KR0167910B1 - Remote data service unit controlling apparatus - Google Patents

Abstract

The present invention relates to a remote data service unit control apparatus which enables a counter station to be loop-backed in its own station to easily control the network of the other station even if there is no user in the data service unit of the other station.

In the conventional data service unit, if the config value of the counterpart DSU is different from that of the counterpart DSU or an error occurs in the counterpart DSU and an error is detected in the own station DSU, a user must exist in the counterpart DSU to correct the error. In addition, there is a problem that the efficiency of data communication is reduced.

In order to solve the problems of the prior art, the present invention is intended to improve the efficiency of network management and data communication that can control the config value of the counterpart DSU even if there is no user in the counterpart DSU.

Description

Remote Data Service Unit (DSU) Control Unit

1 is a block diagram of a conventional data service unit (DSU) programmable gate array.

2 is a block diagram of a conventional remote digital loopback (RDLB).

3 is a block diagram of a data service unit (DSU) programmable gate array block according to the present invention.

4 is a block diagram of a remote data service unit control unit (RDC) according to the present invention.

5 is a flowchart illustrating a remote data service unit (DSU) control operation according to the present invention.

* Explanation of symbols for main parts of the drawings

10: central processing unit (CPU) 20: programmable gate array (PGA)

30: digital phase locked loop 40: transmission clock phase locked loop

50: coding unit 60: decoding unit

70: transmission and reception pattern unit 80: remote data service unit control unit (RDC)

100: transmitter 101: pattern generator

102: error detector 103: receiver

110: config value transmission request unit

111: correction pattern portion 200: receiver

201: transmitter

The present invention relates to a remote data service unit (DSU) control device. In particular, even if there is no user in the data service unit of the counterpart station, the counterpart station is loop-backed in the own station to easily control the network of the counterpart station.

In general, a data service unit (hereinafter, abbreviated as DSU) uses digital data as a point-to-point or point-to-multipoint dedicated line between a computer and a computer or various data terminals. It is to enable remote high speed data communication.

Under this background, the block structure of a conventional data service unit programmable gate array controls the operation of the programmable gate array (PGA) 20 and the PGA 20 as shown in FIG. It consists of a central processing unit (10) for relay control, loopback control, DTE interface control and status.

The programmable gate array (PGA) 20 is composed of a digital phase locked loop 30, a transmission clock phase locked loop 40, a coding unit 50, and a decoding unit 60.

The conventional apparatus configured as described above divides the clock inputted through the oscillator from the PGA 20 into the clock for each transmission speed in the digital locked loop 30 and the transmit clock phase locked loop 40.

In this case, the coding unit 50 and the decoding unit 60 generate and detect an IDLE, a failure, a loop back signal, and the like of the data service unit (DSU).

On the other hand, the digital signal of the data terminal input from the connection of the data terminal device (DTE) is controlled according to the speed and state of the data terminal.

At this time, the DTE interface controller controls the data terminal ready signal (DTR) / data set ready signal (DSR), transmission request signal (RTS) / transmission clear signal (CTS) delay time, data channel detection signal (DCD), and loop back by DTE. Test signals (LLB, DLB, RDLB) are controlled.

2 shows a block diagram of a conventional remote digital loop back (RDLB), in which the counter station DSU is automatically put in a digital loop back (DLB) state so that the counter station DSU can be resent by sending a test pattern from the host DSU. The DSU will compare the transmit and receive patterns.

However, in the conventional data service unit, if the config value of the counterpart DSU is different from that of the counterpart DSU or an error occurs in the counterpart DSU and an error is detected in the own station DSU, the user can exist in the counterpart DSU to correct the error. In addition to the inconvenience, there is a problem that the efficiency of data communication is reduced.

The present invention has been made to solve the problems of the prior art, and its object is to improve the efficiency of network management and data communication that can control the config value of the counterpart DSU even if there is no user in the counterpart DSU. .

DETAILED DESCRIPTION OF THE INVENTION The present invention for achieving this object is described in detail with reference to the accompanying embodiments as follows.

3 is a block diagram of a DSU programmable gate array block according to the present invention, in which a communication line between a local station and a counterpart DSU is connected before transmitting a signal for controlling a remote DSU to a programmable gate array (PGA) in a conventional configuration. A transmission and reception pattern unit 70 and a remote data service unit control unit 80 for transmitting and receiving a signal for controlling the remote DSU are provided.

Here, the remote data service unit controller 80 is composed of serial / parallel and parallel / serial conversion circuits for the transmission / reception pattern unit 70 requesting the configuration of the counterpart DSU.

The remote data service unity control unit 80 generates a pattern by scrambling the transmitter 100 and the receiver 103 with a polynomial (1 + X ^-5 + X ^-7 ) as shown in FIG. 101, an error detector 102 for detecting a data error state input from the transmitter 100 to the receiver 103, and a config value transmission request unit for requesting transmission of config values, which are information contained in the DSU. A local station DSU including a correction pattern unit 111 for displaying and correcting the config value on the LCD and transmitting it to the destination station DSU, and a partner station DSU including the receiver 200 and the transmitter 201. It is done.

Referring to the operation and effect of the present invention configured as described above are as follows.

The remote DSU control unit (RDC) uses the main channel and uses the DSU front panel key. In addition, the RDC is performed in a remote digital loop back (RDLB) state in order not to affect the counterpart DSU in the RDC shown in FIG.

Herein, the control operation of the remote DSU according to the present invention will be described with reference to FIG. The local station DSU transmits an RDC attempt pattern, and the counterpart station DSU transmits an recognition frame pattern to the local station DSU when the RDC attempt pattern is correctly received.

At this time, when the recognition frame pattern is received, the local station DSU transmits the remote configuration request pattern for requesting transmission of the configuration value of the counterpart station DSU through the remote data service unit controller 80.

Subsequently, when the EOR value is detected or the unregistered control field is received, the counterpart DSU transmits a NACK pattern. Otherwise, the counterpart DSU transmits a recognition frame pattern including the config value.

In the local DSU, the remote config value is stored in the CPU RAM and the config value is displayed on the LCD and corrected.

When the modified config value is transmitted to the counterpart DSU and the recognition frame pattern is modified by the own station DSU, the RDC end pattern is transmitted and then returned to the data transmission mode.

The EOR value is a value that compares two data values (0 or 1) to 1 if they are the same and to 1 otherwise.

As described above, the present invention can remotely control the config value of the counterpart DSU even if there is no user in the counterpart data service unit (DSU), thereby increasing the efficiency of network management and data communication.

Claims (2)

The programmable gate array 20 including the digital phase locked loop 30, the transmit clock phase locked loop 40, the coding unit 50, and the decoding unit 60, and controls the operation of the programmable gate array 20. And a data service unit having an LCD display, a relay control, a loop back control, a DTE interface control, and a central processing unit 10 for sensing a status, wherein the programmable gate array 20 controls a remote DSU. And a transmission and reception pattern unit 70 for connecting a communication line between the local station and the counterpart DSU before transmitting a signal, and a remote data service unit control unit 80 for transmitting and receiving a signal for controlling the remote DSU. A remote data service unit (DSU) control unit. The pattern generator (101) of claim 1, wherein the remote data service unit controller (80) generates a pattern by scrambling the transmitter (100) and the receiver (103) with a polynomial (1 + X ^-5 + X ^-7 ). ), An error detector 102 for detecting a data error state input from the transmitter 100 to the receiver 103, and a config value transmission request unit 110 for requesting transmission of config values, which are information that the DSU has. ), And a local station DSU including a correction pattern unit 111 for displaying and correcting a config value on the LCD and transmitting the same to a counterpart station DSU, and a counterpart station DSU including a receiver 200 and a transmitter 201. Remote Data Service Unit (DSU) Control Unit.