KR100233936B1 - Line dispersing method of a switching system - Google Patents

Abstract

The present invention relates to a method for redistributing extension on a switchboard cross-section board, in particular, when the station installation plan is changed after the installation of the cross-section board on the switchboard, the wire redistribution is performed for all facility plans up to the final capacity except the existing star cluster facilities. However, it is possible to easily calculate the internal dispersion plan that guarantees the maximum facility dispersion effect for new facility plans such as exchange exchange, exchange capacity change, final module number change, and dispersion rate change while maintaining the cluster status in the existing facility. By doing so, it is possible to solve the problem that an arbitrary arrangement according to the change of the facility plan does not allow efficient cross-section wiring operation due to mass production of a long-distance jumper.

Description

Extension method of extension of station on switchboard

The present invention relates to a method for redistributing an extension on a cross section of a switchboard, and in particular, as a systematic method for recalculating the result of the extension of the extension obtained through the distribution of the line on the cross section of the switchboard by changing the exchange installation plan. The present invention relates to a method for redistributing stations on a single-sided board so that it can be operated smoothly until the end of the year by arrangement.

In general, the internal distribution of the exchanger is applied to the internal station up to the final year before the cross-sectional wiring board is installed, and the result is that the internal wire is arranged at any position on the wiring board.

After the initial installation, it will take at least several years or 10 years to complete the deployment and accept the final modules. Therefore, the multi-planboard installation plan may be changed before the final year is reached. For example, the type of installation exchanger, the final capacity, the exchange installation order, etc. may be changed, or the final module may increase due to a sudden increase in demand.

When the above situation occurs, it is easy to arbitrarily arrange the facilities according to the change of the installation plan, and the arbitrary facility arrangements are not able to efficiently operate the cross-sectional wiring board by mass-producing long-distance jumpers. .

Therefore, the present invention systematically redistributes the internal dispersion of all facility plans up to the final capacity except the existing star cluster facilities in order to solve the above problems, to minimize the effect of the change in the facility plan and maximize the effect of facility dispersion. It is an object of the present invention to provide an internal separation method on the cross-sectional wiring of an exchanger capable of efficient operation on the cross-sectional wiring board.

1 is an embodiment of the extension method of the present invention, in which three exchangers are installed in the order of A, B, and C, and the dispersion is performed according to a predetermined dispersion ratio according to the capacity ratio of each of the installed exchangers. drawing.

FIG. 2 is a diagram showing a state in which a redistribution target area of the terminal capacity of the exchanger in FIG. 1 is set. FIG.

FIG. 3 is an internal dispersion according to the dispersion ratio 100% by applying the final capacity ratio (1: 1: 1) to three exchangers (B, D, and E) separately by separating the redistribution target areas of FIG. Figure.

4 is a view showing the results of converting the ratio for each module in consideration of the ratio of the redistribution portion in all modules.

FIG. 5 shows a state in which dispersion is performed by applying a 100% dispersion rate to three exchangers B, D, and E in an unsung terminal terminal region. FIG.

Table 1 shows examples of redispersion results.

In order to achieve the above object, the method for redistributing an extension on an exchanger cross-sectional wiring board of the present invention includes a star cluster in the installed exchanger, except for the redistribution target of the existing end cluster in the existing exchanger. Designating an unfinished uncommitted part as a commutation terminal terminal part, and distributing the exchanger extension of the distributed part of the installed exchanger that is not formed by a distribution rate of 100% over the newly defined exchanger terminal module. Designating the portion as an astral extension portion; Designating a region to be redistributed, which has not been decentralized; Separating the redistribution target area separately and independently performing extension dispersion according to a predetermined dispersion rate by applying an exchanger end capacity ratio to an uninstalled exchange; Dispersing the exchanger extension at a distribution ratio of 100% according to the ratio of the final capacity to the non-installed distribution target exchangers in the unsung terminal terminal portion, and reflecting each dispersion result obtained by the ratio on the matrix on the whole module It is characterized by consisting of the steps to organize.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, in order to better understand the technology of the present invention, some of the terms used in the present invention will be clarified as follows.

First, the exchange capacity means the functional capacity that each exchange can accommodate to the maximum, and the final capacity means the sum of all exchange capacity to be installed in the telephone station.

The final year is the time when the final capacity is reached through the extension process after establishing the telephone station. A module means a unit of a cross-section boarding structure and a final module means the total number of modules on a cross-sectional wiring board to accommodate the final capacity.

Figure 1 shows three exchangers installed in the order of A, B, and C until the final year, and the capacity is 100,000, 100,000, 50,000, respectively (capacity ratio = 2: 1: 1). The results are easy to understand.

On the other hand, it is shown that the extension module panel on the front surface of the cross-sectional wiring board for convenience of understanding. The numbers along the rows at the top of the figure show the number of modules, and the values along the columns represent the percentage of variance occupied by each exchange in the module.

In the figure, 4 modules are installed for 20 final modules, and about 70% of the terminal plates are in use (for reference, the modules and terminal plates are expanded as needed whenever the star demand occurs. 8 ~ 20 modules are not currently installed).

At this time, when part A of exchange A was formed and used up to 4 modules, when demand for forecast was increased due to the construction of large apartment complex, etc., the capacity of final exchange was 50,000. Suppose we have replaced two exchangers, D and E, each with a capacity of 100,000 each.

When the exchange capacity is changed, the capacity of China is increased to 150,000 lines and changed to 400,000, and assuming that there are 28 terminal modules for accommodating 400,000, the redistribution process is performed as follows.

That is, in the redistribution, the portions that have been previously formed and used are excluded from the redistribution target, and the parts that are not in the redistribution are included in the redistribution target.

Since exchange A has already been installed and the cluster has begun, installation should be made up to the final capacity of the exchange. Therefore, before the full redistribution is carried out, the unexposed part of the A exchange distribution part (a minor end extension part) is distributed over the newly defined terminal module (28 modules).

FIG. 2 is a diagram showing the result of distributing the unsung end extension portion of the distributed A exchange portion over the newly defined terminal module.

Referring to the drawings, a portion remaining undispersed afterwards is indicated by a redistribution target region (uninstalled exchange portion) and an uncomposed portion of an existing installed module as an unsung terminal plate portion.

FIG. 3 separates the redistribution target region of FIG. 2 separately and applies the final capacity ratio (1: 1: 1) to three exchangers B, D, and E to perform internal dispersion according to the designated dispersion ratio 100%. As a figure showing the state, the result of converting the ratio for each module in consideration of the ratio of the redistribution part in the whole module is shown.

Referring to the drawing, when the redistribution target region as shown in FIG. 2 is determined, the internal dispersion is performed by separating only the portion and using an existing distribution algorithm as it is. In other words, extrinsic dispersion is performed according to a specified dispersion ratio by applying a ratio of exchange terminal capacity, for example, (1: 1: 1), to B, D, and E exchangers. At this time, it can be arbitrarily set within the range of dispersion ratio (0 to 100%) for convenience of understanding, and was set to 100% in this embodiment.

4 is a view showing the results of converting the ratio for each module in consideration of the ratio of the redistribution portion of the entire module (78.2% in the example), Figure 5 is a non-sung terminal block area where the module is already Is a diagram showing the results of performing internal dispersion by applying 100% dispersion to the B, D, and E exchangers.

The result of extension redistribution is the recalculation of the dispersion result, and the form of the result is the same as that of extension. In other words, each module is represented by a distribution ratio of each exchange.

In the present invention, when the station installation plan is changed after the installation of the cross-sectional wiring board, the internal network redistribution is carried out for all facility plans up to the final capacity except the existing star cluster facilities, while maintaining the existing star cluster status as it is. In other words, it is possible to easily calculate the internal dispersion plan that guarantees maximum facility dispersion effect for exchange exchange, exchange capacity change, final module number change, and dispersion rate change. It is possible to solve the problem of not being able to operate the efficient cross-sectional wiring board by producing jumpers.

In addition, the present invention can propose an alternative to the change in the facility plan at the time of operation of the cross-sectional wiring board, it is possible to ensure that the cross-sectional wiring board can be operated smoothly in the event of changes in the facility plan to play a role in terms of economic efficiency. This is big.

Claims (2)

The method of redistributing the station on the cross-section board that recalculates the results of the station dispersion on the switch-side cross-section board calculated at the beginning of the facility plan to reflect the change in the plan of the facility, such as changing the installation order of the exchange, changing the model, and eventually increasing the number of modules. In the present invention, the step of designating the star cluster portion of the installed exchange is completed but not completed, except for the pre-distribution target portion of the existing exchange cluster is completed, the designation of the uncommitted terminal portion as an unsung terminal plate portion, Distributing the exchanger extension of the distributed portion of the installed exchanger that is not formed by the cluster at a dispersion ratio of 100% over the newly defined exchanger termination module, and designating the portion as an unstarred extension portion; Designating a region to be redistributed, which has not been decentralized; Separating the redistribution target area separately and independently performing extension dispersion according to a predetermined dispersion rate by applying an exchanger end capacity ratio to an uninstalled exchange; Dispersing the exchanger extension at a distribution ratio of 100% according to the ratio of final capacity to the unsuccessful distributed target exchangers in the unsung terminal terminal portion, and reflecting the respective dispersion results obtained by the separation in the matrix by the ratio on the matrix Extension redistribution method on the cross-sectional switchboard of the exchanger, characterized in that consisting of. 2. The method of claim 1, wherein the predetermined predetermined dispersion ratio in the region to be redistributed is in a range of 0 to 100%.