KR970009752B1 - Apparatus for cable test - Google Patents

Abstract

A cable tester in a data transmitter which judges whether or not a cable abnormally operates by means of a generating function of a fixed pattern is disclosed. In the tester, monitor control interface device(15) interfaces a monitor and control signal through a monitor control bus between a transmission data processor and a monitor controller and selects one of a real transmitting data or a fixed pattern. A fixed pattern generator(16) receives a transmitting clock and a sync frame and generates a fixed pattern suitable for the sync frame. A line driver(13) selects one of the transmitting data of the transmission data processor and the fixed pattern of the fixed pattern generator(16) and converts the selected signal into a =F signal.

Description

Cable Test Equipment in Data Transmission Equipment

1 is a block diagram of a cable test apparatus of a general data transmission apparatus.

2 is a detailed block diagram of a conventional transmitter in FIG.

3 is a detailed block diagram of a receiver in FIG. 1;

4 is a detailed block diagram of a transmitter according to the present invention.

* Explanation of symbols for main parts of the drawings

11 transmission data processing means 12 transmission parity generating means

13 line driving means 15 supervisory control interface means

16: fixed pattern generating means 17: data selection means

The present invention relates to a cable test in a twisted pair data transmission method between devices, in particular to determine whether the normal operation of the cable by the function of generating a simple fixed pattern off-line to inform the operator Therefore, the present invention relates to a cable test apparatus for a data transmission apparatus to enhance maintenance functions.

The test apparatus of the conventional twisted pair cable is composed of each device (1) (2) connected to the twisted pair cable to transmit and receive data, clock, parity as shown in FIG.

Herein, each device receives data from the first and second transmitters 10 and 10a for processing data and transmits the data as ± data, and receives the data from the transmitters 10 and 10a to restore and process the data. First and second receivers 20 and 20a, and monitoring controllers 30 and 30a for monitoring and controlling all operating states in the apparatus.

Here, the type of twisted cable signal interfaced between the transmitter and receiver 10, 20, 10a and 20a of each device is ± data to be transmitted, ± clock for data retime, and for detecting a cable failure on-line. It consists of ± parity.

FIG. 2 is a detailed block diagram of the transmitter 10 and 10a in FIG. 1. As shown in FIG. 1, a transmission data processor 11 and a transmission data processor 11 for transmission of a synchronous frame and serial data are shown. A transmission parity generation unit 12 which receives the transmission data and the synchronization frame from the terminal and generates parity in units of bytes, and each serial signal inputted from the transmission parity generation unit 12 and the transmission data processing unit 11; A line driver 13 for converting the transmission data, the transmission clock, and the transmission parity into ± signals (± transmission data, ± transmission clock, ± transmission parity), and monitoring signals and control signals from the transmission data processing unit 11. It consists of a supervisory control interface 14 which interfaces with the supervisory control part 30 via a control bus.

In addition, the receivers 20 and 20a of the respective devices may include a line receiver 21 for converting a ± signal received through a twisted pair cable into a unipolar signal, and the data received from the line receiver 21. A sync frame for extracting the frame and reproducing the parity in bytes from the parity reproducing unit 22 and the parity received from the line receiving unit 21 and the frame from the parity reproducing unit 22. A parity comparison unit 23 for detecting an error by comparing reproduction parity, and a parity error counting unit 24 for counting the number of errors detected by the parity detection unit 23 according to the reception clock of the line receiving unit 21. And a reception data processing unit 25 for processing data and clocks received from the synchronization frame detection and parity reproducing unit 22 according to a system application, and the reception data processing unit 25. And a supervisory control interface unit 26 for interfacing the supervisory control signal with the supervisory control units 30 and 30a through the supervisory control bus of the parity error counting unit 24.

The conventional twisted pair cable configured as described above will be described by dividing the operation of the test apparatus into a transmitter and a receiver.

First, in the transmission unit 10, the transmission data processing unit 11 constructs serial data to be transmitted to the power station 2, and inserts a sync frame so that the receiver 20a of the power station device can find the start of the frame. It feeds to the line drive part 13 together.

The transmission parity generation unit 12 divides the transmission data into 8 bit forms based on the synchronization frame information received from the transmission data processing unit 11 so that the number of 1s in 8 bits always has a specified value (even or odd). The transmission parity is configured in units of 8 bits (1 byte).

The line driver 13 adjusts the transmission data, the transmission clock received from the transmission data processing unit 11, and the transmission parity received from the transmission parity generation unit 12 so as to be suitable for balanced twisted pair cable transmission. Transmit to Transmit Clock, ± Transmit Parity) and send to adjacent device.

At this time, the ± signals should use the twisted pair cable of the same length to have the same delay.

Next, the signal (± received data, ± received clock, ± received parity) received from the balanced twisted pair cable is converted into a unipolar signal through the line receiver 21.

The sync frame detection and parity reproducing unit 22 searches for a frame of serial reception data from the monopolar data and the clock converted through the line receiving unit 21, and divides the data into a form of 8 bits (1 byte) from there to determine parity. Play it.

The parity comparison unit 23 detects a parity error by comparing the unipolar parity converted by the line receiving unit 21 with the parity reproduced by the sync frame detection and parity reproducing unit 22.

The parity error counting unit 24 counts the number of parity errors detected by the parity comparing unit 23 and sends the count value to the monitoring control interface unit 26.

The monitoring control interface unit 26 notifies the operator of the parity error count value at the operator's request.

However, the test apparatus of the conventional twisted pair cable is not solved when the operator wants to separately test the state of the balanced twisted pair cable connected between the devices because the output of the transmitting data processing unit is directly output to the receiving unit of the power station. If there is no data to be transmitted, there is a problem in that there is no change in the transmission parity, which not only interferes with the cable test but also has a limitation in maintenance function.

Accordingly, the present invention provides a fixed pattern generation function for determining whether a cable is abnormal in an offline state in a system for transmitting data, clock, and parity to a neighboring device using a balanced twisted pair cable to improve the problems of the related art. Test the cable by generating a fixed pattern in the twisted pair transmission method that has a selection function by the operator. Even if there is no data to be sent, the cable is tested to the neighboring device by the operator's command before the data to be transmitted is tested in advance. It is an object of the present invention to provide a cable testing apparatus in a data transmission apparatus that enhances the maintenance function such as to enable the service.

Referring to the configuration of the present invention for achieving the above object in detail based on the accompanying drawings as follows.

4 is a block diagram of an apparatus for testing a cable in a data transmission apparatus according to the present invention. As shown in FIG. 4, transmission data processing means 11 for transmitting a synchronous frame and serial data and monitoring all operating states in the apparatus are shown. And a supervisory control interface means for interfacing a supervisory and control signal through a supervisory control bus between the supervisory control means 30 for controlling and generating a selection signal for selecting one of actual transmission data and a fixed pattern according to an operator's request. (15), fixed pattern generating means (16) for receiving the transmission clock and the synchronization frame from the transmission data processing means (11) and generating a fixed pattern suitable for the synchronization frame, and selecting the monitoring control interface means (15). According to the signal, one of the transmission data of the transmission data processing means 11 and the fixed pattern of the fixed pattern generating means 16 is selected. And data selection means 17 for transmission to the line driving means 13 for converting the signal into the +/- signal.

Hereinafter, the configuration of the reception means opposite to the transmission means is the same as the block configuration of the test apparatus of the conventional twisted pair cable is omitted.

Referring to the operation, effects of the present invention configured as described above in detail.

First, the operation of the transmission means 10 will be described with reference to FIG. 4, and if the operator desires a separate cable test, the selection signal is sent out so that the fixed pattern is selected by the data selection means 17 through the monitoring control interface means 15. do.

At this time, the fixed pattern generating means 16 receives the synchronization frame and the transmission clock from the transmission data processing means 11 and counts the transmission clock based on the synchronization frame to form a fixed pattern in units of 8 bits (1 byte).

At this time, the fixed pattern is made by using the count value, and the number of '1' in 8 bits is configured to be odd once and even once.

In this way, the values of the transmission parity are repeated so that '1' and '0' are repeated, thereby determining whether a cable is abnormal.

The data selected in response to the operator's command in the data selecting means 17 is converted into a ± signal via the transmission parity generating means 12 and the line driving means 13 and transmitted to the adjacent device 2 via the balanced twisted pair cable. .

The operation of the receiving means 20a of the neighboring device 2 is converted into a ± signal by the line driving means 11 of the transmitting means 10, and the line receiving part 21 of the receiving means 20a via the balanced twisted cable. Received by the parity comparison means 23 detects a parity error and informs the operator, the operator determines whether the qualitative operation of the cable connected between the device (1) (2).

As described above, the present invention provides a twisted pair in which one of the outputs of the transmission data processing means (the actual data) and the output of the fixed pattern generating means (the fixed pattern) is output to the adjacent device according to the operator's command. If you want to test the condition of the cable separately, you can test it, and even if there is no data to be transmitted, you can select the fixed pattern by the operator's command and send it to the adjacent device, so that you can test the cable before loading the data to be transmitted. There is an effect to strengthen the maintenance function.

Claims (1)

Interfaces the monitoring and control signals through the supervisory control bus between the transmission data processing means for the transmission of the synchronous frame and the serial data and the supervisory control means for monitoring and controlling the entire operating state in the apparatus. Supervisory control interface means for generating a selection signal for selecting one of data and a fixed pattern, fixed pattern generating means for receiving a transmission clock and a synchronization frame from the transmission data processing means and generating a fixed pattern suitable for the synchronization frame; And data selection means for selecting one of the transmission data of the transmission data processing means and the fixed pattern of the fixed pattern generating means and transmitting the data to a line driving means for converting the signal into a ± signal according to the selection signal of the monitoring control interface means. Cabling in a data transmission apparatus Label the test device.