KR19990056203A - Connection device of packet switch and packet terminal - Google Patents

Abstract

The present invention is a device that can extend the transmission distance while continuing to use the connection standard RS-232C in connecting a packet exchanger and a packet terminal to the signal exchanger in the RS-232C line method to the packet exchanger, the signal converter A signal converter is connected to a packet terminal, and the signal converter is connected to the packet terminal to extend the transmission distance.

Description

Connection device of packet switch and packet terminal

The present invention relates to an apparatus for connecting a packet exchanger and a packet terminal, and more particularly, to an apparatus for connecting a packet exchanger and a packet terminal to extend a transmission distance by using a signal converter.

The connection protocol between a conventional packet switch and a terminal is an X.25 protocol. The X.25 protocol is divided into a physical layer, a data link layer, and a packet layer. When using the RS-232C interface to implement the physical layer has a disadvantage that the transmission distance does not exceed a maximum of about 15m. And, due to the characteristics of RS-232C, a connection standard between a packet switch and a packet terminal, the transmission distance is There is a problem that is limited to a maximum of 15m.

Therefore, an object of the present invention is to provide an apparatus capable of extending the transmission distance while continuing to use the connection standard RS-232C.

In order to accomplish the above object, the present invention connects a packet converter to the packet switch in an RS-232C line manner and connects a packet terminal side signal converter to the packet exchanger. Is connected to the packet terminal to extend the transmission distance.

1 is an exemplary configuration diagram of a packet switch 101 and a packet terminal 103 referred to in an embodiment of the present invention.

FIG. 2 is an exemplary connection diagram using the signal converter 105 and the signal converter 106 in FIG. 1.

3 is a detailed circuit diagram of the signal converter of FIG.

4 is a detailed circuit diagram of a packet communication unit of the packet switch 101.

5 is a detailed circuit diagram of the series I / O 406 of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A detailed description of a preferred embodiment of the present invention will now be described with reference to the accompanying drawings. In the following, reference numerals are given to components of each drawing, even though the same components are shown in different drawings. Note that they have the same sign. In describing the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or a chip designer, and the definitions should be made based on the contents throughout the present specification.

1 is an exemplary configuration diagram of a packet switch and a packet terminal according to an embodiment of the present invention.

In connecting the packet exchanger 101 and the packet terminal 103, a signal converter 105 is connected to the packet exchanger 101 in an RS-232C line manner, and from the signal converter 105 to the packet terminal 103 side. The signal converter 106 is connected by two wires, and the signal converter 106 is connected to the packet terminal 103 to extend the transmission distance.

FIG. 2 illustrates a connection relationship between the packet switch side signal converter 105 and the packet terminal side signal converter 106 of FIG.

FIG. 3 is an exemplary view illustrating in detail a signal converter of either the signal converter 105 or 106 of FIG. 2.

A data connection unit 301 connected to the packet communication unit RS 232C method of the packet terminal 103 or the packet switch 101, and the data connection unit 301 to drive data to be transmitted in the RS-232C method. RS-232C driver 303, a signal processor 305 for interleaving / deinterleaving the signals transmitted and received through the RS-232C driver 303 and correcting errors, and a digital signal passing through the signal processor 305 The line matching unit 309 is configured to transmit the analog signal to the counterpart signal converter, and the line terminal 307 is connected to the line matching unit 306 and two wires.

The line matching unit 309 is connected to the signal processing unit 305 and the line terminal 307 side for analog / digital or digital / analog for digital data required by the packet terminal side or analog signal required by two wires. The line encoders 311 and 314 for logging are connected, and the hybrid unit 312 is connected to the line encoder 311 and the line encoder 313 is connected to the hybrid unit 312 through a line transformer 313. In FIG. 3, the data connection unit 301 is responsible for connection with the data packet terminal, the RS-232C driver 303 processes data of the RS-232C level, and the signal processing unit 305 is the RS. The TTL level signal transmitted through the -232C driver 303 is processed according to the data processing class and then sent to the line matching unit 309, and the line matching unit 309 performs data 2B1Q signaling. It is sent to the rear line matching unit 309. The line terminal 307 is connected to the relative signal converter using two wires.

4 is a specific circuit diagram of a packet communication unit on the packet switch side;

Central processing unit 402, multi-function input / output control unit 401, memory element unit 403, reactivation circuit unit 404, clock generator 405, ready signal generator 407, decoder 408, external And a buffer 410. The central processing unit 402 patches a program and analyzes and processes the memory device unit 403 or other input / output data according to these instructions, and includes various data by interrupt and direct memory access. The multi-function input / output control unit 401 includes an interrupt controller, a direct memory access controller, a timer, and the like, and generates a timer clock required for serial input / output (SIO) operation. And a ROM, and stores a program and temporary storage information for operating the central processing unit 402. The reactivation circuit unit 404 initializes the central processing unit 402, and the clock generation unit 405 generates a clock used in the system. The ready signal generation unit 407 sets the command processing time of the central processing unit 402. Generates a signal to determine. The decoder 408 divides the memory and I / O elements into an appropriate address space. The external buffer 410 protects and restores signals when various buses and control signals are inputted and outputted outside the module. The series I / O 406 is shown in detail in FIG.

FIG. 5 is a block diagram illustrating a detailed description of the serial I / O 406 of FIG. 4.

The HDLC processing unit 504 configures an HDLC frame to exchange data with the packet exchange 101, and the interface with the processor uses direct memory access (DMA). The clock generation unit 501 supplies clock and frame synchronization. The Line Driver / Receiver 507 is composed of an RS-232C drive and a connection part, and is in charge of RS-232C connection with the packet terminal 103. 503 has a mode for determining the speed at which data is transmitted and received and for determining whether to supply or receive a clock.

In the configuration connected through two of the signal converters 105 and 106 of the present invention, one of the two signal converters is configured in the LT mode and the other NT mode, and the internal clock in the equipment set to the LT mode, the packet terminal 103 and The other signal converter and the packet switch 101 generate synchronization signals for transmission and reception. Any of the two signal converters may be set to NT or LT mode. The clock mode can be set using the mode key on the front panel operation unit (not shown). When the clock is set, it synchronizes with each other. When the clock is set, the lamp lights up on the front panel.Then terminate the role between two signal converters by pressing the speed mode key on the front panel and setting the speed according to the speed between the packet switch and the packet terminal do.

Therefore, a specific embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5.

In the conventional configuration, the connection between the packet switch 101 and the packet terminal 103 is direct. At this time, the packet exchanger 101 supplies a clock, and synchronizes each other by using the generated clock, and when a synchronous signal is transmitted, a message is transmitted to the other party, and the transmitted message becomes a frame type message of HDLC. In order to compensate for this disadvantage, the present invention is constructed between the packet switch 101 and the packet terminal 103 after the configuration as shown in FIG. 2 using the signal converter of FIG. 3. The long distance communication is possible. The extension of the transmission distance is transmitted by using the 2-wire line by sending data to the line by the 2B1Q signal in the line matching unit 309 mentioned in FIG. Is restored to the RS-232C signal from another signal converter and transmitted to the packet switch 101 or the packet terminal 103. At this time, the synchronization signal is not supplied by the packet switch 101, but the clock is supplied by the signal converter 105 set in the LT mode, and the clock is used to detect the synchronization signal. In order to achieve the configuration as shown in FIG. 1, the clock receiving mode is set, and the signal converter 105 and the signal converter 106 configured as shown in FIG. 2 are connected. The packet terminal 103 is connected to the other side (another signal converter). ) Is connected to each other to detect a synchronization signal, and when the synchronization signal is detected, a message is sent and received, and smooth communication is possible from this time. In this case, the communication speed is determined as shown in FIG. 2 (signal converter-signal converter), and the speed is determined from the signal converters 105 and 106 at the packet switch 101 or the packet terminal 103 before detecting the synchronization signal. The clock is used to determine the speed, and the synchronization signal is detected using the clock. As shown in the packet terminal 103, it is the same as the conventional one. However, the packet switch 101 is now receiving and using the clock to supply the clock. It should be determined whether to supply or receive. When the above procedure is performed, it can be seen that the long distance communication between the packet switch 101 and the packet terminal 103 is possible.

As described above, the shortcoming of the short-range communication such as the packet switch and the packet terminal is compensated for, and when the connection is made according to the configuration principle of the present invention, there is an advantage that the long-distance communication between the packet switch and the packet terminal is possible.

Claims (2)

In connecting a packet switch and a packet terminal, A packet exchanger configured to connect a signal converter to the packet switch in an RS-232C line manner, to connect a packet terminal-side signal converter from the signal converter, and to connect the signal converter to the packet terminal to extend a transmission distance. And a connection device of a packet terminal. The signal converter of claim 1, wherein the signal converter A data connection unit 301 connected to the packet communication unit RS 232C method of the packet terminal 103 or the packet switch 101, and the data connection unit 301 to drive data to be transmitted in the RS-232C method. RS-232C driver 303, a signal processor 305 for interleaving / deinterleaving the signals transmitted and received through the RS-232C driver 303 and correcting errors, and a digital signal passing through the signal processor 305 And a line matching unit 309 for matching an analog signal to a counter signal converter, and a line terminal 307 for connecting the line matching unit 306 to two wires. Connection device of packet terminal.