KR20000047176A - Interface board tester for wll system - Google Patents

Abstract

PURPOSE: An interface board tester for the WLL(Wireless Local Loop) system is provided to confirm whether an interface board connected with a radio port and an interface board connected with an exchange are operated normally in a radio port controller. CONSTITUTION: An interface board tester(70) comprises a control board(701), a plurality of testing boards(702), a synchronization generation board(703) and a clock generation board(704). The control board(701) carries out overall control operation. The synchronization generation board(703) provides operation clocks to each testing board(702). The clock generation board(704) generates a required clock signal of 4 megahertz or 16 megahertz. A monitoring device(71) sends input information to test the testing boards(702) mounted in the interface board tester(70) and monitors output results of the testing boards(702).

Description

Relay board tester for wireless subscriber network system

The present invention relates to a board test apparatus for a wireless local loop (WLL) system, and more particularly, to check whether a relay board coupled to a base station and a relay board coupled to an exchange are operating normally in a base station controller. The present invention relates to a relay board test apparatus for a subscriber network system.

In general, in the case of a PSTN network or an Internet network, since the wired network is configured, in order to provide a communication service to a specific subscriber, it is necessary to combine the communication network and the subscriber through a wire. However, if the subscribers are located in a mountainous area or the like, combining the subscribers by wires will cause a great economic loss.

Therefore, recently, a so-called wireless subscriber network system for wirelessly coupling a specific subscriber to a wired network such as a PSTN network has been developed and spread.

1 is a block diagram showing the configuration of a general wireless subscriber network system currently commercialized.

In FIG. 1, reference numeral 1 denotes a subscriber access device for coupling a specific subscriber, which is capable of combining various communication terminals such as a telephone device 2 and a facsimile 3 and a personal computer 4, and also a part thereof. In the case of a subscriber access device, there is also a structure configured to connect an ISDN terminal.

In the drawing, reference numeral 5 denotes a base station which is coupled to the subscriber access device 1 by radio to provide a wireless communication line to the subscriber access device 1, which is connected to the subscriber access device 1 in a CDMA manner. To be combined. In addition, each base station 5 is able to accommodate a total of 80 channels, for example, to provide a communication channel to at least 64 subscriber access devices 1 simultaneously.

In the drawing, reference numeral 6 denotes a base station controller which performs a control process such as controlling a wireless subscriber network system and providing a communication channel to each subscriber access device, for example, 16 base stations (5 _{1 to} 5 _16). It is configured to accommodate). In addition, the base station controller 6 is coupled to the base station 5 through the E1 link and the LAPD protocol, and the PSTN network and the Internet through the WLL gateway 7 and the data communication matching device 8. It is coupled to the packet network.

In addition, in the base station controller 6, the section combined with the base station and the section combined with the WLL gateway 7 or the data communication matching device 8 are differently provided with their operation clocks according to the apparatus adjacent to the corresponding section. Will be.

For example, the relay board connected to the base station is operated with an operating clock of 4 MHz, while the relay board coupled with the WLL gateway 7 is operated with an operating clock of 16 MHz.

However, in the conventional test apparatus, the operation clock to be applied is set to one clock and is fixedly applied. Therefore, the operation clock is only used to test the other boards except for the operation clock of the relay board as described above. Of course, it is necessary to provide a plurality of test apparatuses according to the above, and it is cumbersome to perform the same test procedure several times according to the operation clock.

Accordingly, the present invention was created in view of the above circumstances, and it is possible to test all of the relay boards having different operation clocks at the same time and having the same configuration through one test equipment. The purpose is to provide.

1 is a system configuration diagram showing a schematic configuration of a general wireless subscriber network system.

Figure 2 is a block diagram showing the internal configuration of a base station controller to which the present invention is applied.

Figure 3 schematically shows the appearance of the test apparatus according to the present invention.

4 is a functionally separated view of the device shown in FIG. 3;

*** Explanation of symbols for the main parts of the drawing ***

70: test apparatus, 701: control board,

702: test board, 703: synchronous generation board,

704: clock generation board, 71: monitoring device,

72: clock information storage unit.

In the relay board test apparatus for a wireless subscriber network system according to the present invention for realizing the above object, the subscriber matching device and the base station are wirelessly coupled, the base station and the base station control period, the base station controller and the exchange period are combined into E1, In the wireless subscriber network system coupled to the E1 and performing a relay function, the board is provided to be identical to the operation clock of the device coupled to the board. The slot information of the test board, the operation clock information of the corresponding slot, and the test data In addition to the control means for monitoring the output result from the test board, the control means for controlling to provide an operation clock set in the corresponding test slot based on the test slot information applied from the monitoring means, from the control means Clock generation means for generating a clock based on a predetermined control signal applied; And a synchronizing generating means for controlling to output a clock applied from the clock generating means to a corresponding test board based on a positive control signal, and generating a synchronizing signal based on the generated clock. The output terminal of is characterized in that connected in series with the input terminal of each test board.

That is, according to the above, by automatically adjusting the operation clock of the board to be tested and individually applying to the corresponding test board, it is possible to easily test a plurality of test boards with different operation clocks with the same board with one device. Will be.

Next, an embodiment according to the present invention will be described with reference to the accompanying drawings.

2 is a block diagram showing an internal configuration of a base station controller to which the present invention is applied.

In the figure, reference numeral 61 denotes a base station connection unit for interface with a base station, which converts each channel input through the transcoder 62, which will be described later, into an E1 data type of 2.048 MHz and transmits the same to the base station. The data input from the base station is transmitted to the transcoder 62 based on the predetermined control signal.

In addition, reference numeral 62 denotes a transcoder that performs a function of compressing / extending the input data and canceling echo of voice data, which operates in a 4MHz operation clock.

Reference numeral 63 denotes a relay line matching device 64, that is, a switch side or a signal generator, which will be described later on the data input from the transcoder 62, that is, the data transmitted from the base station side, based on a predetermined control signal. In addition to switching to (66), as a time switching unit for transmitting the data input from the relay line matching device 64 to the transcoder 62 or the signal generator 66, it operates in a 16MHz operation clock .

In addition, reference numeral 64 is a relay line matching device for connection with a switch to be connected to the wireless subscriber network system, which converts the data received from the time switching unit 63 into an E1 frame structure and transmits it to the switch side. The clock is extracted from the data applied from the exchange side, and the state information of the received data is detected.

On the other hand, reference numeral 65 denotes a clock signal based on data applied from the relay line matching device 64, and a network synchronizer 66 for applying the clock signal to the base station and the base station controller, 66 based on a predetermined control signal. A signal generator for transmitting a multi-frequency, DTMF tone signal to each channel of the time switch 63, and detecting a DTMF, fax modem signal, etc. applied from the time switch 63. Hereinafter referred to as VSU).

Reference numeral 67 denotes a main processor that controls the overall operation of the base station controller 60 based on a control command input from a base station operating apparatus (not shown), and reference numeral 68 denotes the main controller via an IPC channel. A processor interface IPCU (Inter Processor Communication Unit) for data transmission and reception between a processor 67 and a processor in each device of the base station controller 60.

On the other hand, Figure 3 is a view showing the hardware configuration of the relay test apparatus according to the present invention.

In FIG. 3, reference numeral 70 denotes a schematic appearance of a test apparatus according to the present invention. The test apparatus includes a single shelf, a control board 701 for performing an overall control operation, and a plurality of test boards. 702, a synchronization generating board 703 for providing an operation clock to each test board, and a clock generating board 704 for generating predetermined clock signals, for example, clock signals of 4 MHz and 16 MHz, are mounted.

Here, the test board 702 is a relay board constituting the base station connecting portion 61 and the relay line matching device 64 shown in Figure 2, the base station connecting board 61 is a transcoder 63 connected adjacent thereto Since the operation clock of the base station access board 61 is also 4MHz, the operation clock of the time switch unit 63 connected to and adjacent to the relay line matching board 64 is 16MHz. The operating clock of the board 64 is also 16 MHz.

On the other hand, reference numeral 71 is a monitoring device for transmitting the input information for testing the test board 702 mounted on the test device 70, and monitors the output result of the test board 702.

Next, the operation of the above configuration will be described with reference to the drawings shown in FIG.

4 is a functionally separated view of the test apparatus shown in FIG.

First, the test tube designates a slot in which the test board is to be mounted in the test apparatus 70, and sets an operation clock of the designated slot in advance. For example, the test board may include slots 3 to 12 of the test apparatus 70. In addition to setting the slots to be mounted, slots 3 to 7 are applied with a 4 MHz operating clock, and slots 8 to 12 are provided with a 16 MHz operating clock to monitor the clock information of the test slot and the test slot. 71 is applied to the control board 701 of the test apparatus 70.

Subsequently, the control board 701 stores the clock information of the test slot and the test slot applied from the monitoring device 71 in the clock information storage unit 72.

Subsequently, when the test board 702 is mounted in the corresponding test slot, a predetermined signal is applied to the control board 701 from the test slot in which the test board is mounted, and the control board 701 is based on this. 702) is confirmed.

In addition, the control board 702 reads a clock slot according to a test slot and a test slot stored in the clock information storage unit 72 to provide a corresponding operation clock to a slot in which the test board 702 is mounted. 704 and the synchronization generating board 703 is controlled.

That is, the clock generation board 704 generates clocks of, for example, 4 MHz and 16 MHz based on a predetermined control signal applied from the control board 701, and the synchronization generation board 703 generates the clocks from the clock generation board 704. The applied 4MHz and 16MHz clocks are provided to the test board 702 based on the control signals applied from the control board 701, respectively.

Subsequently, after the relay board to be tested is mounted in the test slot of the test apparatus 70, the test tube in the state where the operation clock is provided as described above, the test tube and the test information of the relay board to be tested through the monitoring device 71 The relay board of the present system inputs arbitrary data to the SHW (Sub HighWay) matching terminal, for example, whether the data is correctly written and read when the data is accessed into the DPRAM area of the relay board. Is the same data as looped data when the looped data is matched, each loopback function is operated, and predetermined data is read in order of Local, Remote Link, and Busy Key If the alarm is generated when the relay line is in the state of the relay line using the PCM link cable, the clock restored from the PCM link input terminal must be correct, and the jitter is inserted into the PCM link terminal. That satisfy the CCITT G.824 standard, when the ride / mounting of the board is to check whether the operation of the corresponding.

That is, the test data input through the monitoring device 71 is applied to each test board 702 through the control board 701, the test results output through the test board to the control board 701 Each is applied to be monitored through the monitoring device 71.

In addition, the output result of the test board may be implemented to be directly coupled to the monitoring device (71).

That is, according to the above, in testing a plurality of relay boards in a wireless subscriber network system, each relay board is mounted in a test slot of a test apparatus, and a different operation clock is applied to the corresponding relay board as a shih board. In addition, multiple relay boards with different operating clocks can be tested at one time with one test apparatus.

Therefore, by applying the operation clock of the board to be tested to correspond to the test board, respectively, it is possible to test a plurality of test boards having the same configuration and different operation clocks with one test device at a time.

On the other hand, the present invention is not limited to the above embodiments and can be modified in various ways without departing from the technical spirit of the present invention.

In the above embodiment, the relay board of the base station controller is illustrated as a test board in the wireless subscriber network, but the configuration of the board to be tested is the same and can be applied to the case of testing a plurality of boards having different operation clocks.

As described above, according to the present invention, by applying the operation clock of the board to be tested to correspond to the test board, respectively, it is possible to test a plurality of test boards having the same configuration and different operation clocks with one test device at a time. It becomes possible.

Claims (2)

The subscriber matching device and the base station are wirelessly coupled, the base station and the base station control period, the base station controller and the exchange period is combined by E1, the board coupled to the E1 performing the relay function is coupled to the board adjacent to the In the wireless subscriber network system provided to be the same as the operation clock, Monitoring means for inputting slot information of the test board, operation clock information and test data of the corresponding slot, and monitoring output results from the test board; Control means for controlling to provide an operation clock set in the corresponding test slot based on the test slot information applied from the monitoring means; Clock generation means for generating a clock based on a predetermined control signal applied from said control means; And a synchronization generating means for adjusting a clock applied from the clock generating means to a corresponding test board based on a predetermined control signal, and generating a synchronization signal based on the generated clock. And an output terminal of the synchronization generating means is connected in series with an input terminal of each test board. The method of claim 1, Relay board test apparatus for the wireless subscriber network system, characterized in that the output terminal of each test board is connected in series with the control means.