KR19980046179U - Test signal generator for asymmetric digital transmitter - Google Patents

Abstract

The present invention relates to an ADSL test signal generator for generating a T1 level 1.544 Mbps data signal and a 9.6 Kbps control signal for testing an asymmetric digital transmission device at a telephone station. Generates T1 level clock and 9.6KHz clock by inputting frequency, and generates T1 level test signal and 9.6KHz test signal according to the generated T1 level clock and 9.6KHz clock. After performing line coding to convert the level of the test signal of T1 and the test signal of 9.6KHz, it is connected to the external ASDL-C through various connection devices, and the line-coded T1 test signal of 9.6KHz By outputting the test signal, whether or not the ASDL-C operates through a simple and portable test signal generator that generates test signals such as T1 level data and 9.6 KHz control signals applied to the ASDL-C. We've got the state to test the effect achieve cost savings and time savings.

Description

Test signal generator for asymmetric digital transmitter

The present invention is an asymmetric digital subscriber line system (hereinafter referred to as ADSL) system, the T1-class 1.544Mbps data signal for testing the asymmetric digital transmitter (ADSL-C (Center)) of the telephone station side and The present invention relates to a test signal generator for ADSL generating a control signal of 9.6 Kbps.

In general, the ADSL system is a system for providing on-demand video services to subscribers by transmitting video image data from a telephone station to a subscriber's home. As shown in FIG. A video server 11, which is a kind of video database that compresses and stores, transmits corresponding video data according to a subscriber's call signal, or has a charge calculation function, and a 1.544 Mbps video image provided by the video server 11. And a video switch 12 for selecting and connecting a corresponding video server according to the needs of telephone video viewers, and unidirectional 1.544 Mbps video image data provided through the video switch 12. It is a signal to receive bidirectional control channel data and transmit it through telephone line. ASDL-C which demodulates and provides video service in case of power failure by using manual filter device as well as Plain Old Telephone Service (POTS) service of telephone exchange 14, and performs transmission error correction function and bidirectional control channel function. And the subscriber side 20 includes an ASDL-R (Remote) 21 and the ASDL-R 21 for receiving video image data and control signal data transmitted from the ADSL-C 13. It is composed of a set top box (STB) (22) for converting the video image data and control signal data received by the on-demand video service through the TV receiver 23.

ADSL system configured as above connects T1 level 1.544Mbps physical layer channel outgoing one-way from telephone station to subscriber's home as well as 9.6Kbps or 16Kbps asynchronous bidirectional control signal for each subscriber to 3.5Km with almost no error.

The low-speed control information exchanged bidirectionally between the subscriber and the telephone station occupies a lower frequency band than the video channel, and three separate signal informations exist simultaneously on the 2-wire copper wire.

In this case, since the signal information is divided in frequency and does not affect each other, the signal information can be transmitted even during a call, and the voice information service can be provided even when the power of the video information is turned off.

On the other hand, prior to the installation of the ASDL-C (13) of the telephone station as described above, the test process, each time is provided with a video server 11 and a video switch 12 through the video server 11 The operation of the ASDL-C 13 was tested using the output T1 level signal and the 9.6 Kbps signal.

However, as the manufacturer includes external equipment such as the video server 12 to test the ASDL-C 13, it is expensive and the economic burden is increased, and the pre-installed ASDL-C is installed. Even in the test, there was a very troublesome problem of operating other equipment such as a video server and a video switch to output a T1 level signal and a control signal of 9.6 Kbps.

The present invention has been made to solve the above problems, the purpose of which is easy to use by forming a compact and portable device that generates a T1 level data signal and 9.6Kbps control signal required for testing ASDL-C Therefore, it is to provide a test signal generator for an asymmetric digital transmitter that generates test signals so that it can test whether there is an abnormal operation of ASDL-C at the factory and the site.

The test signal generator for the asymmetric digital transmitter of the present invention for achieving the above object is to generate an external high frequency frequency to generate a clock of T1 level and a clock of 9.6KHz, respectively, and the generated T1 level clock and 9.6 According to the clock of KHz, T1 class test signal and 9.6KHz test signal are generated, and after performing line coding to convert the level of the generated T1 test signal and 9.6KHz test signal, various connection equipment It is connected to an external device through the line coded T1 class test signal and 9.6KHz characterized in that it outputs a test signal.

1 is a block diagram of a typical asymmetric digital transmitter.

Figure 2 is a block diagram of a test signal generator for testing a telephone station-side asymmetric digital transmission apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: reference clock generator 101: clock generator

102: T1-signal generator 103: 9.6K-signal generator

104: T1-line interface unit 105: 9.6K-line interface unit

106: connection part

2 is a block diagram of a test signal generator for testing an asymmetric digital transmitter in accordance with the present invention, comprising a reference clock generator 100 for generating a stable high frequency frequency reference clock and a flip-flop divider circuit. A clock generator 101 for receiving a stable high frequency frequency generated by the reference clock generator 100 and generating a T1-class clock and a 9.6-KHz clock by a frequency division circuit; and the clock generator 101 T1-signal generator 102 for generating a test signal of T1-class 1.544 Mbps with a predetermined pattern according to the T1-class clock generated in the present invention), and a constant pattern according to the 9.6 KHz clock generated by the clock generator 101. 9.6K-signal generator 103 for generating a test signal of 9.6Kbps and T1-class 1.544Mbps test signal generated by the T1-signal generator 102 are input to receive T1-class data on a telephone line. Level conversion function A level conversion function is provided to receive a test signal of 9.6 Kbps generated by the T1-line interface unit 104 and the 9.6K-signal generator 103 to transmit a control signal of 9.6 Kbps on the telephone line. The 9.6K-line interface unit 105 to perform the test, and the ASDL-C to test the respective test signals which are line coded and output from the T1-line interface unit 104 and the 9.6K-line interface unit 105. It consists of the connection part 106 to connect.

The line coding technique used in the T1-line interface unit 104 and the 9.6K-line interface unit 105 conforms to the signal input standard of the ASDL-C, and a desired line coding technique can be selected by manipulating a switch. .

In addition, the connection portion 106 is provided with a connection connector of various forms, it is possible to easily connect the signal when the ASDL-C test signal generator of the present invention in the field.

Referring to the operation of the test signal generator for an asymmetric digital transmitter of the present invention configured as described above are as follows.

The reference clock generator 100 provides a stable high frequency frequency reference clock, and the clock generator 101 generates a T1 level clock and a 9.6KHz clock through an internal frequency divider circuit.

The generated T1-class clock and the 9.6-KHz clock are input to the T1-signal generator 102 and the 9.6K-signal generator 103, respectively.

Then, the T1-signal generator 102 generates the T1-class 1.544Mbps test data and the clock of a predetermined pattern (for example, 10101010) using the generated T1-class clock, and generates a 9.6K-signal generator. Also, 103 generates a 9.6 Kbps test control data and a clock of a predetermined pattern according to the generated 9.6 KHz clock.

Subsequently, in order to transmit the data and clock of 1.544 Mbps generated by the T1-signal generator 102 and the control data and clock of 9.6 Kbps generated by the 9.6K-signal generator 103 onto a telephone line, line coding is performed. You have to go through the process.

Accordingly, the data and clock of 1.544 Mbps and the control data and clock of 9.6 Kbps are subjected to a line coding process of level conversion by the T1-line interface unit 104 and the 9.6K-line interface unit 105, respectively.

Each of the test signals T1_Tx (+), T1_Tx (-), 9.6K_Tx (+), and 9.6K_Tx (-) line-coded as described above is applied to the external ASDL-C through the connection unit 106.

Then, the ASDL-C operates by inputting the test signals T1_Tx (+), T1_Tx (-), 9.6K_Tx (+), and 9.6K_Tx (-). Allows you to test for abnormalities.

As described above, the present invention has an abnormal operation of the ASDL-C through a simple and portable test signal generator that generates test signals such as T1 level data and 9.6 Kbps control signals applied to the ASDL-C. The state can be tested to save money and save time.

Claims (1)

It consists of a reference clock generator 100 for generating a reference clock of a stable high frequency frequency, and a divider circuit of flip-flop, and receives a stable high frequency frequency generated by the reference clock generator 100 by a frequency division circuit A clock generator 101 for generating a T1-class clock and a 9.6-KHz clock, and a T1-signal for generating a T1-class 1.544 Mbps test signal with a predetermined pattern according to the T1-class clock generated by the clock generator 101 The generator 102, the 9.6K-signal generator 103 for generating a test signal of 9.6Kbps of a predetermined pattern according to the 9.6KHz clock generated by the clock generator 101, and the T1-signal generator A T1-line interface unit 104 for performing a level conversion function to receive a T1 level 1.544Mbps test signal generated at 102 and to transmit T1 level data on a telephone line; and generating the 9.6K signal Input the test signal of 9.6Kbps generated from the unit 103 9.6K-line interface unit 105 for performing a level conversion function to transmit a control signal of 9.6Kbps on the telephone line, and the T1-line interface unit 104 and the 9.6K-line interface unit 105. A test signal generator for an asymmetrical transmission device, characterized in that consisting of a connection unit 106 for connecting each test signal output by line-coded with the ASDL-C to be tested.