JPH0338132A - Relay line selection system - Google Patents

Abstract

PURPOSE:To improve the function of bypass circuit selection when a fault occurs by comparing a destination network address of information with a network address of other station registered in a routing table in the case of information transfer and selecting a nearby normal relay line to the destination network address. CONSTITUTION:A network address assigned to each exchange is expressed in 2-dimension coordinate, a routing table 40 storing network address of other station connecting to the line for each relay circuit connecting to its own station is provided to exchanges NP-A, NP-B, the destination network address of the information and the network address of other station registered in the routing table are compared in the information transfer and the nearby normal relay line is selected to the destination network address. Thus, number of entries of the routing table of each exchange station is the number of lines connecting to its own equipment and the succeeding connection information of the connection destination equipment of the line is not required, then the routing table is simplified.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a trunk line selection method in a data exchange network, and in particular to addressing of a switching center in a data exchange network or an information processing device of an information processing system, routing within the data exchange network or within the information processing system, and in the event of a line failure. This invention relates to a trunk line selection method effective for selecting a detour. [Prior Art J] In a conventional network system, for example, a packet switching network, it is necessary to know the addresses of the switching center and packet subscribers, and the addresses of the sending station, receiving station, first shortest address, etc. are stored in the routing table as routing information. root, second
The shortest route etc. were set in advance. Note that related methods of this type include, for example,
JP 63-172589, JP 63-20219
The technique disclosed in Publication No. 9 can be mentioned. [Problems to be Solved by the Invention] The above-mentioned conventional technology takes into account the simplification of the communication route for communication from one subscriber to another subscriber and the method of selecting a detour when a failure occurs. When building a network system, set all communication stations in the network system in the switching center's routing table.
At the same time, it is necessary to set avoidance routes including detours in advance, so the routing table becomes large and complicated, and the route route must be carefully considered when designing the network. In addition to being time consuming, there is a problem in that the maintenance of the routing table is poor when changing the configuration. The present invention has been made in view of the above circumstances, and its purpose is to solve the above-mentioned problems in the conventional technology, to simplify the routing table used when selecting a trunk line, and to simplify the routing table. It is an object of the present invention to provide a trunk line selection method that improves maintainability and improves the function of selecting a detour when a failure occurs. (Means for Solving the Problems) An object of the present invention is to express the intra-network address assigned to each exchange in two-dimensional coordinates in a data exchange network having a plurality of exchanges and relay lines connecting the exchanges. In addition, each exchange is equipped with a routing table for storing the in-network addresses of other stations connected to that line for each trunk line connected to the own station, and when transferring information, the destination in-network address of the information and the routing table are stored. This is achieved by a relay line selection method that compares the network addresses of other stations registered with the destination network address and selects the normal relay line closest to the destination network address.

[Effect]

In the trunk line selection method according to the present invention, each switching center compares the destination address of the transmitted data with all addresses registered in the routing table, and compares the destination address of the transmission data with all addresses registered in the routing table.
Select the one with the minimum two-dimensional distance. This results in
The number of entries in the routing table of each exchange corresponds to the number of lines connected to the own device, and since connection information on further devices to which the line is connected is not required, the routing table is simplified. Further, even if a line connected to another device is added, the routing table of the device itself is not affected, so there is an effect that the maintainability of the routing table is improved. Furthermore, there is an effect that a detour route in the event of a failure is determined by selecting the next candidate line. Note that when selecting a line, it is also possible to take the usage priority into consideration. In addition, in an information processing system consisting of a data exchange network and subscriber equipment directly connected to it, the intra-network address and data exchange network subscriber number assigned to the exchange are expressed in two-dimensional coordinates, and each exchange For each relay line and subscriber line connected to its own station, it has a routing table that stores the in-network address or subscriber number of another station connected to the line, and when transferring information, the destination subscriber of the information In this type of information processing system, the number is compared with the network address or subscriber number of another station registered in the above routing table, and the nearest normal trunk line or subscriber line is selected. It is also possible to obtain the same effect as above. (Example) Hereinafter, an example of the present invention will be described in detail based on the drawings. FIG. 2 is an explanatory diagram of a method of naming addresses of switching stations and a routing table in a packet switching network showing an embodiment of the present invention. In the figure, 10 to 12 are exchange offices (
(hereinafter also referred to as rNPJ), 20 and 21 are subscriber equipment (
(hereinafter also referred to as EDTEJ), 30 to 33 are lines, 40
shows the routing table of NP-A. NP-AIO has four lines, namely line (A).
309 line (a) 311 line (tsu) 32 and line (1)
) 33 is connected, and line (a) 30 and line (t)
32 is connected to DTE, line (a) 31 and line (1) 3
The connection destination of No. 3 is another NP. FIG. 3 shows a specific example of the routing table of the NP-A, and 41a in FIG. 3(a) shows a specific example of the routing table when the present invention is applied only to a switched network. Reference numeral 42 in Figure (b) shows a specific example of a routing table when the present invention is applied to an information processing system including subscriber devices. In addition, the same figure (a)
41b indicates a DTE table. First, a case will be described in which the present invention is implemented only in a packet switching network and the conventional DTE address system is maintained for the DTE. The intra-network addresses assigned to the NPs constituting the packet-switched network are expressed in an orthogonal coordinate system (x ey ). Here, from Fig. 2, NP-AIO, NP
-The network addresses of Bll and NP-C12 are as follows:
(2,2), (2,4), (3°2). In addition, in this case, the entry targets of the routing table are other N
As for the DTE, a DTE table indicating the correspondence between the DTE address and the address within the NPO network to which the DTE is connected is required, as in the past. In this case, NP
- A 10 routing table 41a and DTE
The table 41b is as shown in FIG. 3(a). Note that the DTE table 41b has all N
P must have it. Next, when the present invention is implemented in an information processing system including subscriber devices, the above-mentioned intra-network address and DTE address are expressed in an orthogonal coordinate system (x*y). DTE
In reality, the address can be created by dividing the number of effective digits of the DTE address into two and assigning the X coordinate to the upper byte and the X coordinate to the lower byte, but in order to simplify the explanation below, (x,
Expressed as y). Therefore, DTE-A20. The DTE addresses of the DTE-B21 are (1, 2) and (2, 1), respectively. In addition, the entries in the routing table in this case are both NP and DTE, and in this case, the NP-AIO
The routing table 42 is as shown in FIG. 3(b). According to the above embodiments, the effect of simplifying the routing table can be obtained in any case. FIG. 4 is a diagram showing an example of a system configuration when the present invention is implemented in an information processing system including a subscriber device. In the figure, 10 to +3 are switching stations (NP), 20 to 25 are subscriber equipments (DTE), and 30 to 38 are lines. Each NP in FIG. 4 has its own routing table in accordance with the method of naming the NP's intra-network address and DTE address and the method of creating a routing table explained with reference to FIG. Below, in Figure 4, %DTE-A
A line selection method when one call is made from the DTE-E 20 to the DTE-E 24 will be described. When the NP-A 10 receives a calling packet from the DTE-A 20, the NP-A 10 selects the destination DTE address (3, 5) closest to the destination DTE address (3, 5) in the calling packet among all the entries in its own routing table A. x+y) coordinate NP or DT
Select the line connected to E. Here, the line (
b) 31 is selected. Similarly, in NP-811, the line (power) is 35%, and in NP-DI3, line (ke) 38 is selected, and the call arrives at the DTE-E 24. Note that at this time, it goes without saying that the (x*y) addresses in the routing table are sorted in ascending order or descending order. Next, a line selection method will be described in the case where a call is made from the same DTE-A 20 to the DTE-E 24 and the line (a) 31 is faulty. In the routing table A of NP-A 10, the line (
b) Invalidate the entry for 31 and make the entry for line (1) 33
Select. Furthermore, line 37 is selected in NP-CI2, line 38 is selected in NP-D I3, and D
A call arrives at TE-E24. In this way, in this example,
It also has a detour function for failed lines. Next, when the DTE-F25 and line (co) 39 are added, the addition of the routing table entry is
Only the NP-CI2 to which the TE-F25 is directly connected is required, and the routing tables of other NPs do not need to be changed. In this way, this embodiment has the advantage that the maintainability of the routing table is good. FIG. 1 shows a flowchart of the line selection process in the NP of FIG. First, the NP extracts the destination X coordinate and the X coordinate from the calling packet from the DTE (step 50). Next, the line going to the NP closest to the destination is selected from the extracted destination address (m, n) and the address (X, y) entered in the routing table of the own station. That is, the sum S of the absolute value of the difference in the X coordinate (m-x) and the absolute value of the difference in the y coordinate (ny) is calculated for each line (step 60). From the above calculation results, select the line for which the value of the sum S mentioned above is the smallest,
The calling pad is transferred to the NP to which the line is connected (step 70). In the configuration shown in FIG. 4, if the present invention is used only in the packet network and the conventional DTE address system is maintained for the DTE, the DTE table is used to determine the destination address as shown in FIG. It is only necessary to add processing for searching the destination NP network address from the DTE address, and the line selection processing is the same as described above. Furthermore, in the configuration shown in FIG. 4, if any line in the routing table is at fault, the faulty line is bypassed by simply invalidating that line in the routing table. In addition, after setting the logical channel, as before,
Needless to say, it is necessary to record the correspondence between the logical channel and the DTE address, and to convert the logical channel to the destination DTE address in subsequent communications. Next, the process of preferentially using each line when selecting one line will be explained. In step 60 of FIG. 1, s = l m -x I + I n y 1 was calculated, but by adding the line priority usage parameter: 2 to this, and depending on the magnitude of S' = 1 m - x l + 1 n - yl + z , you can also select a line. For example, the line with the highest priority may be set to 2=0, and the value of Z may be increased thereafter in order of priority seats. Here, fine tuning is also possible by adding tRflrJ to the increase in Z relative to the priority. FIG. 5 is a configuration diagram of a composite network system showing an application example of the present invention. In the figure, 100 to 160 are end systems (hereinafter referred to as rESJ), 200 to 270 are relay systems (hereinafter referred to as rR8J), 300 is a local area network (LAN), and 310 to 315 are dedicated lines (hereinafter referred to as rPLJ). , 320 indicates a packet switching network (hereinafter referred to as rPsDNJ), and 330 indicates a circuit switching network (hereinafter referred to as rC8DNJ). A network address that uniquely identifies the ES and R3 within the system is assigned to the above-mentioned ES and R3. Further, the network address of the ES has a hierarchical structure, and is assumed to be an RS network address + a local address. The RS network address is the network address of the R3 to which the own ES is directly connected expressed in -(Xpy) coordinates, and the local address is the LAN address or leased line identification number assigned depending on the type of R3 to be connected. It is. For local addresses, (x
, y) It does not matter whether it is expressed in coordinates or not. Also,
Above PSDN 320. In the C3DN 330, it does not matter whether or not the present invention is applied within the network or between the network and the subscriber, as shown in the embodiments of FIGS. 2 to 4. This is a routing issue within the network, and the subscriber, e.g.
3-F240 is PSD N 320, R5-
B210 (7) If you specify the subscriber number, it will be R3-8210.
Then, by specifying the subscriber number of R3-F250 to C3DN 330, it is sufficient to be able to communicate with each of R3-F250. 6(a)-(h) are the routing tables for FIG. 5. The difference between the routing table shown in Fig. 6 and the routing table shown in Fig. 3 is as follows.
In the single network shown in FIG. 3, the entries in the routing table are in units of lines, whereas in the composite network configuration in FIG. 6, the entries in the routing table are in units of R3, and the PSDN 3
20. In the case where the C3DN 330 is not applied with the embodiments of the present invention shown in FIGS. 2 to 4, a network subscriber number corresponding to R3 is required. However, this item is PSDN 320. C3DN
330 is the second! ! 48th from l! This is not necessary if the embodiment of the present invention shown in Section I is applied. In FIG. 5, the routing process when data is transmitted from the ES-CI 20 to the ES-CI 60 will be described below. ES-CI20, which is the originating ES, connects R3-C220 and L
It is connected by AN300, and R3-C:220 is connected to R300.
S-8210 and PL"-8311 are connected. Also, R3-8210 is connected to R3-A200 and PL-A3
10, and R3-D230. R3-B24
0 and is connected via PSDN320. R8-B240
is R3-F250゜R3-G260 and C3DN330
connected with. , R3-F 250 is R3-A2
00 and PL-B315 again. It is connected to R3-8270 and PL-B314. ES-G160, which is the incoming ES, has R3-8270 and L
Connected by AN300. Also, E S -A I
oo. ES-BIIQ and ES-DI30 each have LAN30
0 through R3-A200. R3-B210. R3-D
230. E5-B140. E
S-F 150 is PL-C312, PL-D3, respectively.
R3-B240.13 via R3-B240. Connected to R3-F 250. The ES-C120, which is the originating ES, is the ES-C120, which is the incoming ES.
-G160's network address + local address = (1, 3) + 160 is added to the data and sent to the R3-C220 to which it is connected. Needless to say, it is better to set the LAN address of R5 to the same value for all R3s. In the R3-C220, each address (x, y) in its own routing table (420 in FIG. 6) and the RS of the incoming ES
Compare the network address (1.3) and follow the process shown in Figure 1 to find the nearest PL-831 to the destination ES.
1 and transfer the frame to RS-8210. R
S-8210 selects RS-2240, specifies the destination to RS-B240 using the network subscriber number, and transfers the frame. Similarly, in RS-B240, RS-G26
0, RS-0260 selects the line to RS-8270, and the frame arrives at RS-8270. In RS-8270, (
When it is confirmed that x + y) is the address of the local station, it is transferred to the ES-G 160 indicated by the local address in the completed network address. As described above, according to this embodiment, by providing the RS with a routing table represented by orthogonal coordinates, it is possible to easily select the nearest line even in a complex composite network. Note that the RS routing table only needs to be registered for adjacent RSs, and this point is similar to the embodiments shown in FIGS. 2 to 4. Further, the detour selection process and the line preferential use process in the event of a line failure are also the same as in the previous embodiment. It should be noted that each of the above-mentioned embodiments is shown as an example of the present invention, and it goes without saying that the present invention should not be limited to these. [Effects of the Invention] As described above in detail, according to the present invention, in a data switching network having a plurality of exchanges and trunk lines connecting the exchanges, the network address assigned to each exchange can be divided into two dimensions. In addition to expressing it in coordinates, each exchange is equipped with a routing table that stores the network addresses of other stations connected to that line for each relay line connected to its own station, and when transferring information, it The address is compared with the network address of another station registered in the routing table, and the closest normal trunk line is selected as the destination network address, so the routing table used when selecting the trunk line is This has the remarkable effect of realizing a trunk line selection method that is simplified, maintainability of the routing table is improved, and has an improved function for selecting a detour when a failure occurs.

[Brief explanation of drawings]

FIG. 1 is a flowchart of line selection processing showing an embodiment of the present invention, FIG. 2 is an explanatory diagram of a method of naming exchange addresses in a packet switching network of the embodiment, and FIG. 3 is an explanatory diagram of a routing table. FIG. 4 is a diagram showing a system configuration example when the present invention is implemented in an information processing system including subscriber equipment, FIG. 5 is a diagram showing the configuration of a composite network system showing an application example of the present invention, and FIG. 5 is an explanatory diagram of a routing table for FIG. 5; FIG. 10-S-13: NP, 20-25: D
T.E. 30-39: Line, 40, 41 a, 42
: N P-A routing table, 41b:D
TE table, 50: x, y coordinate extraction step, 60 nilting table comparison step, 70: nearest line selection step, 100~+60: ES. 200-270: R3,300: LAN, 310-
315: PL. 320: PSDN, 330: C3DN, 4 (10-4
70 Nilting Table.

Claims (1)

[Claims] 1. In a data switching network having a plurality of exchanges and trunk lines connecting the exchanges, each exchange stores an in-network address assigned to each exchange, and each exchange stores an address for each relay line connected to its own station. , is equipped with a routing table that stores the in-network addresses of other stations connected to the line, and when transferring information, compares the destination in-network address of the information with the in-network address of the other station registered in the routing table. A trunk line selection method is characterized in that a normal trunk line closest to the destination network address is selected.