KR100233092B1 - Space switch with switching capacity of stm-1*n in full electronic exchange system - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

Space-switching switch device of an electronic exchanger.

I. The technical problem to be solved by the invention

The space division switch device of the electronic switching unit switches all channels of the synchronous transmission mode standard frame received from the subscriber matching device.

All. Summary of Solution of the Invention

The space division switch device of the all-electronic switch has a control memory of the same size as the synchronous transmission mode standard channel capacity, and uses the accompanying clock as the synchronous transmission mode standard parallel clock to provide all channels provided by the synchronous transmission mode standard. Configure to switch.

la. Important uses of the invention

It is used for a switch device of an electronic exchanger.

Description

Space Division Switching Device of Electronic Switching System for Switching All Channels in Synchronous Transmission Mode

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switch device of an electrical exchanger, and more particularly to a space division switch device.

1 is a block diagram of a general electronic exchanger.

In the electronic switch, a plurality of time division switch devices 111a-111n for accommodating subscribers of a predetermined capacity are connected to one space division switch device 112, and the space division switch device 112 exchanges data with the time division switch devices 111, 113. By constructing a large capacity electronic exchanger.

In the electronic switch according to the above configuration, subscriber telephone channel data (64 Kbps) having a predetermined capacity is input to the time division switching device 111 and connected to the space division switching device 112 through time division switching, aggregation, and multiplexing. The entire channel unit transmitted from the device 111 to the space division switch device 112 is referred to as a highway.

Here, there are two methods of transmission for the highway, and the first method is a method of accessing the spatial division switch device 112 with the number of subscriber telephone channels connected to be 2 ¹⁰ (1,024 channels) or 2 ¹¹ (2,048 channels). . If the channel is assumed to be 2,048 channels, the transmission speed between the time division switch device 111 and the space division switch device 112 becomes 131,072 Mbps (64 Kbps * 2,048 channels). 16.384 Mbps (131.072 Mbps / 8bit).

The second method is to connect the time division switch device 111 and the space division switch device 112 using the standard STM-1 (synchronous transfer mode; 155.520 Mbps) method. The total number of channels in the STM-1 is 2,430 (9 * 270), but the number of purely transmittable channels excluding the overhead used during transmission is 2,340 (9 * 260).

However, when the time division switch device 111 and the space division switch device 112 are connected by the second method, when 155.520 Mbps data is input to the space division switch device 112, the space division switch device 112 processes only the existing 2,048 channels of the internal circuit itself. Since the parallel-converted 19.44Mbps * 8bit (2,430 channels) is converted to 16.384Mbps * 8bit (2,048 channels), the partitioned switching is performed.

Hereinafter, the operation of the space division switch device according to the related art will be described in detail with reference to the accompanying drawings.

2 is a view for explaining the configuration of a space split switch device according to the prior art.

As shown in FIG. 2, the space division switch device 112 includes an STM-transmitter / receiver 213 and 217, a clock synchronizer 212, a control memory 215, and a highway selector 216.

That is, the space division switch device 112 receives a 16.384 MHz clock from the network synchronizer 114 and uses it as an internal clock of the space division switch device 112, and 155.520 for transmitting and receiving STM-1 (synchronous transmission mode) data with the time division switch device 111. The clock synchronization unit 212 which generates a clock of / 8 MHz (19.44 MHz) is incorporated.

Therefore, when 64Kbps data is transmitted from the subscriber to the payload of the STM-1 frame through primary time division switching, aggregation, and multiplexing, that is, the rate is converted to 155.520 Mbps, and then transmitted to the space division switch device 112, the space division is performed. The switch device 112 processes this by converting the speed back to 2048 channel speed.

In other words, the conventional space division switch device 112 can process only 2,048 channels, and thus requires a separate 16.384 MHz clock. That is, 16.384 Mbps data is converted to 19.44 Mbps data for conversion to STM-1, and then back to 16.384 Mbps data for function at the space division switch device 112, and converted to 19.44 Mbps when sent to the time division switch device 111 again. When the time division switch device 112 is delivered from the subscriber to the subscriber, the conversion process is performed again.

Therefore, in the conventional electronic switch, since the data rate conversion is performed several times including each data rate conversion at the input / output stage of the space division switch device 112, the hardware required is complicated and the error probability is high during data transmission.

In addition, when the electronic switch performs the exchange function through the time division switch device 111-the space division switch device 112-the time division switch device 111, the exchange capacity of the time division switch device 111 is changed to all channels (2,048 channels 9) of the STM-1 frame. 260), even though it is configured to accommodate the above, due to capacity constraints in the space division switch device 112, it is necessary to use 2,048 channels. Due to these problems, a space division switch device 112 capable of switching the STM-1 payload (2,340) channel is required. However, if the configuration of the space division switch device 112 is to be replaced only 2340, another separate clock frequency is required, so it is necessary to configure the space division switch device 112 to exchange all the 2,430 channels of all STM-1 channels. It is economical.

In addition, in the conventional space division switch apparatus 112, an empty channel is searched for an arbitrary path test during on-line, and after transmitting an arbitrary test data pattern to the corresponding channel, the data fed back from the space division switch apparatus 112 Comparison was made with the route test. This path test method does not significantly affect the device itself when the call traffic pack in the space split switch device 112 is small. However, the space split switch device 112 must be allocated for several path tests in a state where the call traffic is very large. There was a drawback to weighting the device.

Accordingly, an object of the present invention is to provide a device capable of processing all channels of standard STM-1 in a space division switch device of an all-electronic exchange.

Another object of the present invention is to provide an apparatus capable of eliminating data rate conversion at an input / output end of a space division switch device of an all-electronic exchange.

It is still another object of the present invention to provide an apparatus capable of performing a path test and maintenance of a space splitting switch device using an STM-1 overhead channel in a space splitting switch device of an electrical exchanger.

In order to achieve the above objects, a space division switch device of an electronic switching system includes: a space division switch control device for controlling the overall operation of the space division switch device; and parallelization of the synchronous transmission mode standard data received from the time division switch device without speed conversion. A synchronous transmission mode receiver for transmitting the data to the highway selector, a control memory for receiving and storing an address and control data from the space division switch controller, and outputting a highway selection signal for each channel, and receiving a plurality of highway data A plurality of highway selectors for performing spatial division switching on a channel basis under the control of the control memory, and synchronous transmission for converting frame parallel data received from the highway selector according to a synchronous transmission mode standard frame and transmitting them to a time division switch device. A mode transmitter, A clock synchronization unit for receiving a system synchronization clock from the synchronization unit, generating a synchronous transmission mode standard parallel clock, and distributing the synchronous transmission mode transmission / reception unit and highway selection unit; and a test data pattern under the control of the space division switch controller. And a test data generator for inserting the synchronous transmission mode into an overhead channel and sending it to the highway selector and checking whether a path error occurs in the space split switch device as compared with the data output after performing the space division switching of the highway selector. It is characterized by.

1 is a block diagram of a general electronic switch.

Figure 2 is a block diagram of a space division switch device according to the prior art.

Figure 3 is a block diagram of the STM-1 transmitter / receiver of the spatial division switch device according to the prior art.

4 shows a typical STM-1 frame structure.

FIG. 5 is a diagram illustrating an example of using a channel of an STM-1 frame in a conventional space division switch device. FIG.

Figure 6 is a block diagram of a space division switch device according to the present invention.

Figure 7 is a block diagram of the STM-1 transmitter / receiver of the space division switch device according to the present invention.

8 is a view showing an example of using a channel of the STM-1 frame in the space division switch device according to the present invention.

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

First, in adding reference numerals to the components of each drawing, the same components have the same reference numerals as much as possible even if they are displayed on different drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

4 shows a standard STM-1 frame structure.

Referring to FIG. 4, the STM-1 frame includes 2,430 channels, 90 overhead channels, and 2,340 payload channels.

FIG. 5 is a diagram illustrating an example of using an STM-1 frame channel in a conventional space division switch device. Referring to FIG.

Referring to FIG. 5, there are 382 unused channels, and 2,048 channels substantially carrying user data. Therefore, in the related art, the space division switch device 112 only needs to switch the 2,048 channels, and accordingly, a separate clock is required.

6 is a block diagram of a space division switch device according to an embodiment of the present invention.

The space division switch device 112,

Multiple STM-1 (Synchronous Transmission Mode) transceivers 612a converting 155.520 Mbps STM-1 data received from the time division switching device 111 into parallelized 19.44 Mbps * 8-bit data without speed conversion and transmitting it to the highway selector 615 -612n),

A plurality of control memories 614a to 614n for receiving and storing address and control data from the space division switch controller 115 and outputting a highway selection signal in units of channels;

A plurality of highway selectors 615a-615n for receiving highway data from the synchronous transmission mode transmitter and performing a switching function in units of 64 Kbps channels under the control of the control memory 611;

A synchronous transmission mode transmission unit for converting the frame parallel data 19.44 Mbps * 8 bit data received from the highway selector 615 according to the synchronous transmission mode standard frame and transmitting the same to the time division switch device 113;

Receives a 16.384 MHz system synchronization clock from the network synchronizer 114, generates a 19.44 MHz clock as the switch device synchronization clock, and distributes the clock to the STM-1 transmitter / receiver 612/617 and the highway selector 615, respectively. With donation 611,

Generate a random test data pattern under the control of the space division switch control device, insert it into the synchronous transmission mode overhead channel, send it to the highway selection unit 615, and compare the data with the output data after performing the switching function of the highway selection unit 615. 112 consists of a test data generator 613 that checks for a path error.

Referring to the operation based on the configuration of FIG. 6, the STM-1 receiver 612 receives 155.520 Mbps of data from the time division switch device 111 and transmits the data to the highway selector 615 at 19.44 Mbps via serial / parallel conversion. do. The highway selector 615 receives the 19.44 Mbps data, selects a channel according to the highway select signal of the control memory 614, and transmits the channel to the STM-1 transmitter. The STM-1 transmitter converts 19.44 Mbps received from the highway selector 615 to 155.520 Mbps again through parallel / serial conversion and transmits the same to the time division switch device 113.

7 is a detailed configuration diagram of the STM-1 transmitting / receiving unit of the space division switch device according to the embodiment of the present invention.

The STM-1 transmitter / receiver receives the 155.520 Mbps STM-1 signal from the time division switch device 111, synchronizes the clock frame, and converts the 19.44 Mbps data to the highway selector 615 for transmission to the highway selector 615; It is divided into STM-1 transmitter 617 which receives 19.44Mbps data from 615 and changes it to STM-1 standard and transmits it to time division switch device 111.

The STM-1 receiver 612 includes a frame synchronization extractor 711, a bit clock recovery unit 712, a serial / parallel converter 713, an STM-1 overhead processor 714, and a sleep buffer 715. 617 includes a highway data selector 716, an STM-1 overhead inserter 717, and a bottle / serial converter 718.

6 and 7, the frame synchronization extracting unit 711 and the bit clock recovery unit 712 transmit 155.520 Mbps (2,430 channel) data input from the time division switch device 111 from a data sequence to a 155.520 MHz clock and a frame synchronization signal. After extracting the output to the serial / parallel conversion unit 713. The serial / parallel conversion unit 713 converts the extracted signals into 19.44 Mbps data in parallel and outputs them to the STM-1 overhead processing unit 714. The STM-1 overhead processing unit 714 provides various maintenance data of STM-1. To handle the overhead of the STM-1 frame. The sleep buffer 715 inputs the frame overhead processed data to compensate for the phase difference between the extracted clock and the clock phase difference received from the network device, and then outputs the result to the highway selector 615.

Accordingly, 19.44 Mbps of data passing through the sleep buffer 715 is transmitted to the highway selection unit 615 to perform spatial division switching. Here, since the space division switch device 112 according to the present invention uses only 19.44 Mbps data, it is not necessary to convert the data into 16.384 Mbps data as compared with the related art.

That is, when 19.44 Mbps of data passing through the STM-1 receiver 612 is input to the highway selector 615, one highway is selected for each channel according to the selection signal of the control memory 614 input in synchronization with 2,430 channels. Space division switching is achieved. In other words, arbitrary data from the space division switch control device 115 is stored in a specific address of the control memory 614, and a selection signal is output to the selection unit 615 to perform space division switching.

For example, if data from the input highway (IHW) 7 is to be output to channel 240 of the output highway 3 (OHW) 3, the address 240 of the control memory 3 614c is " 0000 0111 " The highway selection signal is input to the selection circuit 3 615c, and the selection circuit selects and outputs data input from the highway 7 to the corresponding channel of the highway 3 by the selection signal.

The 2,430 channels of data switched through the highway selector 615 are input to the STM-1 transmitter 617, and the number of data units input to one STM-1 transmitter 615 depends on the number of switching highways of the SPL 112. Different. That is, when the basic space division switch module is 8 * 8 (based on 155.520 Mbps ports) as in the application example of the present invention, if the number of ports requiring switching is 9 or more, the number of highways input to one STM-1 receiver 617 is 2 More than

That is, the data obtained by the spatial division switching in the highway selector 615 are input to the corresponding STM-1 transmitter 617, respectively. The highway data selector 716 of the STM-1 transmitter 617 selects data containing valid data among a plurality of highways for each channel and outputs the data to the STM-1 overhead inserter 717. The STM-1 overhead inserting unit 717 inserts the overhead necessary for STM-1 transmission and outputs it to the bottle / serial converting unit 718, and the bottle / serial converting unit 718 inserts the overhead. The data is serially converted and output to the time division switch device 111.

When the space division switch device 112 is implemented as described above, even when the space division switch device 112 is in use, it is possible to check whether the normal operation is performed on a specific path of the space division switch device 112. That is, although the space division switch device 112 has a switching capacity of 2,430 channels, it is not necessary to switch to the channel corresponding to the overhead of the actual STM-1 frame. In addition, it is possible to check on-line whether the data path is abnormal by inserting an arbitrary data pattern in a specific channel and comparing the output data after switching.

As described above, in the present invention, since the space division switch device uses only a single clock of 19,44 MHz, the speed of the subscriber telephone channel data (19.44 Mbps <-> 16.384 Mbps) is not required, and thus the hardware required for the conventional method (H / W) is economical, and service quality is improved.

In addition, all payload channels provided by the STM-1 can be switched in the space-switched switch, enabling more efficient use of the data path between the time-switched and space-switched switch devices (292 channels per highway than the traditional method). Increase), in terms of all-electronic switching system, there is an effect of increasing the number of subscribers connected under the same hardware and the same aggregation cost.

In addition, by using the overhead channel that is not used as a data channel during on-line, it is possible to test channel by channel of the space division switch device during operation. It is possible.

Claims (3)

In the space division switch device of an electronic exchanger, And a control memory having the same size as the synchronous transmission mode standard channel capacity, and using the accompanying synchronous clock as the synchronous transmission mode standard parallel clock, so that all channels provided by the synchronous transmission mode standard are switched. Space division switch device for electronic switching system for standard full channel switching in synchronous transmission mode. In the space division switch device of the electrical exchanger, A space dividing switch control device for controlling the overall operation of the space dividing switch device; A synchronous transmission mode receiving unit for transmitting the synchronous transmission mode standard data received from the time division switching device to the highway selector as parallelized data without speed conversion; A control memory for receiving an address and control data from the space division switch controller and storing the highway selection signal in units of channels; A plurality of highway selectors which receive a plurality of synchronous transmission mode highway data from the synchronous transmission mode receiver and perform a switching function on a channel basis under the control of the control memory; A synchronous transmission mode transmitter for converting the frame parallel data received from the highway selector according to the synchronous transmission mode standard frame and transmitting the converted frame parallel data to a time division switch device; Receiving a system synchronization clock from a network synchronizer device to generate a synchronous transmission mode standard parallel clock, the clock synchronization unit for distribution to the synchronous transmission mode transceiver and the highway selector, etc. Space-switching switch device of an electronic exchanger. The method of claim 2, Under the control of the space division switch controller, An arbitrary test data pattern is generated and inserted into the synchronous transmission mode overhead channel and sent to the highway selector. After performing the space division switching, the data is compared with the output data. And a test data generator for checking whether a path error has occurred.

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