JPS6333949A - Data communication system - Google Patents

Abstract

PURPOSE:To attain the data communication service with high reliability and high efficiency by applying a job start and job end request to a PAD on the condition of a link setting request and a link interruption request from an HDLC terminal equipment. CONSTITUTION:A job start request is given to a packet composing/decomposing means 2 on the condition of a link setting request from the HBLC terminal equipment 1. Further, a job end request is given to the packet composing/ decomposing means 2 on the condition of a link interruption request from the HDLC terminal equipment 1. Thus, a host side starts data transfer immediately after a reset confirming packet RF transmission. Moreover, since the supervision of carrie-on/carrier-off is not needed, job start or end by mis-recognition due to noise is not caused. Furthermore, since it is not required to take timing for data transfer enable or link setting end notice, the control is simplified.

Description

[Detailed Description of the Invention] [Summary] In the HDLC control means provided between the HDLC terminal and the packet assembly and disassembly means (PAD), a link setting request and a link disconnection request from the HDLC terminal are triggered to start operation. This is a method in which requests and end-of-work requests are made to the PAD.

[Industrial application field]

TECHNICAL FIELD The present invention relates to a data exchange processing device, and particularly to a data exchange processing device.
(High Level Data Link Con
trol) Link setting and disconnection from the terminal will trigger the start of work.
Packet assembly/disassembly means (
This invention relates to a data communication system that accommodates PAD.

The background of the present invention will be explained with reference to FIG. In addition, in the following description, the same reference number shall represent the same thing.

In FIG. 5, the HDLC terminal 21 and the host computer 22 are connected to a line 23, a data transmission/reception control section 24, and an H
They are connected via a DLC procedure control section 25, PAD 26, x, 25 procedure control section 27, data transmission/reception control section 28, and line 29. Data transmission/reception control unit 24, HDLC
The procedure control unit 25 and PAD 26 are components of the data exchange processing device. The present invention relates to a method for accommodating a PAD'26 by an HDLC procedure control section 25 in a data exchange processing device, and more specifically, the present invention relates to a method for accommodating a PAD'26 by an HDLC procedure control section 25 in a data exchange processing device.
Regarding the method of starting and ending work during D26.

[Conventional technology]

A conventional PAD accommodation system will be explained with reference to FIG. 6th
In the figure, ■ is a carrier-on signal control step;
■ indicates a link setting step of the HDLC procedure, ■ indicates a data communication step, ■ indicates a link setting step, and ■ indicates a carrier-off signal control step. As is clear from the figure, conventionally, the link setting step (2) was executed only after the carrier-on signal control step (2) was completed.

In other words, conventionally, the carrier signal from the HDLC terminal 21
When the HDLC procedure control unit 25 receives the
DLC: The procedure control unit 25 recognized that this is the start of data communication between the HDLC terminal 21 and the host computer 22. Further, when the HDLC procedure control unit 25 receives carrier off from the HDLC terminal 21, the HDLC
The procedure control unit 25 recognized that this was the end of the data communication. Note that carrier on and carrier off refer to HDL
It means the presence or absence of a carrier (predetermined DC voltage level) between the C terminal 21 and the HDLC procedure control unit 25. For example, by turning on or off the power of the HDLC terminal 21, a carrier on or carrier off signal is generated. can get.

The frame format of information used in the HDLC procedure is shown in FIG. 8, and the types of commands and responses in the HDLC procedure are shown in FIGS. 9 and 10, respectively. Also, X, -
FIG. 11 shows packets used in the X.25 data transfer procedure. DM shown in FIG.

SARM, I, RR, RD, RNR, Disc.

US represents the various commands and commands shown in FIGS. 9 and 10, R, Q, RF.

DT and RR represent the various packets shown in FIG.

FIG. 7 is a functional block diagram showing the configuration of a conventional HDLC procedure control section 25. As shown in FIG. In the figure, the HDLC procedure control unit 25 includes a carrier control unit 251, a link setting control unit 2
52, a data transfer control section 253, and a link disconnection control section 254.

The carrier control unit 251 requests the PAD 26 to start working in response to the carrier on from the HDLC terminal 21, and
In response to the start response from D26, carrier on is sent to HDLC terminal 21.

Furthermore, at the end of the work day, a request for end of work is made to the PAD 26, and in response to this, a carrier off message is sent to the HDLC terminal 21 in response to an end of work response from the PAD 26.

After completion of DM frame reception, SARM frame transmission, and UA frame reception with the HDLC terminal 21, the link setting control unit 252 notifies the PAD 26 of link setting completion.

The data transfer control unit 253 transmits and receives I frames and RR frames to and from the HDLC terminal 21, and
The data transmission request and data transmission confirmation are made to the PAD 26, and the data transmission confirmation and data reception notification are received from the PAD 26, thereby performing data communication.

The link disconnection control unit 254 performs RD frame reception, RNR frame transmission/reception, DISC frame transmission, and UA frame reception with the two HDLC terminals, and then PAD
26 is notified that the link has been disconnected.

[Problems to be solved by the invention]

According to the above-mentioned prior art, since the link setting step (2) was executed only after the carrier-on signal control step (2) was completed, the x,25 procedure control unit 27 did not respond to the reset request packet RQ (DTE). Even though data communication is possible after sending the reset confirmation packet (packet) RF, the HDLC terminal 21 side is executing the link setting step
5 Procedure control unit 27 side (host side) and HDLC terminal 21
There is a problem that a state mismatch occurs on both sides, and data cannot be transferred during this time. For this reason, conventionally, after sending the reset confirmation bucket) RF from the procedure control unit 27,
The databake node DT was sent after counting the time required for the link setting step (■) or after receiving a link setting completion notification from the link setting control unit 252.
Such timing control and link setting completion notification are complicated to control, and the time from sending the reset confirmation packet RF to sending the data packet DT is used exclusively for link setting, and is not used for data transfer. The problem of not being able to do so remains unresolved.

Furthermore, in the conventional method described above, which recognizes the carrier-on signal and the carrier-off signal as the start and end of data transfer, respectively, noise generated by the modem connected to the HDLC terminal 21 is recognized as the carrier-on signal and the carrier-off signal. There is also the problem that data transfer may be erroneously started or ended if it is mistakenly recognized as an off signal.

Furthermore, in the conventional method described above, there is a problem in that it is impossible to start the work from the host side.

[Means for solving problems]

FIG. 1 is a block diagram of the principle of the present invention.

In the HDLC control means 3 provided between the HDLC terminal 1 and the terminal assembly and disassembly means 2,
In response to a link setting request from , a start request is made to the packet assembling and disassembling means 2 . In addition, the HD
In response to a link disconnection request from the LC terminal 1, a termination request is made to the packet assembling and disassembling means 2.

[For production]

According to the present invention, since the start request and the end request are made to the PAD in response to the link setting request and link disconnection request from the HDLC terminal, the host side immediately sends the data data after sending the reset confirmation packet 1-RF. transfer can be initiated. Furthermore, since there is no need to monitor carrier-on and carrier-off, there is no possibility of false start or end of work due to noise or the like. Furthermore, since there is no need to determine the timing until data transfer becomes possible or to notify link setting completion, control is simplified.

〔Example〕

The present invention is based on the premise that a carrier is established between the HDLC terminal 21 and the HDLC procedure control section 250. This can be achieved by using a modem in which the carrier is always on, or by not monitoring the carrier with the data exchange processing device.

FIG. 2 shows an HDLC terminal 2 as an embodiment of the present invention.
The case of starting from 1 will be explained.

At the time of starting operation, the HDLC terminal 21 notifies the HDLC procedure control unit 250 of the start of operation by transmitting a mode setting request frame DM to the HDLC procedure control unit 250. H in the data exchange processing device
The DLC procedure control unit 250 receives the frame DM and transmits a mode setting SARM to the HDLC terminal 21 if the mode can be set.

) (The DLC terminal 21 sends a mode setting response frame UA in response to the frame SARM. When the HDLC procedure control unit 250 receives the frame UA, link setting is completed and data transfer becomes possible.

The HDLC procedure control unit 250 issues a start request to the PAD 26 in response to receiving the frame UA. The PA 026 recognizes this start-of-work request as the start of work, transmits a start-of-work request packet RQ (DTE) to the x, 25 procedure control unit 27 on the host side, and waits for a start-of-work response from the host side. The HDLC procedure control first 250 sends the input regulation frame RNR to the HDLC terminal in order to temporarily put it in a busy state, since even if data is received from the HDLC terminal 21 during this waiting time, it cannot be sent to the other host side. Send it on the 21st.

When the PAD 26 receives the reset confirmation packet I-RF from the X, 25 procedure control unit 27, it sends a start response to the HDLC procedure control unit 250 in response to the reset confirmation packet I-RF, and the HDLC procedure control unit 250 responds to this start response. The input restriction release frame RR is transmitted to the HDLC terminal 21, and data transfer is then started.

The end-of-day processing from the HDLC terminal 21 is the same as the conventional example shown in FIG. 3, so a description thereof will be omitted. However, the present invention does not require carrier-off monitoring.

Referring to FIG. 3, a case in which work is started from the host side will be described as another embodiment of the present invention. Previously, it was impossible to start work from the host side. According to this embodiment, it is also possible to start work from the host side, as described below, by automatically turning on the power of the HDLC terminal 21 in response to an instruction from the host side.

In FIG. 3, first, X on the host side, 25 procedure control unit 2
7 sends a start request packet RQ (DTE) to the PAD 26, the PAD 26 sends a start request to the HDLC procedure controller 250, and if the mode can be set, the HDLC procedure controller 250 sends a mode setting request frame to the HDLC terminal 21. Send SARM. Upon receiving the frame SARM, the HDLC terminal 21 turns on its power and transmits a mode setting response frame UA. HDL
The C procedure control unit 250 makes a start request to the PAD 26 in response to the reception of the frame UA, and the PAD 26 uses this as an opportunity to send the start response bucket) RF x, 25 procedure control unit 27
Send to. This enables data transfer.

To end the work from the host side, x, 25 procedure control unit 27
requests the PAD 26 to end its work by transmitting an end-of-work request packet RQ (D'TE) during data transfer. The HDLC procedure control unit 250 transmits an input restriction frame RNR to the HDLC terminal 21 in response to the end-of-day request. The HDLC terminal 21 transmits a response frame RR in response to receiving the frame RNR. The HDLC procedure control unit 250 transmits a link disconnection frame Disc in response to the reception of the frame RR, so that the HDLC procedure control unit 250
Notify of link disconnection. Upon receiving the frame DISC, the HDLC terminal 21 performs link disconnection processing and transmits a link disconnection response frame UA.

The HDLC procedure control unit 250 sends an end-of-work response to the PAD 26 in response to the frame UA, and the PAD 26 uses this as an opportunity to send an end-of-work notification I-RQ (DER) to x on the host side.
25, the procedure controller 27 is notified that the work has ended.

FIG. 4 shows the HDLC procedure control unit 2 in the embodiment of the present invention.
50 is a functional block diagram showing the configuration of 50. FIG.

In the same figure, the HDLC procedure control section 250 includes a carrier control section 2501, a link setting control section 2502, a data transfer control section 2503, and a link disconnection control section 2504.

The carrier control unit 2501 only transmits and receives carrier-on signals to and from the HDLC terminal, and does not perform work start and end processing as in the conventional example shown in FIG.

As shown in FIGS. 2 and 3, the link setting control unit 2502 receives DM frames from the HDLC terminal 21,
S A, RM frame transmission, UA frame reception, RN
In addition to transmitting R frames and RR frames, P
It receives a start-of-work instruction, sends a start-of-work response, sends a start-of-work request, and receives a start-of-work response with the AD26. SARM to receive start-up instructions
The transmission of a start response corresponds to the reception of a UA frame, the transmission of a start request corresponds to the reception of a UA frame, and the reception of a start response corresponds to the transmission of an RR frame.

The data transfer control section 2503 is the same as the data transfer control section 253 in the conventional example shown in FIG.

The link disconnection control unit 2504 performs RD frame reception, RNR frame transmission, RNR frame reception, DISC frame transmission, and UA frame reception with the HDLC terminal 21, and also receives end-of-work instructions, transmits end-of-work responses, and sends end-of-work responses with the PAD 26. Sends end-of-work requests and receives end-of-work responses.

〔Effect of the invention〕

As explained above, according to the present invention, the start request and the end request are made to the PAD in response to the link setup request and link disconnection request from the HDLC terminal, so the host side sends the reset confirmation packet RF. Data transfer can begin immediately after that. Furthermore, since there is no need to monitor carrier-on and carrier-off, there is no possibility of false start or end of work due to noise or the like. Furthermore, since there is no need to determine the timing until data transfer becomes possible or to notify link setting completion, control is simplified. Furthermore, it becomes possible to start work from the host side, which was previously impossible. Thus, the present invention enables highly reliable and highly efficient data communication services.

[Brief explanation of drawings]

Fig. 1 is a principle block diagram of the present invention, Fig. 2 is an explanatory diagram of one embodiment of the present invention, Fig. 3 is an explanatory diagram of another embodiment of the present invention, and Fig. 4 is an explanatory diagram of an embodiment of the present invention. FIG. 5 is a detailed explanatory diagram of the present invention; FIG. 6 is an explanatory diagram of a conventional PAD accommodation system; FIG. 7 is a functional block diagram of a conventional HDLC control section; Figure 9 shows the frame format of information used in the HDLC procedure, Figure 9 shows the types of commands in the HDLC procedure, Figure 10 shows the types of responses in the HDLC procedure, and Figure 11 shows the FIG. 2 is a diagram showing packets used in the V.25 data transfer procedure. 21...HDLC terminal, 22...Host computer, 23...Line, 26...PAD. 27... Link disconnection control unit.

Claims (1)

[Claims] 1. HDLC terminal (1) and packet assembly and disassembly means (2)
The HDLC control means (3) provided between the HDLC terminal (1) issues a start request to the packet assembly/disassembly means (2) in response to the link setting request from the HDLC terminal (1), and A data communication system characterized in that a link disconnection request from (1) is used as an opportunity to issue a termination request to the packet assembly/disassembly means (2).