JPH099313A - Cross connector - Google Patents

Abstract

PURPOSE: To executor re-arrangement of a connection path on a network efficiently to the utmost and to prevent deterioration in the reliability due to the re-arrangement to the utmost. CONSTITUTION: The cross connector 100 interconnecting communication channels 10 via a network 20 where time switches and spatial switches are in T-S-T connected, is provided with a connection part storage means 101 storing information relating to a connection path set at present on a network, a connection ratio storage means 102 storing a connection rate for each path of communication channels designated externally and a connection rate for each path set at present, a connection path setting means 103 referring to stored connection information to set an idle connection path, and a connection path re-arrangement means 104 rearranges a connection path set up at present in compliance with the designated connection rate so as to set a desired idle connection path when the idle connection path cannot be selected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cross-connect device, and more particularly, it is provided with a network in which a time switch and a space switch are connected by T-S-T, and a connection path for connecting specified communication lines is specified. The present invention relates to a cross-connect device that performs relocation based on a connection ratio for each route.

[0002]

2. Description of the Related Art A conventional cross-connect device of this type has a communication line of a certain route added, and when a maintenance person designates a communication line to be connected by the cross-connect device,
After analyzing the current status of the connection path being set in the network of the cross-connect device and selecting an empty connection path, input the connection instruction to each time switch and space switch to set the selected connection path, and I had to set up a connection path.

In the above process, if an empty connection path cannot be selected at present, a part of the connection path currently set in the network is relocated by trial and error to generate an empty connection path. Was trying.

When considering rearrangement, it is best to create an empty connection path in the target communication line for the time being,
It was impossible to take into consideration the future trend of expansion of communication lines for each route.

As a result, immediately after the rearrangement of a certain communication line is executed, if the communication line of the same route is expanded, it becomes necessary to execute the rearrangement again in the cross-connect device.

Further, in the relocation, it is necessary to avoid the interruption of communication due to the relocation as much as possible for the communication line which is being used for a particularly important purpose. It was extremely difficult to consider.

[0007]

As is clear from the above description, in the conventional cross-connect device, when a new communication line is accommodated and an empty connection path cannot be selected, the existing connection path is manually operated. Since we were trying to relocate it, it is utmost to create an empty connection path for the target communication line for the time being, and consider the trend of adding communication lines for each route in the future, or the importance of communication lines It was almost impossible to consider relocation with consideration for sex.

As a result, there is a possibility that the relocation of the existing connection path may be repeatedly invalidated for the frequently added path.
In addition, relocation is performed for communication lines that are very important,
There was also a risk of interrupting important communications and reducing the reliability of communications.

It is an object of the present invention to realize a cross-connect device that can relocate a connection path on a network as efficiently as possible and can prevent deterioration of reliability due to relocation as much as possible. .

[0010]

FIG. 1 is a diagram illustrating the principle of the present invention. In FIG. 1, reference numeral 100 is a cross-connect device to which the present invention is applied, and 20 is a time switch (TSW).
(1 ₁ ) and the space switch (SSW) (2 ₁ ) are TS
-T-connected network.

Reference numeral 101 is a connecting path holding means provided in the cross-connect device (100) according to the present invention. 10
Reference numeral 2 is a connection ratio holding means provided in the cross-connect device (100) according to the present invention.

Reference numeral 103 is a connection path setting means provided in the cross-connect device (100) according to the present invention. 10
Reference numeral 4 is a connection path rearrangement means provided in the cross-connect device (100) according to the present invention.

[0013]

The connection path holding means (101) includes the connection path holding means (101) for holding information about the connection path currently set on the network (NW) (20) and the connection ratio holding means (102). Communication line (1
The connection ratio for each route of 0) and the connection ratio for each route currently set are held.

When a pair of communication lines (10) to be connected is designated, the connection path setting means (103) refers to the connection information holding means (101) and selects an empty connection path,
Set.

When the connection path setting means (103) cannot select an empty connection path, the connection path rearranging means (104) indicates the current connection information stored in the connection information holding means (101). The connection path being set is rearranged according to the specified connection ratio held by the connection ratio holding means (102), and a desired empty connection path can be set.

The connection path rearranging means (104) holds the connection ratio holding means (10) when the connection ratio holding means (102) does not hold the connection ratio designated from the outside.
It is considered that the rearrangement is performed according to the connection ratio for each route currently set in 2).

Further, the connection path rearranging means (104), when rearranging the connection path, specifies the communication line (1) designated as important.
It is considered that the relevant connection path of 0) is excluded from the relocation target.

Therefore, the setting of the specified connection path is automatically tried, and if the specified connection path cannot be selected, the rearrangement is executed in accordance with the specified future communication line extension tendency. Efficient and highly reliable cross-connect because the possibility of repeating relocations is reduced, and important communication lines are excluded from relocations, so there is no risk of interruption of important communications due to relocations. The device becomes feasible.

[0019]

An embodiment of the present invention will be described below with reference to the drawings. 2 is a diagram showing a cross-connect device according to an embodiment of the present invention, FIG. 3 is a diagram illustrating a network control unit in FIG. 2, and FIG. 4 is a diagram illustrating a line ratio database in FIG. , FIG. 5 shows T in FIG.
FIG. 6 is a diagram illustrating a -S connection database, and FIG.
7 is a diagram illustrating a connection matrix database in FIG. 7, FIG. 7 is a diagram illustrating a temporary line transfer table in FIG. 3, FIG. 8 is a diagram illustrating an address search processing process in FIG. 3, and FIG. FIG. 10 is a diagram exemplifying a process of creating a temporary line transfer table in FIG. 10, and FIG. 10 is a diagram exemplifying a process of block avoidance in FIG. The same reference numerals indicate the same objects throughout the drawings.

The cross-connect device (10 shown in FIG.
0) includes a network (NW) (20), a network control unit (CTL) (30), and a man-machine interface unit (MMI) (40).

The network (NW) (20) is composed of a plurality of time switches (TSW) (1) and a plurality of space switches (SSW) (2), and each time switch (TSW) (1). A communication line (10) is housed in each of them, and each time switch (TSW) (1) and each space switch (SSW) (2) are connected to each other by a jumper wire (6).

Each time switch (TSW) (1) has a line accommodating section (LI) accommodating a communication line (10).
F) (3) and a time switch side jumper accommodating portion (TJF) (4) accommodating a jumper wire (6) connecting between the space switches (SSW) (2),
In addition, each space switch (SSW) (2) accommodates a jumper wire (6) connecting between each time switch (TSW) (1) and a space switch side jumper housing (SJ).
F) (5) is added.

On the other hand, the network control unit (CTL) (3
0) is an operator instruction receiving unit (3) as shown in FIG.
1), address receiving unit (32), important line instruction receiving unit (33), TS connection search unit (34), address search unit (35), line transfer table creation unit (36), block avoidance unit (37). ), Line setting instruction unit (38), line ratio database (3A), TS connection database (3)
B), connection matrix database (3C), line setting database (3D) and line temporary movement table (3E).

Among the above, the connection matrix database (3
C), the line setting database (3D) corresponds to the connection path holding means (101) in FIG. 1, and the line ratio database (3A) corresponds to the connection ratio holding means (10) in FIG.
2), the address search unit (35) corresponds to the connection path setting means (103) in FIG. 1, and further the line transfer table creation unit (36) and block avoidance unit (37).
Corresponds to the connection path rearranging means (104) in FIG.

The line ratio database (3A) is shown in FIG.
As shown in FIG. 2, each time slot (TS) in the time switch (TSW) (1) has each space switch (SS)
W) any of the space switch side jumper housings (S) (S)
JF) (5) Data (d) indicating whether they are connected to each other
_Axy ) and jumper housing (SJF) on each space switch side
(5) Subtotal (N) of data (d _Axy ) for each combination
And a ratio of each subtotal (N) to the total [hereinafter referred to as a line setting ratio (H ₁ )] and a designated line ratio (H ₂ ) input by a maintenance person or the like from the man-machine interface unit (MMI) (40). Is stored.

In the TS connection database (3B), as shown in FIG. 5, each time switch (TSW).
(1) time Switch side jumper housing (TJF)
(4) and the TS connection data (d _B ) indicating the connection state between the space switch side jumper accommodating portion (SJF) (5) of each space switch (SSW) (2) [d _B if connected]
= "+ 1", if unconnected d _B = "- 1"] is stored.

In the connection matrix database (3C),
As shown in FIG. 6, at each time slot (TS) in the time switch (TSW) (1), each space switch side jumper accommodating section (SJF) (5) of each space switch (SSW) (2) is connected. The same space switch (SSW) (2), the space switch side jumper accommodating portion (S
Data (d _C ) indicating JF) (5) is stored.

In the line setting database (3D),
Various types of information about each communication line (10), such as line name, important flag (p), connection information, etc., are stored. The above line ratio database (3A), TS connection database (3B), connection matrix database (3C)
And the line setting database (3D), the connection path holding means (101) and the connection ratio holding means (1) in FIG.
02).

2 to 10, a maintenance person or the like uses the man-machine interface unit (MMI) (40) to set a pair of communication lines (10) whose connection paths are to be set [one side is (10 _x ) the other side]. Is designated as (10 _y )], input communication line information (x) and output communication line information (y), information (p) designating an important line, or a designated line ratio (H ₂ ) (CTL) (3
Enter for 0).

The specified line ratio (H ₂ ) is such that the connection line [that is, the space switch side jumper accommodating portion (in the space switch (SSW) (2) ( SJF) (5) It is possible to determine the ratio in consideration of the margin of mutual connection data (d _3A )].

The important line instruction receiving unit (33) adds an important flag (p) to the communication line (10) designated as the important line, stores it in the line setting database (3D), and also receives the address receiving unit (32). ) Transmits the inputted input communication line information (x) and output communication line information (y) to the address searching unit (35), and the operator instruction receiving unit (31) further
The input designated line ratio (H ₂ ) is stored in the line ratio database (3A).

When receiving the input communication line information (x) and the output communication line information (y) from the address receiving unit (32), the address searching unit (35) refers to the line setting database (3D) and Switch side jumper housing (T
JF) (4) the space switch side jumper housing (SJF) (5) is searched, then the TS connection database (3B) is searched via the TS connection search section (34), In the process shown in FIG. 8, an empty connection path is searched.

To summarize FIG. 8, steps S12 and S1
3, the time switch for receiving the communication line (10 _x) and a _{(10 y) (TSW) (} 1 x) and space switches retrieved from _{(1 y) (SSW) (} 2 x) and (2 _y) Space switch side jumper housing (SJF)
This is the extraction processing of (5 _x ) and (5 _y ), and step S
14 is a jumper accommodating portion (SJF) on both space switch sides
(5 _x ) and (5 _y ) are in a free state, and it is a process of determining a time slot (TS _n ) in which an empty connection path can be selected. Step S15 is a jumper on the space switch side that has successfully selected an empty connection path. Housing (SJF) (5 _x ), (5
_y ) and a time slot (TS _n ) are transmitted to the line setting instructing unit (38), and step S18 is a space switch side jumper accommodation unit (SJF) (5 _x ) which is unsuccessful in selecting an empty connection path. And (5 _y ) to the block avoiding unit (37).

The line setting instructing section (38) identifies the space switch side jumper accommodating sections (SJF) (5 _x ) and (5 _y ) transmitted from the address searching section (35) and the time slot number (n = “1”), the network (NW) (20) is instructed to set the connection path, and a response indicating that the connection path specified by the network (NW) (20) is normally completed is returned. When returned, the corresponding connection information is stored in the line setting database (3D).

The block avoidance unit (37) is connected to the space switch side jumper accommodating unit (SJ) from the address searching unit (35).
F) When receiving (5 _x ) and (5 _y ), refer to the line setting database (3D), the line ratio database (3A) and the connection matrix database (3C).
In the process shown in (1), one of the space switch side jumper accommodating units (SJF) [for example (5 _x )] is searched for an empty time slot (TS _n ), and the detected time slot (TS _n ) is The connection path connected to the other space switch side jumper housing (SJF) [for example (5 _y )] in the closed state is connected to another time slot (TS _m ).
By relocating to the space switch side jumper accommodating section (SJF) (5 _x ) and (5 _y ) the connection path between which can be set to the time slot (TS _n ) Seeking, temporary line transfer table (3E)
The indexed line ratio (H ₂ ) designated by the maintenance person or the like is selected from the temporary line transfer table (3E) of each index number in the process shown in FIG. If the specified line ratio (H ₂ ) is not specified, the line temporary transfer table (3E) having the index number closest to the line setting ratio (H ₁ ) calculated from the current data is selected, and the selected line temporary is selected. Based on the movement table (3E), the line setting instruction unit (38) is instructed to perform the rearrangement process of the connection path being set on the network (NW) (20).

To summarize FIG. 9, step S22 is a process of excluding the connection path related to the communication line (10) to which the important flag (p) is added from the target of relocation, and steps S23 and S24 are This is a search process of a movable time slot (TS) [time slot number (n)], and steps S27 and S28 are movable time slot (TS) [time slot number (m)] and space switch side jumper accommodation. This is the number storage process of the copy (SJF) (5), and steps S2E and S2F are the setting process of the temporary movement value (see FIG. 7) in the temporary line movement table (3E).

Further, in summary of FIG. 10, step S32
, The corresponding term _[(H 3xy the line temporary moving table (3E) line setting the ratio of the [index number (I)] (H ₃₎ with the specified line ratio (H ₂₎ [or line setting ratio (H _1)] ) And (H _2xy ) or (H _2xy )], and steps S33 through S35 are
Temporary line transfer table (3) for each index number (I)
E) is a process for extracting the temporary line transfer table (3E) having the smallest index number (I), and step S36 is a process for adding the number of comparisons to the counter value.
Steps S37 to S3C are processes for repeatedly executing the above processes for all terms of the line setting ratio (H ₃ ).

The block avoiding unit (37) instructs the circuit setting of the movement pattern of the temporary circuit movement table (3E) having the largest index value from the temporary circuit movement table (3E) created as described above. To the section (38).

The line setting instructing section (38) causes the network (NW) (20) to set the corresponding connection path in the same process as described above, and when the processing is normally completed, the corresponding connection information is stored in the line setting database (3D). To store.

As is apparent from the above description, according to the present embodiment, the network control unit (CTL) (30) inputs the information of the connection path to be newly set from the man-machine interface unit (MMI) (40). Then, the line ratio database (3A), TS connection database (3B),
Refer to the connection matrix database (3C) and the line setting database (3D), try to select an empty connection path,
If a free connection path cannot be selected, the specified line ratio (H ₂ ) input from the man-machine interface (MMI) (40) or the line setting ratio (H ₁ ) calculated from the current condition is complied with. Try to relocate the connection path that is currently being set, select an empty connection path, and use the network (N
W) (20) can be instructed to be set, and the connection path associated with the communication line (10) in which the important flag (p) is set can be excluded from the relocation target.

2 to 10 are merely examples of the present invention until now, for example, a network control unit (CTL).
The configuration of (30) and the processing steps are not limited to those shown in the figure, and many other variations are considered,
In any case, the effect of the present invention does not change. Further, it goes without saying that the cross-connect device (100) targeted by the present invention is not limited to that shown in the drawings.

[0042]

As described above, according to the present invention, the setting of the specified connection path is automatically tried, and when the specified connection path cannot be selected, the specified future communication line extension tendency is complied with. Since the relocation is performed, the possibility of repeating invalid relocations is reduced, and the important communication lines are excluded from the relocation target, so that there is no risk of interrupting important communication due to the relocation, thus improving efficiency. It is possible to realize a highly-reliable and highly reliable cross-connect device.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a cross-connect device according to an embodiment of the present invention.

FIG. 3 is a network control unit in FIG.

FIG. 4 is a line ratio database in FIG.

5 is a TS connection database in FIG.

FIG. 6 is a connection matrix database in FIG.

FIG. 7 is a circuit temporary transfer table in FIG.

FIG. 8 is an address search process in FIG.

FIG. 9 is a process of creating a temporary line transfer table in FIG.

FIG. 10 is a block avoidance processing process in FIG.

[Explanation of symbols]

 1 time switch (TSW) 2 space switch (SSW) 3 line accommodation part (LIF) 4 time switch side jumper accommodation part (TJF) 5 space switch side jumper accommodation part (SJF) 6 jumper line 10 communication line 20 network (NW) 30 network control unit (CTL) 31 operator instruction receiving unit 32 address receiving unit 33 important line instruction receiving unit 34 TS connection searching unit 35 address searching unit 36 line transfer table creating unit 37 block avoiding unit 38 line setting instructing unit 3A Line ratio database 3B T-S connection database 3C connection matrix database 3D line setting database 3E line temporary transfer table 40 man-machine interface (MMI) 100 cross-connect device 101 connection path holding means 102 connection ratio holding means 103 connection path setting Means 104 connecting channel relocation means

Claims (3)

[Claims] 1. A time switch and a space switch are TS.
In a cross-connect device that connects communication lines to each other via a T-connected network, a connection path holding unit that holds information about a connection path currently set on the network, and a communication line specified from the outside. When a connection ratio holding unit that holds the connection ratio for each route and the connection ratio for each route that is currently set and a pair of communication lines to be connected are specified, refer to the connection information holding unit. Connection path setting means for selecting and setting an empty connection path by means of a free connection path, and a current setting indicated by the current connection information held by the connection information holding means when the connection path setting means cannot select an empty connection path. Rearrange the connection path in accordance with the specified connection ratio held by the connection ratio holding means,
A cross-connect device, comprising: a connection path rearrangement means capable of setting a desired empty connection path. 2. The connection path rearranging means, when the connection ratio holding means does not hold a connection ratio designated from the outside, for each route currently set by the connection ratio holding means. 2. The cross-connect device according to claim 1, wherein the cross-connect device is rearranged in accordance with the connection ratio. 3. The connection path rearranging means excludes the connection path related to the communication line designated as important from the relocation target when the connection path is rearranged. The cross-connect device described.