JP2007259229A - Optical transmission network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical transmission network which has a high-reliability voice and data information transmission system and needs inexpensive equipment. <P>SOLUTION: An intra-office system includes an intra-office wavelength multiplexer which performs wavelength multiple separation with voice information optical signals as a redundant configuration composed of a first and second data optical transmission systems. A subscriber reception system includes a subscriber wavelength multiplexer which performs wavelength multiple separation of the data optical signals as a redundant configuration corresponding to the first and second data transmission systems with the voice information optical signals. The intra-office wavelength multiplexer has an intra-office switching discrimination part which discriminates switching between the first and second voice transmission systems and an intra-office switching control part which selects either of the first and second data transmission systems according to the switching of the voice transmission systems. The subscriber wavelength multiplexer has a subscriber switching discrimination part which discriminates switching between the first and second voice transmission systems and a subscriber switching control part which selects either of the first and second data transmission systems according to the switching of the voice transmission systems. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical transmission network, and more particularly to an optical transmission network comprising an in-station subscriber accommodation device and a remote subscriber accommodation device connected by a wavelength division multiplexing transmission line.

  In recent years, with the development of the subscriber optical access network due to the spread of the Internet, the development of a high-speed digital transmission network, an in-station subscriber accommodation device and a remote subscriber accommodation device for connecting a subscriber to the transmission network, etc. (For example, refer to Patent Document 1).

  FIG. 1 schematically shows an example of a conventional intra-station device, a remote subscriber accommodation device, and a network configuration between the subscriber accommodation device and the intra-station device.

  A station such as a communication carrier is provided with a station device for accommodating a subscriber line. In the conventional network shown in FIG. 1, an in-station subscriber accommodation apparatus 110 for accommodating a digital subscriber line (DSL) is a telephone exchange (PBX) connected to a voice information network such as a public telephone line network 11 or the like. The exchange 14 is provided.

  The in-station subscriber accommodation device (hereinafter simply referred to as in-station accommodation device) 110 has redundant interfaces, that is, high-way interfaces of the 0 system and the 1 system (hereinafter referred to as HW interfaces). That is, the exchange 14 is connected with an HW interface (0 system) 15 and an HW interface (1 system) 16. When one of the HW interface (0 system) 15 and the HW interface (1 system) 16 is used (when it is an operation system or an act system), the other is in a standby state (that is, a standby system or a standby system). When a failure or the like occurs, it is switched to a normal transmission system for operation.

  Further, the in-station accommodation device 110 is provided with an in-station router 17 connected to an IP (Internet Protocol) network 12 to provide data system information service via the IP network 12.

  On the other hand, the in-station accommodation device 110 is bidirectionally connected to a remote subscriber accommodation device 115 provided outside the office by a 0-system and 1-system audio optical transmission line (optical fiber) and a data-system optical transmission line (optical fiber). It is connected. The remote subscriber accommodation device 115 accommodates the subscriber terminal device 19 which is one or a plurality of users. The in-station accommodation device 110 provides the DSL service to the subscriber (subscriber terminal device 19) accommodated in the remote subscriber accommodation device 115 outside the office.

  More specifically, the remote subscriber accommodation device 115 includes a demultiplexing unit (0 system) 120 and a demultiplexing unit (1 system) 121. The demultiplexing unit (system 0) 120 and the HW interface (system 0) 15 of the in-station accommodation apparatus 110 are two of the downlink audio system optical transmission path (system 0) 111A and the upstream audio system optical transmission path (system 0) 111B. They are connected by optical fibers. Similarly, the demultiplexing unit (system 1) 121 and the HW interface (system 1) 16 are composed of two lines, a downstream audio system optical transmission path (system 1) 112A and an upstream audio system optical transmission path (system 1) 112B. Connected with optical fiber.

  The remote subscriber accommodation device 115 is provided with a DSL processing unit 125. The DSL processing unit 125 and the intra-station router 17 are connected by two optical fibers, a downstream data optical transmission path 113A and an upstream data optical transmission path 113B.

  Note that uplink and downlink transmission paths, transmission systems, and the like will be described with reference signs A and B respectively.

  That is, between the intra-station accommodation apparatus 110 and the remote subscriber accommodation apparatus 115, four transmission lines in the uplink and downlink directions for the redundant audio system optical transmission lines (system 0 and system 1), and the data system Regarding the optical transmission line, there are two transmission lines in the uplink direction and the downlink direction, and a total of six transmission lines is provided.

  The remote subscriber accommodation device 115 is provided with a subscriber circuit unit 122. The subscriber circuit unit 122 transmits and receives voice system information via the splitter unit 126 between the demultiplexing unit (0 system) 120 and the demultiplexing unit (1 system) 121 and the subscriber terminal device 19. The splitter unit 126 separates or combines the audio system information and the data system information.

  Further, the DSL processing unit 125 of the remote subscriber accommodation device 115 transmits / receives data system information between the intra-station router 17 and the subscriber terminal device 19 via the splitter unit 126. The DSL processing unit 125 performs predetermined processing such as header processing and speed conversion necessary for transferring data system information.

  The subscriber terminal device 19 is connected to the splitter unit 126 of the remote subscriber accommodation device 115 by a line such as a metallic cable. The subscriber terminal device 19 has a splitter 191 and separates the voice system information and the data system information transmitted from the splitter unit 126 of the remote subscriber accommodation device 115 superimposed on the line. Voice system information such as telephone and facsimile (FAX) is processed by the voice terminal unit 192, and data system information is sent to the information terminal unit 194 such as a personal computer (PC) via the DSL modem 193 and processed. The reverse process is performed on the upstream signal from the subscriber terminal device 19 to the remote subscriber accommodation device 115.

However, in such a conventional network, since the data information transmission system between the intra-station device and the subscriber accommodation device is single, a communication failure occurs when a failure occurs in the interface of the data information transmission system, There was a problem that the reliability of the network was low. In addition, the voice information transmission system requires 4 routes (2 × 2 = 4) of optical fibers for the uplink / downlink and redundant configuration, and further 2 routes (2) in the uplink / downlink as the data information transmission system. In total, 6 routes are required and the equipment cost is high.
JP 2000-224625 A (3rd page, FIG. 1)

  The present invention has been made in view of the above-described points, and an object of the present invention is to provide an optical transmission network having a highly reliable voice information and data information transmission system and having a low equipment cost.

The optical transmission network of the present invention includes a redundant configuration of an in-station audio signal transmission circuit and a data optical signal that are connected to an audio communication network and a data transmission network, and are composed of first and second audio transmission systems that transmit and receive audio information optical signals. An intra-station device including an intra-station data signal transmission circuit that performs transmission / reception, and a subscriber voice signal transmission circuit that transmits / receives an audio information optical signal to / from the intra-station device connected to a plurality of subscriber devices An optical transmission network having a subscriber accommodation device to perform,
The intra-station device includes an intra-station wavelength multiplexing device that performs wavelength multiplexing and separation on the audio information optical signal as a redundant configuration of the data optical signal from the first and second data transmission systems, and the subscriber accommodation device transmits the data optical signal to the data optical signal described above. Including a subscriber wavelength multiplexing apparatus for performing wavelength multiplexing and demultiplexing with the audio information optical signal as a redundant configuration corresponding to the first and second data transmission systems,
The intra-station wavelength multiplexing apparatus selects either the intra-station switching determination unit that determines whether the first and second audio transmission systems are switched, or the first and second data transmission systems based on the switching of the audio transmission systems. An in-station switching control unit,
The subscriber wavelength multiplex device includes a subscriber switching discriminating unit that discriminates switching between the first and second voice transmission systems, and one of the first and second data transmission systems based on the switching of the voice transmission systems. And a subscriber switching control unit to be selected.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings described below, substantially the same or equivalent components and parts are denoted by the same reference numerals.

  FIG. 2 is a block diagram schematically showing the configuration of the communication network 5 that is Embodiment 1 of the present invention. That is, it schematically shows an intra-station device, a remote subscriber accommodation device, and a network configuration between the subscriber accommodation device and the intra-station device in the communication network 5.

  In the communication network 5, a station subscriber accommodation device 10 that accommodates a subscriber line is provided in a station such as a communication carrier. The in-office subscriber accommodation device (hereinafter simply referred to as the in-office accommodation device) 10 has an exchange 14 such as a telephone exchange (PBX) connected to a voice information network such as a public telephone network 11.

[Configuration of in-station accommodation device]
The intra-station accommodation apparatus 10 uses a redundant interface for a voice information transmission system connected to the public telephone network 11 or the like. That is, it has 0-system and 1-system highway interfaces (hereinafter referred to as HW interfaces). That is, the exchange 14 is connected with an HW interface (0 system) 15 and an HW interface (1 system) 16. The HW interface (0 system) 15 and the HW interface (1 system) 16 function as an in-station audio signal transmission circuit. When one of the HW interface (0 system) 15 and the HW interface (1 system) 16 is used (when it is an operation system or an act system), the other is in a standby state (that is, a standby system or a standby system). When a failure occurs in one transmission system, it is switched to a normal transmission system and operated.

  Further, the in-station accommodating device 10 is provided with an in-station router 17 connected to the IP network 12. The intra-station router 17 performs routing and data transfer on data system signals transmitted and received between the IP network 12 and the remote subscriber accommodation device 20 based on the destination information of the IP packet. That is, the intra-station router 17 functions as an intra-station data signal transmission circuit.

  Further, the in-station accommodating apparatus 10 is provided with an in-station WDM (wavelength multiplexing / demultiplexing) apparatus 30. The in-station WDM device 30 has a redundant configuration corresponding to the HW interface (0 system) 15 and the HW interface (1 system) 16, and includes an in-station wavelength demultiplexing unit (0 system) 31 and an in-station wavelength demultiplexing unit, respectively. (System 1) 32 is provided. (In the following, in-station wavelength multiplexing / demultiplexing units (system 0, system 1) 31, 32 may be simply abbreviated as wavelength multiplexing / demultiplexing units 31, 32). Are transmitted / received between the HW interface (0 system) 15 and the wavelength demultiplexing unit (0 system) 31, and the 1-system audio system optical signal is transmitted between the HW interface (1 system) 16 and the wavelength demultiplexing unit (1 system) 32. Sent and received.

  Further, the downstream optical signal, which is a data system signal from the intra-station router 17, is distributed by the coupler 33 and supplied to the wavelength demultiplexing unit (0 system) 31 and the wavelength demultiplexing unit (1 system) 32. Uplink optical signals that are data system signals from the wavelength demultiplexing unit (0 system) 31 and the wavelength demultiplexing unit (1 system) 32 are coupled by a coupler 34 and supplied to the intra-station router 17. That is, it is configured such that the upstream optical signal of the operation system of the 0 system and the 1 system transmission system is transmitted to the intra-station router 17.

  That is, the data-system optical signal between the intra-station router 17 and the remote subscriber accommodation apparatus 20 is also distributed to the wavelength multiplexing / demultiplexing section (0 system) 31 and the wavelength multiplexing / demultiplexing section (1 system) 32 of the intra-station WDM apparatus 30 for wavelength multiplexing. In addition to being separated, a redundant data transmission system is configured.

  More specifically, the intra-station WDM device 30 includes an optical separation / coupling unit, a wavelength conversion unit, and the like, which will be described later.

[Configuration of remote subscriber accommodation device]
As shown in FIG. 2, the remote subscriber accommodation device 20 is provided with a subscriber WDM device 50 corresponding to the intra-station WDM device 30. The subscriber WDM apparatus 50 includes a subscriber wavelength demultiplexing unit (system 0) 51 and a subscriber wavelength demultiplexing unit (system 1) 52, and an intra-station wavelength demultiplexing unit (system 0) 31 and an intra-station wavelength demultiplexing unit, respectively. The unit (1 system) 32, the 0 system WDM optical transmission line 18 (0) (one optical fiber) and the 1 system WDM optical transmission line 18 (1) (one optical fiber) are connected. (In the following, the subscriber wavelength demultiplexing units (system 0, system 1) 51, 52 may be simply abbreviated as wavelength demultiplexing units 51, 52.)
Also in the remote subscriber accommodation device 20, the data-type optical signal to / from the intra-station router 17 is also distributed to the subscriber wavelength demultiplexing unit (0 system) 51 and the subscriber wavelength demultiplexing unit (1 system) 52 for wavelength. A demultiplexed and redundant data transmission system is configured.

  First, a case where the 0-system transmission system is used as an operational system will be described. The downstream wavelength division multiplexed signal transmitted from the intra-station wavelength demultiplexing unit (system 0) 31 via the system 0 WDM optical transmission line 18 (0) is wavelength-separated (DEMUX) in the subscriber wavelength demultiplexing unit (system 0) 51. Then, the downlink voice optical signal is supplied to the subscriber demultiplexing processing unit 21. In the subscriber demultiplexing processing unit 21, subscriber demultiplexing processing is performed, for example, by time division demultiplexing processing, and is separated into voice information signals for each subscriber.

  The voice system signal is supplied to the subscriber circuit unit 22. The subscriber circuit unit 22 processes the analog voice transmission signal for the subscriber and supplies it to the splitter 26.

  On the other hand, the downlink data system optical signal wavelength-separated (DEMUX) in the subscriber wavelength demultiplexing unit (system 0) 51 is supplied to the DSL processing unit 25, and after optical-electrical conversion, the data signal for the subscriber is obtained by DSL processing. And supplied to the splitter 26. The signal is superimposed on the audio transmission signal in the splitter 26 and transmitted to the subscriber terminal device 19.

  On the other hand, when a failure or the like occurs in the 0-system transmission system and the 1-system transmission system is used as an operation system, that is, from the intra-station wavelength demultiplexing unit (1 system) 32 via the 1-system WDM optical transmission line 18 (1). The downstream wavelength multiplexed signal transmitted in this way is also wavelength-separated by the subscriber wavelength demultiplexing unit (system 1) 52, and the audio system signal is transmitted by the subscriber demultiplexing processing unit 21 and the subscriber circuit unit 22 by the DSL processing unit 25. The point that the data system signal is processed is the same.

  The downlink data system optical signals from the subscriber wavelength demultiplexing unit (system 0) 51 and the subscriber wavelength demultiplexing unit (system 1) 52 are supplied to the coupler 53 and transmitted to the DSL processing unit 25. In other words, the optical signal of the operation system out of the 0 system and the 1 system transmission system is transmitted to the DSL processing unit 25. The upstream data system optical signal from the DSL processing unit 25 is distributed by the coupler 54 and supplied to both the subscriber wavelength demultiplexing unit (0 system) 51 and the subscriber wavelength demultiplexing unit (1 system) 52. That is, the data optical signal between the remote subscriber accommodation device 20 and the intra-office router 17 is also distributed to the wavelength multiplexing / demultiplexing unit (0 system) 51 and the wavelength multiplexing / demultiplexing unit (1 system) 52 of the intra-office WDM device 30 for wavelength multiplexing. Separately and redundantly configured data transmission systems are configured.

  As described above, the subscriber terminal device 19 separates the voice system information and the data system information transmitted via a line such as a metallic cable by the splitter 191, and the voice system information and the data system information are respectively stored in the voice terminal unit 192. And sent to the information terminal unit 194 for processing.

  With respect to the upstream voice system information and data system information signal from the subscriber terminal device 19 to the remote subscriber accommodation device 20, the reverse processing described above is performed.

[Configuration of in-station WDM equipment]
Next, the intra-station WDM device 30 will be described in detail with reference to the drawings. Referring to FIG. 3, the intra-station WDM device 30 is provided with a system switching determination unit 35 and a system switching control unit 36.

  As described above, the intra-station WDM device 30 is provided with the wavelength demultiplexing units (0 system, 1 system) 31, 32 and couplers 33, 34. In more detail, the wavelength demultiplexing units (system 0, system 1) 31 and 32 perform the wavelength demultiplexing (MUX, DEMUX) so as to perform the light demultiplexing / coupling unit, electro-optical conversion unit, wavelength conversion. Part. Although these can take various configurations, examples of such configurations will be described later.

  As shown in FIG. 3, the in-station WDM device 30 includes a transmission system (operating system) operated in the audio information transmission systems (0 system and 1 system) of the wavelength demultiplexing units (systems 0 and 1) 31 and 32. ) Is provided. The system switching determination unit 35 determines that the transmission system has been switched by determining the transmission system selected as the active system. That is, the system switching determination unit 35 determines that the operating system for audio system information transmission has been switched from the 0 system to the 1 system or from the 1 system to the 0 system.

  Note that the system switching discriminating unit 35 does not have a transmission system selected as the active system when both transmission systems of the 0-system and the 1-system audio information transmission system are not operated due to a failure or the like. It is configured to output a determination signal indicating that both transmission systems of the transmission system cannot be operated.

  Further, the intra-station WDM device 30 is provided with a system switching control unit 36. The system switching control unit 36 performs switching control of redundantly configured data information transmission systems (system 0 and system 1) based on the determination result by the system switching determination unit 35.

  With reference to FIG. 4, the configuration and operation of the intra-station WDM device 30 will be described in detail below. As described above, the wavelength demultiplexing units (system 0, system 1) 31 and 32 have an optical demultiplexing / coupling unit, an electro-optical conversion unit, a wavelength conversion unit, etc. that can be realized by various configurations. ing. Therefore, the intra-station WDM device 30 can take various configurations, but FIG. 4 shows an example of the configuration of the intra-station WDM device 30.

  The 0-system transmission system will be described. The HW interface (0-system) 15 transmits and receives an optical signal having a wavelength λP to and from the 0-system wavelength converter 42 (0). That is, the downstream audio system information optical signal (wavelength λ P) from the HW interface (0 system) 15 is converted into an electrical signal by the optical-electrical converter OE (11), and further, the optical-electrical converter OE (12 ) Is converted into an optical signal of wavelength λ1 and supplied to the 0-system beam splitter 43 (0).

  Further, the upstream audio system information optical signal (wavelength λ2) from the 0-system beam splitter 43 (0) is converted into an electrical signal by the optical-electrical converter OE (12), and further, the optical-electrical converter OE ( 11) is converted into an optical signal (wavelength λp) and supplied to the HW interface (system 0) 15.

  As described above, the optical-electrical converter (OE (11), (12), etc.) is an optical-electrical converter that mutually converts an optical signal into an electrical signal and an electrical signal into an optical signal ( Hereinafter, they are simply referred to as OE (11) and OE (12)).

  The same applies to the 1-system transmission system. That is, the HW interface (1 system) 16 transmits and receives an optical signal having the wavelength λ P to and from the 1 system wavelength conversion unit 42 (1). That is, the downstream audio system information optical signal (wavelength λp) from the HW interface (system 1) 16 is converted into an optical signal of wavelength λ1 by the OE (31) and OE (32) of the system 1 wavelength converter 42 (1). 1 system beam splitter 43 (1). On the other hand, the upstream audio system information optical signal (wavelength λ 2) from the system 1 beam splitter 43 (1) is converted into an optical signal (wavelength λ P) by the OE (32) and OE (31) and is converted into the HW interface (system 1) 16. To be supplied.

  The downstream data system information optical signal (wavelength λ P) from the intra-station router 17 is branched into two by the coupler 33, one of which is provided by the OE (21) and OE (22) provided in the 0 system wavelength converter 42 (0). The wavelength is converted into an optical signal of wavelength λ3 and supplied to the 0-system beam splitter 43 (0). The other downstream optical signal (wavelength λ P) branched into two by the coupler 33 is wavelength-converted into an optical signal of wavelength λ 3 by OE (41) and OE (42) provided in the 1-system wavelength converter 42 (1), It is supplied to the 1-system beam splitter 43 (1).

  Further, the upstream data system information optical signal (wavelength λ 4) from the 0 system beam splitter 43 (0) is transmitted by the OE (22) and OE (21) of the 0 system wavelength converter 42 (0). ) And is supplied to the coupler 34. Similarly, the upstream data-system information optical signal (wavelength λ4) from the 1-system beam splitter 43 (1) is also transmitted by the OE (42) and OE (41) of the 1-system wavelength converter 42 (1). Wavelength conversion to wavelength λP). The optical signals (wavelength λ P) from the 0-system wavelength converter 42 (0) and 1-system wavelength converter 42 (1) are combined by the coupler 34 and supplied to the intra-station router 17. As described above, the couplers 33 and 34 have a function of branching and multiplexing optical signals.

  Here, various wavelengths can be appropriately selected for the above-described optical signals. In general, wavelengths in the vicinity of the 1.5 μm band are used for long-distance, wavelength division multiplexing (Dense WDM) applications. For example, wavelengths λP = 1310 nm, λ1 = 1470 nm, λ2 = 1550 nm, λ3 = 1490 nm, λ4 = 1570 nm Etc. can be selected.

  In other words, the couplers 33 and 34, the 0-system wavelength converter 42 (0) and the 0-system beam splitter 43 (0), and the 1-system wavelength converter 42 ( It is duplicated (redundant configuration) by 1) and 1-system beam splitter 43 (1). Further, the system composed of the 0-system wavelength converter 42 (0) and the 0-system beam splitter 43 (0) is added to the 0-system wavelength demultiplexing section 31 described above, the 1-system wavelength converter 42 (1), and the 1-system beam splitter 43. The system consisting of (1) corresponds to the aforementioned 1-system wavelength demultiplexing unit 32 (FIG. 2).

The 0-system beam splitter 43 (0) combines the output optical signal (downstream optical signal) from the 0-system wavelength converter 42 (0) and sends it to the 0-system WDM optical transmission line 18 (0). The output optical signal from the wavelength converter 42 (1) is combined and sent to the 1-system WDM optical transmission line 18 (1). Complementarily, the 0-system beam splitter 43 (0) and the 1-system beam splitter 43 (1) are connected to the 0-system WDM optical transmission line 18 (0) and the 1-system WDM optical transmission line 18 (1). Are divided and supplied to the 0-system wavelength converter 42 (0) and the 1-system wavelength converter 42 (1), respectively.

[System switching discrimination and system switching control in in-station WDM equipment]
As shown in FIG. 4, the intra-station WDM device 30 is provided with a system switching determination unit 35 and a system switching control unit 36. The system switching discriminating unit 35 monitors the 0-system and / or 1-system audio system information signals and discriminates that the transmission system has been switched by discriminating the audio system information transmission system selected as the active system. .

  The system switching discriminating unit 35 is connected to an electrical interface in the 0-system and 1-system wavelength converters 42 (0), 42 (1), for example, and has a function as an optical terminal unit. Then, the system switching determining unit 35 monitors the output signals of OE (21) and OE (31), which are upstream audio system electrical signals, for example, and determines switching between the selected transmission system and transmission system. In addition, you may comprise not only the electrical signal after conversion but discriminate | determining by directly monitoring an optical signal. Further, the determination may be made by monitoring either the upstream or downstream audio system signal.

  For example, when the audio system electrical signal is an STM-n signal of the SDH (Synchronous Digital Hierarchy) system, the system switching determination unit 35 is mapped to the section management information (section overhead: SOH), and the terminal station K1 and K2 bytes (b1-b5) having section switching information (TTC standard G.707) are monitored.

  Note that the above-described system switching determination method is merely an example. That is, not only the SDH method but also various other transmission methods can use system switching information (signal) or a signal corresponding thereto. Alternatively, although it is not directly used as the system switching information, it is natural that the system switching can be determined by detecting information (signal) that changes accompanying the system switching.

  In addition to this, it is also possible to determine system switching based on the presence or absence of a signal. That is, an electrical signal or an optical signal in the 0-system and / or 1-system transmission system is monitored, and the transmission system (operating system) used (selected) is determined by the presence or absence (or signal strength) of the signal. However, when the signal (or signal strength) changes, it may be determined that the transmission system has been switched.

  The system switching determination unit 35 sends a system switching signal indicating that the transmission system (active system) has been switched to the system switching control unit 36. The system switching control unit 36 performs control to switch the transmission system of the data system information based on the system switching signal supplied from the system switching determination unit 35.

  The system switching control unit 36 controls, for example, the opto-electric converters on the data system transmission system of the 0-system and 1-system wavelength converters 42 (0), 42 (1), and the 0-system and 1-system optical-systems. One of the electrical converters is controlled to stop one and operate the other. When the active system 0 system fails and the system switching determination unit 35 issues a system switching signal, for example, the system switching control unit 36 goes to the OE (21) and / or OE (22) of the 0 system transmission system. Stop the clock supply (or stop the clock), supply the clock to the OE (41) and / or OE (42) of the 1 system transmission system (or operate the clock), and operate the 0 system transmission system From this state, system switching is performed using the 1-system transmission system that was the standby system as the active system.

  Instead of clock control, the electrical interface data between OE (21) and OE (22) or the electrical interface data between OE (41) and OE (42) is masked (all "0", "1" It is also possible to selectively switch between the 0 system and the 1 system for the data transmission system. Further, the OE (21), the OE (22), the OE (41), and the OE (42) can be controlled to have functions equivalent to these. Furthermore, an optical switch or the like can be inserted into the optical transmission line (fiber), and optical transmission switching can be optically controlled based on the system switching information. For example, it is possible to configure the couplers 33 and 34 as switch-coupled couplers and selectively switch between the 0-system and 1-system data transmission systems based on the system switching signal from the system switching discriminating unit 35.

  Further, the intra-station WDM device 30 may be provided with an optical module monitoring unit 37. The optical module monitoring unit 37 performs optical input interruption (LOS) and optical module (optical-electrical converter, etc.) in the in-station WDM device 30 such as the 0-system and 1-system wavelength converters 42 (0), 42 (1). Optical signal abnormality such as optical output abnormality (laser element (LD) drive current abnormality, etc.) (LOF) is detected. When the optical signal abnormality is detected, the optical module monitoring unit 37 supplies the abnormality detection signal to the system switching control unit 36.

  An operation using the abnormality detection signal by the optical module monitoring unit 37 will be described below. In FIG. 4, a case where a duplicate failure (failure) occurs when the 1-system transmission system is the standby system and the 0-system transmission system is used as the active system will be described.

  As shown in FIG. 5, when the HW interface (system 0) 15 is the active system and the HW interface (system 1) 16 is the standby system, the system 0 transmission system (wavelength converter 42 (0 ), The beam splitter 43 (0)) and the WDM optical transmission line 18 (0) are the operation system, the first transmission system (the wavelength converting unit 42 (1), the beam splitter 43 (1)) and the WDM optical transmission line 18 (1). ) Becomes the standby system.

  At this time, if the standby system HW interface (system 1) 16 fails and a failure occurs in the active system 0 transmission system (when there is a duplicate failure), the system switching discriminating unit 35, as described above, Both the 0-system and 1-system audio transmission systems related to the audio system signals are determined to be faulty, and the service is stopped.

  However, in this embodiment, the optical module monitoring unit 37 determines whether or not the OE of the operation system and the standby system (system 0 and system 1) of the data system signal in the intra-station WDM device 30 is normal (whether there is a failure or not). ) Is detected. For example, the optical module monitoring unit 37 monitors the abnormalities of the OE (41) and OE (42), which are standby systems for data signals in the intra-station WDM device 30, and supplies an abnormality detection signal to the system switching control unit 36. . When the optical module monitoring unit 37 detects no abnormality (normal) and no abnormality detection signal is supplied, the system switching control unit 36 supplies a clock to the OE (41) and the OE (42) (or 1st transmission system which was a standby system is used as an operation system. On the other hand, the clock supply to the OE (21) and OE (22) of the 0-system transmission system that was the active system is stopped, and the 0-system transmission system is stopped.

  That is, when both the 0-system and the 1-system audio transmission systems are in failure, the system switching control unit 36 does not depend on the determination signal of the system switching determination unit 35 (a signal indicating a failure in both audio transmission systems), but the optical module monitoring unit At 37, the data transmission system is determined to be normal (no failure detected).

  With this operation, even when a failure (duplication failure) occurs in both the HW interface (transceiver) and the transmission system in the voice transmission system, it is normal without depending on the system state of the voice transmission path. Data system signals can be transmitted by selecting a transmission path (transmission system).

[Configuration of subscriber WDM apparatus, system switching discrimination and system switching control]
As shown in FIG. 6, the subscriber WDM device 50 corresponding to the intra-station WDM device 30 also has the same configuration as the intra-station WDM device 30.

  The subscriber WDM device 50 has the same configuration as the intra-station WDM device 30 and operates in a complementary manner. That is, the downstream wavelength multiplexed signal transmitted through the 0-system WDM optical transmission line 18 (0) or the 1-system WDM optical transmission line 18 (1) is transmitted by the beam splitter 63 (0) or the beam splitter 63 (1), respectively. Wavelength separation is performed, and wavelength conversion is performed by the wavelength conversion unit 62 (0) or the wavelength conversion unit 62 (1). More specifically, in the 0-system wavelength conversion unit 62 (0) or 1-system wavelength conversion unit 62 (1), the optical signal having the wavelengths λ1 and λ3 is converted into the optical signal having the wavelength λQ in the downstream direction, and the wavelength λ2 in the upstream direction. The optical signal of λ4 is converted into an optical signal of wavelength λQ. However, the present invention is not limited to these, and various wavelengths can be selected as appropriate. For example, λQ may be the same wavelength as the above-mentioned λP or the wavelength of the same band (1.3 μm or 1.5 μm band).

  Further, the subscriber WDM device 50 is provided with a system switching determination unit 55, a system switching control unit 56, and an optical module monitoring unit 57. These functions and operations are the same as those of the system switching determination unit 35, the system switching control unit 36, and the optical module monitoring unit 37 in the intra-station WDM device 30, respectively.

  For the transmission system of downlink and uplink data system information with the intra-station router 17, couplers 53, 54, 0-system beam splitter 63 (0), 0-system wavelength converter 62 (0), 1-system beam splitter 63 (1), and Duplexing (redundant configuration) is performed by the 1-system wavelength converter 62 (1). Here, the 0-system beam splitter 63 (0) and the 0-system wavelength converter 62 (0) are added to the above-described 0-system wavelength demultiplexing section 51, the 1-system beam splitter 63 (1) and the 1-system wavelength converter 62 (1). ) Corresponds to the 1-system wavelength demultiplexing unit 52 (FIG. 2).

  FIG. 7 is a block diagram schematically showing the configuration of the remote subscriber accommodation apparatus 20 according to the second embodiment of the present invention.

  In the present embodiment, the remote subscriber accommodation device 20 is provided with a subscriber demultiplexing processing unit 21, a subscriber circuit unit 22, a DSL processing unit 25, a splitter 26, and a subscriber WDM device 50. Similar to the example.

  In addition, the subscriber WDM device 50 switches the transmission system (operating system) used in the voice information transmission systems (0 system and 1 system) of the wavelength demultiplexing units (system 0 and system 1) 51 and 52. A system switching discriminating unit 55 is provided for discriminating the fact. The subscriber WDM device 50 is provided with a system switching control unit 56 that controls switching of redundantly configured data signal transmission systems (system 0 and system 1) based on the determination result by the system switching determination unit 55. In addition, the optical module monitoring unit 57 that supplies an optical signal abnormality detection signal to the system switching control unit 36 for an optical-electrical converter or the like is also provided in the same manner as in the above-described embodiment.

  However, in this embodiment, unlike the embodiment described above, the system switch discriminating unit 55 has switched the operating transmission system (active system) based on the signal from the subscriber demultiplexing processing unit 21. Is configured to determine.

  However, in the present embodiment, unlike the above-described embodiment, the system switching determining unit 55 determines an operating transmission system (operating system) based on a signal from the subscriber demultiplexing processing unit 21. In other words, the switching in the voice transmission system is determined by monitoring the signal in the subscriber demultiplexing processing unit 21 that transmits and receives signals to and from the subscriber wavelength multiplexing apparatus.

  More specifically, it is determined that the transmission system has been switched based on the downlink audio optical signal supplied to the subscriber demultiplexing processing unit 21. For example, after converting the audio system optical signal into an electric signal, it can be determined by header information such as section management information (section overhead) attached to the audio signal.

  Alternatively, as described above, system switching can be determined by detecting system switching information (signals) in various transmission systems, signals corresponding thereto, or information (signals) that change accompanying system switching. it can. In addition to this, the system switching is performed simply by monitoring the presence or absence of a signal, that is, the signal in the 0-system and / or 1-system transmission system, and the transmission system used depending on the presence or absence (or signal strength) of the signal. It is also possible to determine that the transmission system has been switched when the signal (or signal strength) changes.

  As described above in detail, it is possible to provide an optical transmission network that can transmit voice information and data information with high reliability and at a low equipment cost.

  In the above-described embodiment, the up direction and the down direction are provided for convenience, and any of them may be the up direction or the down direction.

  The above-described embodiments are merely examples. In addition, the above-described embodiments can be applied with appropriate modifications and combinations.

It is a figure which shows typically an example of the network structure between the conventional intra-station apparatus, a remote subscriber accommodation apparatus, and the said subscriber accommodation apparatus and an intra-station apparatus. It is a block diagram which shows typically the structure of the communication network which is Example 1 of this invention. It is a block diagram which shows typically the structure of an in-station WDM apparatus. It is a block diagram which shows typically an example of a structure of an in-station WDM apparatus. It is a figure explaining the case where a duplication fault generate | occur | produces when the 1-system transmission system is made into a standby system and the 0-system transmission system is used as an operation system. It is a block diagram which shows typically an example of a structure of a subscriber WDM apparatus. It is a block diagram which shows typically the structure of the remote subscriber accommodation apparatus which is Example 2 of this invention.

Explanation of symbols

10 Station accommodation device 15 HW interface (system 0)
16 HW interface (1 system)
17 Intra-station router 20 Remote subscriber accommodation device 30 In-station WDM device 31 Intra-station wavelength demultiplexing unit (system 0)
32 Intra-station wavelength demultiplexing unit (1 system)
33, 34 Coupler 35 System switching discrimination unit 36 System switching control unit 37 Optical module monitoring unit 50 Subscriber WDM device 51 Subscriber wavelength demultiplexing unit (system 0)
52 Subscriber Wavelength Demultiplexer (System 1)
53, 54 Coupler 55 System switching discrimination unit 56 System switching control unit 57 Optical module monitoring unit

Claims (6)

Redundant intra-office audio signal transmission circuit comprising first and second audio transmission systems connected to an audio communication network and a data transmission network for transmitting / receiving audio information optical signals, and an intra-office data signal transmission circuit for transmitting / receiving data optical signals Including an intra-station device, a subscriber voice signal transmission circuit for transmitting and receiving the voice information optical signal to and from the intra-station device connected to a plurality of subscriber devices, and a subscriber accommodation device for transmitting and receiving the data optical signal An optical transmission network comprising:
The intra-station apparatus includes an intra-station wavelength multiplexing apparatus that performs wavelength multiplexing and separation of the data optical signal and the audio information optical signal as a redundant configuration including first and second data transmission systems, and the subscriber accommodation apparatus includes the data optical signal. A subscriber wavelength multiplexing device that performs wavelength multiplexing and separation with the audio information optical signal as a redundant configuration corresponding to the first and second data transmission systems;
The intra-station wavelength multiplexing apparatus selects either the intra-station switching determination unit that determines switching between the first and second audio transmission systems, or the first and second data transmission systems based on the switching of the audio transmission systems. An intra-station switching control unit that
The subscriber wavelength multiplexing device includes a subscriber switching discriminating unit that discriminates switching between the first and second voice transmission systems, and one of the first and second data transmission systems based on the switching of the voice transmission systems. An optical transmission network comprising: a subscriber switching control unit that selects   The audio information optical signal is a digital synchronization signal, and the intra-station switching determination unit determines switching between the first and second audio transmission systems based on section management information of the digital synchronization signal. 2. An optical transmission network according to 1.   The subscriber wavelength multiplexing apparatus controls a clock signal to the first and second data transmission systems to select one of the first and second data transmission systems. Optical transmission network.   The intra-station wavelength multiplexing device has a fault detection unit that detects a fault in the first and second data transmission systems of the intra-station data signal transmission circuit, and the intra-station switching control unit is independent of a determination result of the intra-station switching determination unit. 2. The optical transmission network according to claim 1, wherein one of the first and second data transmission systems is switched to a data transmission system in which no failure is detected.   The subscriber wavelength multiplexing device has an optical signal abnormality detecting unit for detecting an optical signal abnormality in the first and second data transmission systems of the subscriber data signal transmission circuit, and the subscriber switching control unit is configured to switch the subscriber switching unit. 2. The optical transmission network according to claim 1, wherein the optical transmission network is switched to a data transmission system in which an optical signal abnormality is not detected, of the first and second data transmission systems regardless of a discrimination result of the discrimination unit.   The said subscriber switching control part monitors the signal transmitted / received between the said subscriber wavelength multiplexing apparatuses, and discriminate | determines switching of the said 1st and 2nd audio | voice transmission system. Optical transmission network.

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