KR100464148B1 - Control method of devices at the switching system - Google Patents

Abstract

The present invention relates to a device control method at an exchange.

In a conventional exchange, when a device transmits and receives data through a sub highway, each device transmits and receives data through an individual sub highway or transmits and receives data by using a predetermined channel provided in the sub highway. Therefore, a plurality of devices can not actually share a single sub-highway, and if the number of devices increases, additional sub-highways need to be added, which requires a lot of physical resources and allocates switching resources accordingly. Therefore, there is a problem in that the system density is lowered and the system manufacturing cost is increased.

According to the present invention, it is possible to allow a plurality of devices to substantially share a single sub highway, thereby saving sub highways and switching resources, and saving physical installation space of an exchange system rack. It can increase the integration level and reduce the system manufacturing cost. In addition, even if the function of the device is different, it can be bundled into one sub highway, so that it is easy to control without switching, and there is an additional effect of simplifying the switching procedure according to the flow of the call.

Description

Control method of devices at the switching system

BACKGROUND OF THE INVENTION The present invention relates to an exchanger, and in particular, a plurality of devices share one subhighway in common, thereby saving the subhighway and thus switching resources in the exchange, thereby improving system integration and reducing manufacturing costs and installation space. It relates to a device control method in.

In general, there are a plurality of devices inside the exchange, where each device performs its own function as it transmits and receives data through sub-highways.

When devices provided in the conventional exchange transmit and receive data through the sub highways, as shown in FIG. 1, each device 11 and 14 uses individual sub highways 12 and 15. To transmit and receive data. That is, the devices 11 and 14 are devices for specific functions to be mounted in the exchange system, and the respective sub highways 12 and 15 are connected to each device 11 and 14 to operate the device controller 10. In response to the instruction, a large amount of data is transmitted and received through the sub highways 12 and 15, and the sub highways 12 and 15 are provided with a plurality of channels for transmitting and receiving data. The PCM conversion card 13 or 16 is connected between the sub highways 12 and 15 and the time switch 17 to convert the type of data transmitted and received, but the data applied from the time switch 17. Is converted into PCM data and sent to the sub highways 12 and 15, and the PCM type data applied from the sub highways 12 and 15 is converted into data of a type that can be processed by the time switch 17. In addition, the time switch 17 switches data input / output through the PCM conversion card 13 (16).

As described above, since the devices 11 and 14 of the conventional exchange shown in FIG. 1 transmit and receive data by using exclusively the sub highways 12 and 15 connected individually, the devices 11 and 14 corresponding to the number of devices are corresponding to each other. Due to the number of sub highways, physical resources are consumed, and switching resources are allocated accordingly, thereby degrading system integration and increasing system manufacturing cost.

In order to solve such a problem, as shown in FIG. 2, a method of allowing data communication by connecting a plurality of devices 21 to 23 to one sub highway 24 has been proposed. That is, the devices 21 to 23 are devices for specific functions to be mounted in the exchange system, and one sub highway 24 is connected to each device 21 to 23 to operate according to the operation instruction of the device control unit 20. By transmitting and receiving data through the corresponding sub highway 24, each device 21 to 23 uses a predetermined channel exclusively among a plurality of channels provided in the sub highway 24 to transmit data through the corresponding channel. Send and receive data.

As described above, although the devices 21 to 23 of the conventional exchange shown in Fig. 2 externally use one sub highway 25 to transmit and receive data, a predetermined portion of the sub highway 25 is provided. Since data is transmitted and received using a channel exclusively, a plurality of devices do not actually share a subhighway. When the number of devices increases, additional subhighways need to be added, which requires a lot of physical resources. Due to the need to allocate switching resources, there is a problem in that the system density is lowered and the system manufacturing cost is increased.

The present invention is to solve the problems described above, the object is, when the device transmits and receives data through the sub-highway in the exchange, each device transmits data using one sub-highway in common By receiving, it saves the sub-highway and the switching resources accordingly in the exchange to improve the system integration and reduce the manufacturing cost and the installation space.

1 is a block diagram illustrating a case where a device uses individual sub highways in a conventional exchange.

2 is a block diagram illustrating a case where a plurality of devices are connected to one subhighway in a conventional exchange.

3 is a block diagram illustrating the manner in which multiple devices use a common sub highway in an exchange in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

11, 14, 21-23, DV1-DVn: device,

12, 15, 24, 33: subhighway,

13, 16, 25, 34: PCM (pulse code modulation) conversion card,

10, 20, 31: device control unit,

32: channel status database,

30: upper processor,

17, 26, 35: time switch,

In order to achieve the above object, the present invention provides a method for controlling a device in a switch, the method comprising: recording channel state information indicating whether a device uses a channel of a sub highway in a channel state database of a device controller; and; When the channel use request of another device is generated while the device uses the channel of the sub highway, the device controller determines that the channel is in use from a channel state database to prevent another device from using the channel of the sub highway. and; When the channel usage request of another device is generated while the device terminates the channel of the sub highway, the device controller confirms that the channel is not in use from the channel state database and uses the channel of the sub highway to another device. Characterized in that it comprises a process.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, when the device of the exchange transmits / receives data through the sub highways, it is as shown in FIG. That is, a plurality of devices DV1 to DVn transmit and receive data using one sub highway 33, but occupy the sub highway 33 under the control of the device controller 31 to transmit and receive data. Thus, one sub highway 33 is used in common. The device controller 31 controls the data transmission and reception of the devices DV1 to DVn by controlling the use of the sub highways 33 for the plurality of devices DV1 to DVn in response to a request from the upper processor 30. In addition, the channel state database 32 is provided therein, and the channel state of the sub highway 33 is recorded in the channel state database 32, and the information recorded in the channel state database 32 is recorded. By controlling the use of the sub highway channels for the devices DV1 to DVn, the devices DV1 to DVn use the sub highway 33 in common. In addition, whenever the channel usage state of the sub highway 33 is changed, the device controller 31 changes and records the corresponding channel usage state in the channel state database 32.

When the device controller 31 allows a plurality of devices DV1 to DVn to use the channel of the sub highway 33, only one device should use the channel. For example, if one device DV1 of the plurality of devices DV1 to DVn uses only the channel in the transmission direction and the other device DV2 uses only the channel in the reception direction, the separate control according to this is It is not necessary. However, when most of the devices DV1 to DVn constituting the exchange perform the maintenance function, the transmission / reception bidirectional channel of the sub highway 33 should be used. In this case, the device controller 31 may use a plurality of devices ( One Taiwan sub highway 33 can be used in the DV1 to DVn.

The operation of the present invention having the structure and function as described above will be described with reference to FIG. 3. When the device controller 31 is authorized to use the sub highway 33 for the devices DV1 to DVn from the upper processor 30, the device controller 31 opens the internal channel state database 32. It checks whether the channel of the sub highway 33 is available. For example, if the device DV1 is using the channel, the timer is activated to make the channel available after a certain time, or other information is not available. Transmit to devices DV2 to DVn.

For example, when one device DV1 uses a channel of the sub highway 33 and a channel use request of another device DV2 to DVn occurs, the device control unit 31 using the channel is used. Status information indicating that the device DV1 is in use is written to the channel status database 32, and other devices DV2 to DVn cannot use the channel of the sub highway 33. Thereafter, when the device DV1 finishes using the channel of the sub highway 33, the device controller 31 records the channel state information in the channel state database 32 indicating that the channel of the sub highway 33 is not in use. To enable it and allow other devices to use sub-highway 33.

When the devices DV1 to DVn use the channel of the sub highway 33 only in a certain direction, the data transmission and reception modes of the devices DV1 to DVn can be maintained only in the direction in which they are mainly used. For example, if one device DV1 has a 90% utilization rate in the data transmission direction, the device DV1 mainly uses the transmission channel of the sub highway 33, but the other device DV2 to DVn does not use the device DV1. When a request for channel usage for a channel is received, when there is no channel usage of the device DV1, the channel of the sub highway 33 is used for the device for which the channel usage is requested.

In addition, when each device is distributed and the device control unit is separately configured for each device, an independent channel state database is placed in each device control unit, and signals received from the upper processor 30 are simultaneously received by each device control unit. By receiving the transmission and maintaining each channel state database in the same state, each device controller checks the channel state of the subhighway to control channel usage.

As described above, the channel state database 32 records and stores channel state information of the sub highway 33 connected to each of the devices DV1 to DVn, and the device control unit 31 stores the channel state database 32. By controlling the use of the sub highways 33 in the devices DV1 to DVn according to the information, the plurality of devices DV1 to DVn use one sub highway 33 in common at the exchange.

In addition, the embodiment according to the present invention is not limited to the above, and those skilled in the art will be able to carry out various modifications and changes of the present invention within the obvious scope. Such modifications and variations are intended to fall within the technical scope of the present invention.

As described above, according to the present invention, since it is possible to allow a plurality of devices to substantially share a single sub highway, it is possible to save the sub highway and switching resources, and to reduce the physical installation space of the exchange system rack. It can save money, increase system density, and reduce system manufacturing costs. In addition, even if the function of the device is different, it can be bundled into one sub highway, so that it is easy to control without switching, and there is an additional effect of simplifying the switching procedure according to the flow of the call.

Claims (3)

In the device control method at the exchange, Recording channel state information indicating whether a device uses a channel of a sub highway in a channel state database of a device controller; When the channel use request of another device is generated while the device uses the channel of the sub highway, the device controller determines that the channel is in use from a channel state database to prevent another device from using the channel of the sub highway. and; When the channel usage request of another device is generated while the device terminates the channel of the sub highway, the device controller confirms that the channel is not in use from the channel state database and uses the channel of the sub highway to another device. Device control method in a switch comprising the step of. The method of claim 1, When the channel of the sub highway is in use, operating the timer to make the channel available after a certain time, or notifying that the channel is not available. The method of claim 2, When the devices are distributed and a device control unit is separately configured for each device, an independent channel state database is placed in each device control unit, and the channel state database of each device control unit is kept in the same state. And controlling the channel use of the device by checking a channel state of the sub highway from its channel state database.