JP3981873B2 - Order wire control system, network element and order wire control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an order wire control system and a network element for setting and controlling an order wire line that enables a conference call between network elements in a network in which a plurality of network elements are connected in a ring shape, a mesh shape or the like. The present invention relates to an order wire control method.
[0002]
[Prior art]
A ring network in which a plurality of network elements (hereinafter abbreviated as “NE” (Network Element)) are connected by a ring-shaped transmission line, a network in which a plurality of such networks are connected, or a plurality of NEs in a mesh shape A large-scale network connected to each other by a transmission line is known. For high-speed multiplex transmission, a SONET (Synchronous Optical Network) / SDH (Synchronous Digital Hierarchy) system has been standardized.
[0003]
For example, as shown in FIG. 14A, when a ring network is configured by connecting a plurality of NE1 to NE4 through a double ring transmission line, a maintenance call or the like can be made by each of the NE1 to NE4. The phone to be connected is connected. The above-mentioned standardized SONET / SDH system is applied to this ring network, and the frame format thereof is as shown in FIG. 15 in the case of STM-1 (OC-3) (155 Mbps). That is, the overhead has a 9-column configuration, the payload has a 262-column configuration, the overhead SOH has a section overhead (Section Over Head), the pointer has an H1, H2, H3 byte configuration, and the LOH has a line overhead ( Line Over Head).
[0004]
Overhead A1, A2 are frame synchronization bytes, B1, B2 are error monitoring bytes, D1-D12 are data communication bytes, E1, E2 are order wire bytes, F1 is a network operation byte, J0 is a section trace byte, K1, K2 Indicates an automatic switching byte, and Z1 and Z2 indicate spare bytes. Other than these bytes are empty bytes. An order wire line is formed by using E1 and E2 bytes.
[0005]
In the case of a ring network configuration, the order wire line is also in a ring shape. If the configuration is as it is, howling occurs due to the voice information circulating and returning to the transmission source. Therefore, for example, the master station is NE1 and the other NE2 to NE4 are slave stations. In the master station, one of the EAST side and the WEST side, for example, the order wire line on the WEST side is cut off. That is, E1 and E2 bytes are extracted and terminated. As a result, the order wire line is constituted by the route of NE1-NE4-NE3-NE2 and does not form a loop, so that howling is prevented and communication between NE1-NE4 is possible. That is, a loop protection function for preventing howling is provided.
[0006]
As shown in FIG. 14B, when a line disconnection failure occurs between NE1 and NE2, NE1 of the master station connects an order wire line on the west side based on the failure information. Thereby, even if a line disconnection failure occurs, an order wire line is formed between NE1 and NE4. Also, the order wire line is cut off at the WEST side of NE4. When the failure of the line is recovered, the original state is switched back. In other words, a ring restore function for failure relief is provided.
[0007]
  There is also known a large-scale network in which a plurality of ring network configurations are connected to each other via an NE and high-speed multiplex transmission is performed by applying the SDH / SONET method. There is known a configuration in which an order wire control device is provided in an NE for connecting the ring network, and an order wire line for connecting between ring networks is set by setting to selectively connect a voice information adding means in the order wire control device (for example, , JP2001-127781).
[0008]
[Problems to be solved by the invention]
When a plurality of ring networks are connected via a common NE, one NE of each ring network other than the common NE is used as a master station, thereby preventing howling by the loop protection function and the ring restoration function described above. In addition, it is possible to set an order wire line capable of repairing a failure. However, a network in which a plurality of NEs are connected in a mesh shape, for example, a network in which a plurality of ring networks are connected through a plurality of NEs, as shown in FIG. 16, is known. On the ring network side, it is conceivable that NE1 is used as a master station and the order wire line on the WEST side is cut off, and on the other ring network side, the order wire line on the WEST side of NE5 is cut off.
[0009]
However, there is a problem that the order wire line forms a loop between NE2 and NE3 because a plurality of NE2 and NE3 are connected via a double transmission line. Although it is conceivable to manually set an order wire line so as not to form a loop between NE2 and NE3, it becomes impossible to exhibit an automatic relief function when a failure occurs. In a mesh network, it is conceivable to manually set an order wire line so as not to form a loop. However, there is a problem that automatic remedy when a failure occurs becomes impossible.
[0010]
SUMMARY OF THE INVENTION An object of the present invention is to automatically form an order wire line so that a loop does not occur, and to enable automatic relief when a failure occurs.
[0011]
[Means for Solving the Problems]
The order wire control system according to the present invention will be described with reference to FIG. 1. An order wire control for setting an order wire line in a network in which a plurality of network elements NE1 to NE5 are connected by a transmission line such as a ring or mesh. The network elements NE1 to NE5 include an order wire control device 1 for setting an order wire line. The order wire control device 1 includes an order wire byte and a line connection setting information byte for setting the order wire line. Output means for multiplexing and transmitting the communication means 2a corresponding to the input port to be separated and extracted, the line connection means 6 including the function for selecting and adding the order wire bytes, and the order wire bytes from the line connection means 6 and the line connection setting information bytes. Port-compatible communication means 2b; And a setting control means 4 for processing the connection setting information byte. The setting control means 4 uses the input port of the received line connection setting information byte of the minimum value as the receiving source, and outputs the maximum value from the output port corresponding to this input port. The line connection setting information byte is returned, and the line connection setting information having a value obtained by adding 1 to the receiving line connection setting information byte is sent from the other output port, and the input port of the transmission source and the output port corresponding to this input port And a control function for setting the input port that has received the maximum line connection setting information byte and the output port corresponding to the input port to the port for the order wire line.
[0012]
Also, one of the plurality of network elements NE1 to NE5 is set as a master station, and the setting control means 4 of the order wire control device 1 of this master station has a minimum value, for example, line connection setting information of all “0”. Bytes are transmitted from all output ports, and the maximum value, for example, an input port that has received a line connection setting information byte of all “1” and an output port corresponding to this input port are set as a pair and set as an order wire line port. It has a control function.
[0013]
The network element includes an order wire control device 1 connected to another network element to form an order wire line with the other network element. The order wire control device 1 is an order wire byte. And communication means 2a corresponding to the input port for separating and extracting the line connection setting information byte for setting the order wire line, the line connection means 6 including a function for selectively adding the order wire bytes, and the order wire from the line connection means 6 A communication means 2b corresponding to the output port that multiplexes and transmits the connection byte and the line connection setting information byte, and a setting control means 4 that processes the line connection setting information byte. The input port of the line connection setting information byte of the value is the receiver, and the output corresponding to this input port The line connection setting information byte of the maximum value is returned from the port, and the line connection setting information of the value obtained by adding 1 to the receiving line connection setting information byte is sent from the other output port, and the input port of the transmission source and this input port A control function is provided for setting the corresponding output port, the input port that has received the maximum value of the line connection setting information byte, and the output port corresponding to this input port to the port for the order wire line.
[0014]
The order wire control method of the present invention is an order wire control method for setting an order wire line in a network in which a plurality of network elements NE1 to NE5 are connected by a ring-like or mesh-like transmission line, and includes a network element NE1. The setting control means 4 of the order wire control device 1 to NE5 uses the input port of the minimum value of the line connection setting information byte as the reception source, and returns the maximum value of the line connection setting information byte from the output port corresponding to the input port. In addition, the line connection setting information byte with a value obtained by adding 1 to the reception line connection setting information byte is sent from another output port, and the input port as the transmission source and the output port corresponding to this input port, and the maximum value of the line connection setting The input port that received the information byte and the output port corresponding to this input port Order wire is intended to include the process of setting the port for the line.
[0015]
Also, one of the plurality of network elements NE1 to NE5 is set as a master station, and this master station first sends a minimum value, for example, a line connection setting information byte of all “0” from all output ports. . The maximum value returned by another network element in response to this line connection setting information byte, for example, the input port that has received the line connection setting information byte of all “1” is identified, and this input port and corresponding to this input port This includes a process of setting an output port as a set to a port for an order wire line.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an explanatory diagram of an embodiment of the present invention. A network in which a plurality of network elements, ie, ring networks RN1 and RN2 in which NE1 to NE5 are connected in a ring shape, are connected to each other via NE3 and NE4. 5 indicates a telephone for making a call via an order wire line. Further, NE1 to NE5 have a configuration for transmitting and receiving SONET / SDH frames, and an order wire control device 1, which shows a main part of the order wire control device 1 in NE4. In this order wire control apparatus 1, 2a and 2b are communication means, 3 is a failure detection means, 4 is a setting control means, 5a is a telephone handset, 5b is a telephone handset, and 6 is a line connection means. Lin1 to Linn are lines corresponding to input ports, and Lout1 to Loutn are lines corresponding to output ports.
[0017]
The order wire line is set by transmitting an order wire line setting line connection setting information byte by using empty bytes at preset positions among a plurality of empty bytes in the overhead of the SONET / SDH frame. The telephone call is made by the aforementioned E1 and E2 bytes via the order wire line set according to the line connection setting information byte. Accordingly, the communication means 2a on the input port side in the order wire control device 1 separates and extracts the order wire bytes, that is, the E1 and E2 bytes, and the line connection setting information byte from the overhead of the SONET / SDH frame. The setting information byte is transferred to the setting control means 4, and the E1 and E2 bytes are transferred to the line connection means 6. The line connection means 6 has a function of adding voice information using E1 and E2 bytes. Further, the communication means 2b on the output port side has a function of inserting the E1 and E2 bytes from the line connection means 6 and the line connection setting information byte from the setting control means 4 into a predetermined overhead position and sending it out. Yes.
[0018]
The setting control means 4 processes the line connection setting information byte according to the settings of the master station and the slave station, controls the line connection means 6 according to the processing result, and processes the processed line connection setting information byte. Is transmitted via the communication means 2b. The failure detection means 3 detects line disconnection, failure information, etc., and notifies the communication means 2a and the setting control means 4 of the failure.
[0019]
The communication means 2a and 2b have the main part shown in FIG. 2, 8 is a demultiplexing unit (DMUX), 9 is an invalidity notification unit, and 10 is a multiplexing unit (MUX). The E1 and E2 bytes and the line connection setting information bytes received via the line Lini (i = 1 to n) are separated by the demultiplexing unit 8, and the E1 and E2 bytes are transferred to the line connection means 6 to obtain line connection setting information. The bytes are transferred to the setting control means 4 via the invalidity notification unit 9. When failure detection information from the failure detection means 3 is input to the invalidity notification unit 9, the line connection setting information is transferred to the setting control means 4 as invalid information. The multiplexing unit 10 multiplexes the E1 and E2 bytes from the line connection unit 6 and the line connection setting information byte from the setting control unit 4 at a predetermined overhead position, so that the line Loutj (j = 1 to n). To send.
[0020]
3 is an explanatory diagram of the main part of the setting control means, 11 is a setting unit for setting whether or not it is a master station, 13 is a receiving source selecting unit, 14 is an All “1” transmitting unit, 15 is an adding unit, 16 is A transmission line determination unit is shown. Further, (Lin1) to (Linn) indicate that the lines Lin1 to Linn corresponding to the input ports are connected via the communication means 2a, and (Lout1) to (Loutn) indicate the lines Lout1 to Loutn corresponding to the output ports. And being connected via the communication means 2b.
[0021]
When setting an order wire line, one of the NEs in the network is set as a master station, and the other is set as a slave station. That is, the setting unit 11 is set as to whether or not the master station. When set to the master station, the transmission line determination unit 16 sends a minimum value, for example, a line connection setting information byte of all “0”, to the communication means 2 b corresponding to the output port according to the setting information of the setting unit 11. The communication means 2b uses a predetermined free byte of overhead for the line connection setting information byte, inserts all “0” line connection setting information bytes, and sends them to the lines connected to all output ports of the master station. .
[0022]
When the line connection setting information byte is received, the reception source selection unit 13 sets the input port indicating the minimum value among the plurality of reception line connection setting information bytes as the reception source, and notifies the transmission line determination unit 16 of the input port. To do. Further, the line connection setting information byte of the minimum value is transferred to the adder 15 and 1 is added. For example, if the minimum value of the line connection setting information byte is received via the line Lin2, the adding unit 15 adds 1 to the value of the line connection setting information byte. In this case, the slave station that has received the line connection setting information byte of all “0” from the master station sets the value of this line connection setting information byte to 1 and sends it to the next slave station.
[0023]
The line connection setting of all “1” as the maximum value from the All “1” transmission unit 14 is controlled by the transmission line determination unit 16 from the output port corresponding to the input port which has received the line connection setting information byte of the minimum value. Returns an information byte. Therefore, in FIG. 3, the addition unit 15 adds +1 to the minimum line connection setting information byte received via the line Lin2, and sends it to the lines Lout1 and Loutn other than the line Lout2 corresponding to the line Lin2. The case where the line connection setting information byte of all “1” as the maximum value is returned from the All “1” transmission unit 14 to the line Lout2 corresponding to Lin2 is shown. That is, the line connection setting information byte having the maximum value is transmitted from the output port corresponding to the input port that has received the line connection setting information byte having the minimum value.
[0024]
In this way, the master station receives the maximum line connection setting information byte of all “1” from the partner station that has received the minimum value of “0” of the line connection setting information byte at the start of setting the order wire line. It will be. When the line connection setting information byte is received via a line corresponding to a plurality of input ports, the reception source selection unit 13 selects the one having the smallest value and transfers it to the addition unit 15 and determines the transmission line. Notification to the unit 16. If the line connection setting information bytes have the same value, the receiving line connection setting information bytes corresponding to the input port selected according to the preset order, for example, the port number in ascending order, are transferred to the adding unit 15. That is, the reception source is selected as one input port among the plurality of input ports, and the line connection setting information byte is a value obtained by adding 1 each time it is transferred via the NE.
[0025]
FIG. 4 shows an operation flowchart of the reception source selection unit, where i = 1, reception source = i, and minimum value = reception value (i) (A1). In this case, the input port number is i, the transmission source is associated with the input port number i, the value of the line connection setting information byte of the input port of the number i is the received value (i), and first, this is the minimum value. To do. When the line connection setting information byte of all “0” at the start of the setting of the order wire line is received, the received value = 0.
[0026]
Then, it is determined whether or not to use the OW (order wire) function (A2). If not used, the process is terminated. If used, i = 1 again (A3), and it is determined whether i <n, that is, whether the input port number i exceeds the total number of input ports (A4). When it exceeds, it moves to step (A2). If not, i = i + 1 is set (A5). That is, processing for the next input port number is performed.
[0027]
Then, it is determined whether or not the received value (i) is valid (A6). If the received value (i) is not valid, for example, the failure detection information detected by the failure detection means 3 (see FIG. 1) is the invalidity notification unit 9 (FIG. Since the invalidity notification is transferred to the setting control means 4, the received value (i) corresponds to the case where it is not valid, and the process proceeds to step (A4) for the next input port number. Process. If it is valid, it is determined whether or not the received value (i) is smaller than the minimum value (A7). If the received value (i) is larger than the minimum value, the process proceeds to step (A4). In this case, the receiver is updated to i, the minimum value is equal to the received value (i) (A8), and the process proceeds to step (A4). As a result, the input port with the smallest value of the line connection setting information byte can be set as the receiving source of the order wire line for a plurality of input ports.
[0028]
FIG. 5 is an explanatory diagram of the line connection state, in which an order wire line is set between a line-compatible partner station whose line connection setting information byte received is all “1” and the minimum value. The connection means includes a voice information adding section. (A) shows a case where the line connection setting information byte is all “1” of the maximum value for lines 1 and n and 1 of the minimum value for line 2. When the transmission is performed, the transmission voice information is added to the voice information from other lines in the line connection means, and is sent to the line 1 as shown as line 2 + line n + transmission. Then, it is sent to the line 2 as shown as line 1 + line n + transmission, and is sent to the line n as shown as line 1 + line 2 + transmission. Also, the voice information via the lines 1, 2, n can be added and received as indicated as an incoming call.
[0029]
FIG. 5B shows a case where the value of the line connection setting information byte of line 1 is 2 and the value of the line connection setting information byte of line 2 is 1. Accordingly, the received value is the maximum value. Since the line 1 that is neither “1” nor the minimum value is not set as an order wire line, the line connection means does not connect the line 1. That is, no order wire line is set for line 1.
[0030]
  6 to 8 are diagrams for explaining the order wire line setting operation. FIG. 6A shows an initial state in the same configuration as the network configuration shown in FIG. 1, and arrows in the double ring transmission line. The transmission direction is shown. AndOf FIG.As shown in (B), a master station is set for setting an order wire line.NE1 is a master station, NE2 to NE5 are slave stationsAnd P1 to P4 are shown as the same port number by associating the input port with the output port. Also, '00' indicates that the line connection setting information byte is all “0”.Minimum valueShow the case. In addition,Before order wire line setting startIn the initial state, the values of the line connection setting information bytes from the NE1 to NE5 are generally in an indefinite state, but can be set to a predetermined value in advance.
[0031]
  When the master station is set in the setting unit 11 (see FIG. 3) of the setting control means 4 of the order wire control apparatus 1 of the NE1, the transmission line determination unit 16 applies to all output ports, that is, from the ports P1 and P2 of the NE1. The line connection setting information byte is transmitted as all “0” of the minimum value indicated as “00”. In addition,Do not set as a master stationOther slave stationsofAlso from each port of NE2 to NE5Minimum valueAlthough the line connection setting information byte of all “0” is shown, the final setting of the order wire line in this caseStatusIt does not affect. As shown in FIG. 7C, NE2 is connected to port P1.From NE1When the line connection setting information byte of all “0” is received, the line connection setting information byte of the maximum value “1” shown as “FF”From port P1Return to NE1,Also received by port P11 is added to the line connection setting information byte of all “0” by the adder 15 (see FIG. 3).From other port P2Show as '01Line connection setting information byteSend it out.
[0032]
  NE4 is the master station NE1.Port P1Before receiving the line connection setting information byte of all “0” ('00) fromNE3 ports P2, P3 due to transmission distance differenceAll “0” ('00) line connection setting information bytes from port P1, P4Received byIn this case, the line setting process is started, and the reception line connection setting information byte of the young port P1 among the ports P1 to P4 is in the state indicating the minimum value.Line connection setting information byte of all “1” ('FF) from port P1To port P2 of NE3ReturnandThe received line connection setting information byte of all “0” (“00”) is incremented by 1 and a line connection setting information byte indicated as “01” is transmitted from the other ports P2, P3, and P4. At this time, NE3 and NE5 are still sending line connection setting information bytes of all “0” ('00).Indicates the case.
[0033]
  Next, as shown in FIG.All “0” ('00) line connection setting information bytes are transmitted from the ports P1 and P2 of the NE1 of the master station, and the maximum “all” “1” ('FF) line connection setting information is transmitted from the port P1 of the NE2. A byte is transmitted, a line connection setting information byte of '01 is transmitted from the port P2, a line connection setting information byte of all “1” ('FF) is transmitted from the port P1 of the NE4, and the other ports P2 to P4 are transmitted. Send '01 line connection setting information byte. In the state shown in FIG. 7C, NE3 receives the line connection setting information byte of '01 through ports P1 and P3, and all the maximum value “1” (from NE4 through port P2). The line connection setting information byte of “FF” is received, and the line connection setting information byte of the minimum value “0” (“00”) is received from the NE 4 by the port P4. As described above, the line connection setting information byte of the maximum value “1” ('FF) is transmitted from the port P4 corresponding to the minimum value reception port, and the “01” line obtained by adding +1 to the reception minimum value from the other ports P1 to P3. Send connection setting information byte.
[0034]
  NE5 is alsoIn the state shown in FIG.The line connection setting information byte of all “0” from NE3 is received at port P2, and the port connection setting information byte of “01” from NE4 is received at other port P1.As a result, the minimum line connection setting information byte was received as shown in FIG.With port P2 as the receiverThe maximum value from port P2All “1”('FF)Returns the line connection setting information byte. In this case, the order wire line between NE3 and NE5 is still set.CompleteIt is not in a state. That is, NE5 is connected to port P2.More maximum valueReceives all “1” line connection setting information bytes, and from its port P2.Maximum valueAll “1” line connection setting information bytes are transmitted.
[0035]
  And NE3 is boat P1,P3Than, Receive the line connection setting information byte with the same value of '01P2,P4More maximum valueThe line connection setting information byte of all "1" ('FF) has been received, and the port selection procedure for the same minimum value of the line connection setting information byte is as follows:Like above-mentioned,If you set the port number to select a young number, in this case,In ports P1 and P3The port P1 is set as the reception source. That is, as shown in FIG. 8E, the NE 3 returns all “1” line connection setting information from the port P1. Then, “01” is added to the line connection setting information byte of “01” from NE2, and is transmitted from the ports P2 to P4 as the line connection setting information byte of “02”. The NE 5 receives the line connection setting information byte of “01” at the port P1, and receives the line connection setting information byte of “02 at the port P2, and receives the young port P1 in the minimum value reception from the source. And select “1” from port P1.('FF)Returns the line connection setting information byte.
[0036]
  Other than the NE1 of the master station, the input port that has received the minimum line connection setting information byte, and all “1” corresponding thereto('FF)Pair with the output port that sent the line connection setting information byte of the maximum, and the maximum value of all “1”('FF)A connection port for an order wire line with a pair of an input port that has received the line connection setting information byte and an output port corresponding to this input port.TheSet. Therefore, as shown in FIG. 8 (F), the order wire line of the route of the port P1 of the NE3 port P1 → the NE2 port P2, P1 → NE1 port P2, P1 → NE4 port P2, P3 → NE5 port P1 is set. Is done. This order wire line does not form a loop, and therefore no howling occurs.
[0037]
9 and 10 are diagrams for explaining the operation when a failure occurs. In the connection state of the order wire lines shown in FIGS. 8E and 8F, as shown in FIG. , NE4, NE1 cannot receive all “1” line connection setting information bytes from NE4, and NE4 cannot receive all “0” line connection setting information bytes from NE1. It becomes a state. In this case, failure detection information by the failure detection means 3 in the NE 4 is input to the invalidity notification unit 9 (see FIG. 2), and an invalidity notification is made to the setting control means 4.
[0038]
As shown in FIG. 9B, the minimum value among the values of the line connection setting information bytes received at the ports P1 to P4 of the NE4 is '02 from the NE3 at the ports P1 and P4. The line connection setting information byte. With respect to the line connection setting information byte of the same value, the young port P1 is selected as the receiver, and the line connection setting information byte of all “1” is returned from this port P1, and the other ports P2 to P4 are returned. Then, 1 is added to the line connection setting information byte of “02” of the minimum value, and the line connection setting information byte of “02 + 1 =“ 03 ”is transmitted.
[0039]
Further, since NE5 receives the line connection setting information byte of '03 at port P1 and '02 at port P2, as shown in FIG. 10C, the minimum port P2 is set as the reception source. The line connection setting information byte of all “1” is returned, and the line connection setting information byte of “02 + 1 =“ 03 ”is transmitted from the port P1. As a result, as shown in FIG. 10 (D), on the path of NE1 port P2 → NE2 port P1, P2 → NE3 port P1, P3 → NE5 port P2 and NE3 port P2 → NE4 port P1. An order wire line is set up. That is, the route of the order wire line shown in FIG. 8F is automatically switched to the route shown in FIG. 10D due to a failure between NE1 and NE4. Therefore, a ring protection function and a ring restoration function are provided.
[0040]
FIG. 11 is an explanatory diagram of a mesh network. NEs at intersections of A-1 to E-5 are connected by transmission lines, respectively, and A-1 to E-5 are centered on NE of C-3. NEs and A-5 to E-1 NEs are connected by transmission lines, and C-1 to C-5 NEs and A-3 to E-3 NEs are connected by duplex transmission lines. The connected network is shown, and the center NE indicates a case where twelve ports P1 to P12 are provided as shown below.
[0041]
In such a mesh network, the NE at the position C-3 is set as the master station M, the line connection setting information byte is transmitted from one port P1 among the ports P1 to P12, and the order wire line is connected. When setting sequentially, an order wire line of a route indicated by a thick line in FIG. 12 is set. This order wire line can be set so as not to form a loop, but the number of NEs connected from the master station M is indicated by a numerical value in each circle. Therefore, the second NE from the master station M of C-3 is the NE at the position of A-3, B2, B4, but the other NE is the third or more, for example, E-3 The NE of the position is the sixth from the master station. In other words, the loop is not formed, but the line becomes too long, which may cause a problem in the call.
[0042]
On the other hand, when the present invention is applied, as shown in FIG. 13, the frame including the line connection setting information byte of the minimum value, for example, all “0” is transferred from the master station M at the position C-3 to all ports P1 to P1. Send from P12. Thereby, for example, the NE of B-3 selects the young port P3, for example, because the values of the line connection setting information bytes received by the ports P3 and P4 are the same “0”. And all “1” line connection setting information bytes are returned to the master station M. The NE B-3 transmits a line connection setting information byte having a value of 0 + 1 = 1 from the other ports P1, P2, P4 to P6.
[0043]
Further, when the NE of A-3 receives the line connection setting information byte from the ports P1 and P6 of the NE of B-3, it shows the same value, so the young port P3 is selected as the receiving source, and all “ A line connection setting information byte of 1 ″ is returned. When each NE executes such a procedure, an order wire line having a route without a loop indicated by a thick line is set. In this case, the number of connections from the central master station M is shown as a numerical value in a circle. That is, the order wire line is set so as to be the second from the master station M at the maximum.
[0044]
In addition, when this order wire line failure occurs, the line connection setting information byte of the input port of the line where the failure has occurred is selected as the invalid byte, and the minimum value among the receiving line connection setting information bytes of the other input ports is selected. The input port is set as the receiver, the line connection setting information byte with the maximum value of all “1” is returned from the output port corresponding to the input port, and 1 is added to the minimum value for the other output ports. Sends the value of the line connection setting information byte. As a result, the connection of the order wire line is automatically switched.
[0045]
(Supplementary Note 1) In an order wire control system for setting an order wire line between a plurality of network elements, the network element includes an order wire control device for setting an order wire line, and the order wire control device includes an order wire tool and an order wire tool. A communication means corresponding to an input port for separating and extracting a line connection setting information byte for setting an order wire line; a line connection means including a selective addition function of the order wire byte; and an order wire byte from the line connection means; A communication means corresponding to an output port for multiplexing and transmitting the line connection setting information byte, and a setting control means for processing the line connection setting information byte, wherein the setting control means receives the line connection setting of the received minimum value. The input port of the information byte is the receiver, and the input port A maximum line connection setting information byte is returned from the output port, and line connection setting information having a value obtained by adding 1 to the reception line connection setting information byte is transmitted from the other output port. A control function for setting the output port corresponding to the input port, the input port receiving the maximum line connection setting information byte, and the output port corresponding to the input port as the port for the order wire line; Order wire control system.
[0046]
(Supplementary Note 2) One of the plurality of network elements is set as a master station, and the setting control means of the order wire control device of the master station transmits a minimum line connection setting information byte from all output ports. The additional function according to claim 1, further comprising a control function for setting a port for an order wire line as a set of an input port that has transmitted and received the maximum line connection setting information byte and an output port corresponding to the input port. Order wire control system.
(Supplementary Note 3) The setting control means includes a receiving source selection unit that selects an input port having a minimum value of the line connection setting information byte as a receiving source, and a line connection having a maximum value from an output port corresponding to the input port of the receiving source. The order wire control according to claim 1 or 2, further comprising: a transmission line determination unit that transmits a setting information byte and transmits a line connection setting information byte obtained by adding 1 to the minimum value to another output port. system.
(Additional remark 4) The said order wire | line control apparatus is provided with the failure detection means to notify to the said setting control means that the said line connection setting information byte is invalid by failure detection, Any one of Additional remark 1 thru | or 3 characterized by the above-mentioned. Order wire control system.
(Supplementary Note 5) The order wire control device includes a configuration in which the line connection setting information byte is inserted into an empty byte at a predetermined position in the overhead of the SONET / SDH frame and transmitted. 5. The order wire control system according to any one of 4 above.
[0047]
(Supplementary Note 6) In a network element that is connected to another network element and includes an order wire control device for forming an order wire line with the other network element, the order wire control device includes: Communication means corresponding to an input port that separates and extracts a line connection setting information byte for setting an order wire line and an order wire line, a line connection means including a selective addition function of the order wire byte, and an order wire from the line connection means A communication means corresponding to the output port for multiplexing and transmitting the byte for connection and the line connection setting information byte, and a setting control means for processing the line connection setting information byte, the setting control means for receiving the received minimum value The input port of the line connection setting information byte is the receiver, and the output port corresponding to the input port The line connection setting information byte having the maximum value is returned from the other line, and the line connection setting information having a value obtained by adding 1 to the receiving line connection setting information byte is transmitted from the other output port. A network comprising a control function for setting a corresponding output port, an input port that has received the maximum line connection setting information byte, and an output port corresponding to the input port as a port for the order wire line ·element.
[0048]
(Appendix 7) In an order wire control method for setting an order wire line between a plurality of network elements, an input port of a minimum line connection setting information byte is received by the setting control means of the order wire control device of the network element. The line connection setting information byte of the maximum value is returned from the output port corresponding to the input port, and the line connection setting information byte having a value obtained by adding 1 to the receiving line connection setting information byte is transmitted from the other output port. The input port as the transmission source and the output port corresponding to the input port, and the input port receiving the maximum line connection setting information byte and the output port corresponding to the input port are set as ports for the order wire line. An order wire control method comprising the step of:
(Supplementary note 8) One of the plurality of network elements is set as a master station, and the master station sends a minimum value of the line connection setting information byte from all the output ports, and the maximum value of the line connection setting information. The order wire control method according to appendix 6, further comprising a step of setting a pair of an input port that has received a byte and an output port corresponding to the input port as a port for an order wire line.
(Supplementary note 9) Invalidate the line connection setting information byte corresponding to the detected input port to the setting control means, and the setting control means selects the input port indicating the minimum value of the receiving line connection setting information byte, and The input port indicating the minimum value is set as the reception source, the line connection setting information byte of the maximum value is returned to the output port corresponding to the input port, the input port as the transmission source and the output port corresponding to the input port, The order wire control method according to appendix 6 or 7, further comprising the step of setting the input port receiving the maximum line connection setting information byte and the output port corresponding to the input port as a port for an order wire line. .
[0049]
【The invention's effect】
As described above, in the present invention, even in a complex and large-scale network including a plurality of NEs, a master station is set and a minimum value, for example, all “0” lines are set from the master station to all output ports. Send connection setting information byte to start setting the order wire line. In slave stations other than the master station, the input port that received the line connection setting information byte of the minimum value is used as the receiver, and this input port is supported. For example, the line connection setting information byte of the maximum value of all “1”, for example, is returned from the output port, and the line connection setting information byte having a value obtained by adding 1 to the receiving line connection setting information byte is transmitted from the other output port. Yes, automatically has a ring protection function and a ring restoration function, depending on whether the order wire function is used / not used and the master / slave station settings There is the advantage that it is possible to set the order wire line. Further, since the order wire line is set from the master station through the shortest route, there is an advantage that the call quality can be improved.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of an embodiment of the present invention.
FIG. 2 is an explanatory diagram of a main part of a communication unit.
FIG. 3 is an explanatory diagram of a main part of a setting control unit.
FIG. 4 is an operation flowchart of a reception source selection unit.
FIG. 5 is an explanatory diagram of a line connection state.
FIG. 6 is an explanatory diagram of an order wire line setting operation.
FIG. 7 is an explanatory diagram of an order wire line setting operation.
FIG. 8 is an explanatory diagram of an order wire line setting operation.
FIG. 9 is an operation explanatory diagram when a failure occurs.
FIG. 10 is an explanatory diagram of an operation when a failure occurs.
FIG. 11 is an explanatory diagram of a mesh network.
FIG. 12 is an explanatory diagram of order wire line setting by simple processing.
FIG. 13 is an explanatory diagram of order wire line setting according to the embodiment of this invention.
FIG. 14 is an explanatory diagram of a conventional example.
FIG. 15 is an explanatory diagram of a SONET / SDH frame format.
FIG. 16 is an explanatory diagram of a conventional example.
[Explanation of symbols]
1 Order wire controller
2a, 2b Communication means
3 Failure detection means
4 Setting control means
5 Telephone
5a transmitter
5b handset
6 Line connection means
NE1 to NE5 network elements
RN1, RN2 ring network

Claims (4)

In an order wire control system for setting up an order wire line between a plurality of network elements,
The plurality of network elements include an order wire control device for setting an order wire line,
The order wire control device comprises: communication means corresponding to an input port for separating and extracting an order wire byte and a line connection setting information byte for setting an order wire line; and a line connection means including a selective addition function of the order wire byte; A communication means corresponding to an output port for multiplexing and sending out the order wire byte and the line connection setting information byte from the line connection means, and a setting control means for processing the line connection setting information byte,
One of the plurality of network elements is set as a master station, and the setting control means of the master station sends a minimum value of line connection setting information bytes from all output ports, and sets the maximum value of line connection. A control function for setting an input port that receives an information byte and an output port corresponding to the input port as a pair for an order wire line port, and the setting control means of other network elements excluding the master station includes a plurality of The received line connection setting information byte corresponding to the input port is compared at a predetermined timing, and when the input port of the received line connection setting information byte of the minimum value is single, the input port is selected. Select an input port in a preset order, set the selected input port as the receiver, and select the maximum value from the output ports corresponding to the input port selected as the receiver The line connection setting information byte is returned, and the line connection setting information byte having a value obtained by adding 1 to the received minimum value of the line connection setting information byte is transmitted from the other output port, and the input selected as the receiving source. A control function for setting the port and the output port corresponding to the input port, the input port receiving the maximum line connection setting information byte, and the output port corresponding to the input port to the port for the order wire line; An order wire control system. In a network element with an order wire control device for forming an order wire circuit ,
The order wire control device comprises: communication means corresponding to an input port for separating and extracting an order wire byte and a line connection setting information byte for setting an order wire line; and a line connection means including a selective addition function of the order wire byte; A communication means corresponding to an output port for multiplexing and transmitting the order wire byte and the line connection setting information byte from the line connection means, and a setting control means for processing the line connection setting information byte,
The setting control means when set to the master station sends out the minimum line connection setting information byte from all output ports, and receives the maximum value of the line connection setting information byte and the output corresponding to the input port. A control function for setting a port as a pair to an order wire line port, and the setting control means when not set in the master station, the received line connection setting information bytes corresponding to a plurality of input ports at a predetermined timing When the input port of the line connection setting information byte of the minimum value received is single, the input port is selected. When there are multiple input ports, the input port is selected in a predetermined order, and the selected input port is received. and the original, sends back the line connection setting information bytes maximum value from the output port of the corresponding input port selected by the said receiving source, and the other output port, the received Sends a line connection setting information byte value obtained by adding 1 to the line connection setting information bytes of the small value, the input port and the input port corresponding output port is selected as the received source line connection setting information of the maximum value A network element comprising a control function for setting an input port that has received a byte and an output port corresponding to the input port as a port for the order wire line. In an order wire control method for setting an order wire line between a plurality of network elements,
The plurality of network elements include communication means corresponding to an input port for separating and extracting an order wire byte and a line connection setting information byte for setting an order wire line, and a line connection means including a selective addition function of the order wire byte If, order wire control including a Oh Dawaiya bytes and line connection setting information bytes from該回line connection means and the output port corresponding communication means for transmitting by multiplexing, and a setting control means for processing the line connection setting information bytes A network station configured to set one of the plurality of network elements as a master station, and the setting control means of the order wire control device of the network element set in the master station includes: Bytes are sent from all output ports and the maximum line connection setting information byte is received. Set the power port and input port corresponding output port to a port for the order wire line as a set, the setting control unit of the order wire control device other network elements except for the master station, a plurality of input ports corresponding The received line connection setting information bytes are compared at a predetermined timing, and when the input port of the received line connection setting information byte of the minimum value is single, the input port is selected. The input port is selected with the selected input port as the reception source, the maximum line connection setting information byte is returned from the output port corresponding to the input port, and the received minimum value is received from the other output port. A line connection setting information byte having a value obtained by adding 1 to the line connection setting information byte is transmitted, and the input port as the selected reception source and the input port An order wire control method comprising: setting a corresponding output port, an input port that has received the maximum line connection setting information byte, and an output port corresponding to the input port as a port for an order wire line .   One of the plurality of network elements is set as a master station, and the master station sends a minimum line connection setting information byte from all output ports and receives a maximum line connection setting information byte. 4. The order wire control method according to claim 3, further comprising a step of setting an input port and an output port corresponding to the input port as a set to a port for an order wire line.

Images