost can be reduced.

[Fourth Embodiment] FIG. 14 shows an overall configuration of a fourth example (referred to as a fourth embodiment) of the embodiment. This embodiment is different from the third embodiment in that a service multiplexing / demultiplexing element 12 is provided in the middle of a single optical fiber 4b connecting each OLT to a wavelength router. That is, in the present embodiment, a plurality of OLTs
And are connected to the wavelength router. As in the third embodiment, the wavelength router and each ONU are connected by individual single-core optical fibers.

The service demultiplexing element is used for CWDM applications having a wavelength interval of several tens nm or more, such as a dielectric multilayer filter or a fiber grating. That is, in the present embodiment, service multiplexing on the optical subscriber transmission line is limited to CWDM.
The service multiplexing is performed not only between the ONU and the wavelength router but also on the optical subscriber transmission path between the service multiplexing / demultiplexing element and the wavelength router. On the other hand, user multiplexing is performed by DWDM between the OLT and the wavelength router, as in the third embodiment.

The multiplexing of the transmission of the uplink signal and the transmission of the downlink signal is performed according to TCM. DDM or CWDM is possible. The concept of wavelength allocation at this time is the same as that described in FIG. 4 for TCM and DDM, and the same as that described in FIG. 11 for CWDM. Also, OL
The configurations of T and ONU are the same as in the third embodiment.

That is, when multiplexing bidirectional transmission is performed by TCM, a combination of a 3 dB coupler, when performing multiplexing by DDM, a circulator, and a dielectric multilayer filter or fiber grating suitable for CWDM is possible. When multiplexing bidirectional transmission is performed by CWDM, it can be configured by a dielectric multilayer filter or a fiber grating.

This embodiment enables the optical access network to be wide-area and easy service addition, as in the first embodiment. Furthermore, since a single-core optical fiber can cope with a plurality of services between the OLT and the wavelength router, transmission line costs can be reduced.

[0075]

As described above in detail, according to the present invention, since both service multiplexing and user multiplexing in an optical subscriber transmission line are realized by WDM, a flexible transmission system design becomes possible and new services can be provided. Can be easily added. Further, the use of a low-loss wavelength router makes it possible to widen the optical access network. This allows
A communication network configuration in which the OLT is not installed in the branch office in the conventional communication network but the OLT is installed collectively in the trunk office. With these effects, it is possible to construct an optical access network suitable for low-cost and rapid service deployment.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a first example of an embodiment of the present invention.

FIG. 2 is a configuration diagram of an OLT according to the first embodiment.

FIG. 3 is a configuration diagram of an ONU according to the first embodiment.

FIG. 4 is a conceptual diagram of wavelength assignment when service multiplexing is performed by CWDM in the first embodiment.

FIG. 5 is an input / output characteristic diagram of the wavelength router according to the first embodiment.

FIG. 6 is a conceptual diagram of wavelength assignment when service multiplexing is performed by DWDM in the first embodiment.

FIG. 7 is an overall configuration diagram of a second example of the embodiment of the present invention.

FIG. 8 is an overall configuration diagram of a third example of the embodiment of the present invention.

FIG. 9 is a configuration diagram of an OLT according to a third embodiment.

FIG. 10 is a configuration diagram of an ONU in the embodiment 3;

FIG. 11 is a conceptual diagram of wavelength allocation when service multiplexing is performed by CWDM and bidirectional transmission multiplexing is performed by CWDM in the third embodiment.

FIG. 12 is a conceptual diagram of wavelength allocation when service multiplexing is performed by DWDM and bidirectional transmission is multiplexed by CWDM in the third embodiment.

FIG. 13 is a conceptual diagram of wavelength allocation when service multiplexing is performed by DWDM and bidirectional transmission multiplexing is performed by DWDM in the third embodiment.

FIG. 14 is an overall configuration diagram of a fourth example of an embodiment of the present invention.

FIG. 15 is a configuration diagram schematically showing an entire conventional network.

FIG. 16 is a configuration diagram of an access network having a conventional SS configuration.

FIG. 17 is a configuration diagram of an access network having a conventional PDS configuration.

FIG. 18 is a configuration diagram of an access network based on the WDM-PON scheme.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Location equivalent to trunk line node 2 NNI 3 Optical subscriber line termination device 4a 2-core optical fiber 4b 1-core optical fiber 5 Wavelength router 6 Optical network termination device 7 UNI 8 Optical transmitter 9 Optical receiver 10 User demultiplexing element 11 Interface converter IF # 1 12 Element for service demultiplexing 13 Interface converter IF # 2 14 Element for service multiplexing 15 Element for service demultiplexing 16 Element for user / bidirectional demultiplexing 17 Element for service / bidirectional demultiplexing

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takeshi Kitagawa 2-3-1 Otemachi, Chiyoda-ku, Tokyo Inside Nippon Telegraph and Telephone Corporation (72) Inventor Yasuyoshi Inoue 2-3-3, Otemachi, Chiyoda-ku, Tokyo No. 1 Within Nippon Telegraph and Telephone Corporation (72) Inventor Hitoshi Agematsu 2-3-1 Otemachi, Chiyoda-ku, Tokyo F-term within Nippon Telegraph and Telephone Corporation (reference) 5K002 AA01 AA03 DA02 DA04 DA12 FA01 5K069 AA13 BA09 CB10 DB33 EA24 EA25 EA30

Claims (11)

[Claims] 1. A wavelength router having a plurality of optical fiber input ports and a plurality of optical fiber output ports, and outputting light to a different output port according to the wavelength of the light entering the input port; Optical subscriber line terminating means that is provided with functions and is provided for each service or a plurality of service groups to transmit and receive optical signals, and that functions are provided on the user side of the access network and provided for each user or each of a plurality of user groups. Optical network terminating means for transmitting and receiving optical signals through the optical network. The optical subscriber line terminating means and the wavelength router are connected by one or more optical fibers, and the optical network terminating means and the wavelength router are connected to each other. An optical access network constituted by connecting one or more optical fibers between the optical network terminating means and an optical fiber between the optical network terminating means and the wavelength router, wherein a plurality of channels handled by the optical network terminating means are provided. Control means for performing service multiplexing for assigning to light of different wavelengths, and for controlling an optical fiber between the optical network unit and the wavelength router, performing user multiplexing for assigning different wavelengths to each of the optical network terminating means. An optical access network, characterized by: 2. A wavelength router having a plurality of fiber input ports and a plurality of fiber output ports and outputting light to a different output port according to the wavelength of light entering the input port, and a function provided on a relay side of the access network. Optical subscriber line terminating means for transmitting and receiving optical signals for each service or for a plurality of service groups, and a function provided on the user side of the access network, and for each user or for each of a plurality of user groups. An optical network terminating means for transmitting and receiving signals, connecting the optical subscriber line terminating means and the wavelength router with one or more optical fibers, and connecting the optical network terminating means and the wavelength router. Is connected by one or more optical fibers, an optical access network, wherein a wavelength region that can be transmitted by the optical fiber is divided into a plurality of wavelength bands and assigned to each of the optical network unit, Respectively A service in which a wavelength is assigned to each of the optical network terminating means in a wavelength band, and a plurality of channels handled by the optical network terminating means are assigned to different wavelength bands in an optical fiber between the optical network terminating means and the wavelength router. An optical access network, comprising: a control unit that performs multiplexing and that performs user multiplexing in which an optical fiber between the optical network unit and the wavelength router assigns a different wavelength to each of the optical network unit. . 3. A wavelength router having one or two optical fiber input ports and a plurality of optical fiber output ports, and outputting light to a different output port according to the wavelength of light entering the input port, and relaying an access network. Optical line termination means for transmitting and receiving an optical signal placed for each service or a plurality of service groups, and multiplexing the optical signals from the plurality of optical line termination means to provide an optical signal. Service multiplexing / demultiplexing means for outputting to an optical fiber and conversely demultiplexing the input light from the optical fiber and distributing it to each of the optical network unit terminating means; and a function provided on the user side of the access network, for each user or a plurality of Optical network termination means for transmitting and receiving optical signals placed for each user group, between the optical network termination means and the optical network termination means,
Service multiplexing / demultiplexing means and the wavelength router are arranged; the optical subscriber line terminating means and the service multiplexing / demultiplexing means are connected by an optical waveguide; one or more cores are provided between the service multiplexing / demultiplexing means and the wavelength router; And an optical access network configured by connecting the optical network terminating means and the wavelength router with one or more optical fibers, wherein a plurality of wavelength ranges that can be transmitted by the optical fibers are provided. Divided into wavelength bands and assigned to each of the optical network unit terminating means, a wavelength is assigned to each of the optical network terminating means in each wavelength band, and light between the optical network terminating means and the wavelength router is In the fiber, service multiplexing for assigning different wavelength bands to a plurality of channels handled by the optical network termination means is performed. In the optical fiber between the service demultiplexing means and the wavelength router, for each service, Optical access networks, characterized in that it comprises a service multiplexer for assigning a long strip, the simultaneous control means for user multiplexing to assign a different wavelength for each of the optical network unit in the same wavelength range. 4. In a section of a two-core optical fiber, an optical signal from said optical network unit terminating means to said optical network terminating means;
An optical signal from the optical network terminating means to the optical subscriber line terminating means passes through different optical fiber cores.
The optical access network according to claim 3. 5. In a single-fiber optical fiber section, an optical signal from the optical network unit terminating unit to the optical network unit terminating unit and an optical signal from the optical network unit terminating unit to the optical network unit terminating unit are transmitted. The optical access network according to any one of claims 1 to 3, wherein the optical access network is assigned to another wavelength or wavelength band. 6. An optical signal from the optical network unit terminating unit to the optical network unit terminating unit and an optical signal from the optical network unit terminating unit to the optical network unit terminating unit are the same in one optical fiber. 4. The subscriber line terminating means or the service demultiplexing means and the optical network terminating means having means for allocating a wavelength and separating an optical signal for each propagation direction. Optical access network. 7. The same optical signal from the optical network unit terminating unit to the optical network unit terminating unit and the same optical signal from the optical network unit terminating unit to the optical network unit terminating unit in a single-core optical fiber. The optical access network according to any one of claims 1 to 3, wherein a wavelength is allocated, and an upstream signal and a downstream signal are multiplexed in a time-division manner and transmitted. 8. Each corresponding to an optical network termination device,
N optical transmitters for transmitting optical signals of different wavelengths, n optical receivers respectively corresponding to the respective optical network terminators and receiving optical signals of different wavelengths, Connected to an optical subscriber transmission line made of fiber,
An optical signal from each optical transmitter, after multiplexing, output to an optical fiber for downstream transmission, a user demultiplexing element for demultiplexing the optical signal from the optical fiber for upstream transmission to each optical receiver, An interface converter connected to each optical transmitter and each optical receiver, assembling and disassembling a frame used in an optical subscriber transmission line, and providing an appropriate network node interface for a higher-level network; An optical network unit comprising: 9. An optical network unit, which corresponds to each optical network unit, transmits m optical transmitters for transmitting optical signals having different wavelengths, and each optical network unit, M optical receivers for receiving optical signals of different wavelengths from each other, and an optical subscriber transmission line composed of two optical fibers,
A service multiplexing / demultiplexing element for demultiplexing a signal from a downstream transmission optical fiber, inputting the signal to each optical receiver, multiplexing the output of each optical transmitter, and outputting the multiplexed output to an upstream transmission optical fiber; It is composed of an interface conversion circuit corresponding to the optical subscriber line transmission system, and an optical transmitter and an optical receiver corresponding to the interface conversion circuit are connected to each of the interface conversion circuits to assemble and use a frame used in the optical subscriber transmission line. An optical network termination device, comprising: an interface conversion unit that performs decomposition. 10. An n number of optical transmitters each corresponding to an optical network termination device and transmitting optical signals of different wavelengths, and an optical signal of a different wavelength corresponding to each optical network termination device. N optical receivers for receiving signals, connected to an optical subscriber transmission line comprising a single optical fiber,
After multiplexing the optical signals from the respective optical transmitters, the multiplexed optical signals are output to the optical subscriber transmission line as downstream optical signals, and the upstream optical signal of the optical subscriber transmission line is demultiplexed to each optical receiver. A bidirectional demultiplexing element is connected to each optical transmitter and each optical receiver, and assembles and disassembles a frame used in the optical subscriber transmission line. And an interface converter for providing a node interface. 11. M optical transmitters respectively transmitting optical signals having different wavelengths, each corresponding to each optical network unit, and respectively corresponding to each optical network unit, M optical receivers for receiving optical signals of different wavelengths from each other, and an optical subscriber transmission line composed of a single optical fiber,
A service / bi-directional demultiplexing element for demultiplexing a downstream optical signal and inputting it to each optical receiver, multiplexing the output of each optical transmitter and outputting it as an upstream optical signal to the optical subscriber transmission line; It is composed of interface conversion circuits corresponding to m kinds of optical subscriber line transmission systems, and each of the interface conversion circuits is connected to an optical transmitter and an optical receiver corresponding thereto, and is used in the optical subscriber transmission line. An optical network termination device, comprising: an interface converter for assembling and disassembling a frame.