JPH01288040A - Data transmission equipment - Google Patents

Abstract

PURPOSE:To urge the release of a busy state and to obtain a data transmitter with excellent communication quality by providing a buffer memory monitor section so as to identify the ready state and the busy state of the buffer state thereby using P-bit control of a link level procedure. CONSTITUTION:A buffer memory monitor section 6 references a management table of a buffer not in use in steady state, brings the buffer state into a busy state when number of buffers not in use is a prescribed number or below relating to the operating state of the buffer and production 9 of the buffer busy state is informed to a link level processing section 4. In case of buffer busy state, the link level processing section 4 sends one frame 13 with a P-bit 15 set to an opposite terminal equipment 7 if a transmission data 11 is generated from a packet level processing section 3. Thus, without incurring the deterioration of the data transmission efficiency and the link level processing efficiency of a line due to the increase in the redundant response frame, the decrease in the buffer memory is prevented and the busy state is quickly released.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] This invention complies with CCITT Recommendation X-25 Level 2-LAP
P/B specified in link level procedures such as B and HDLC.
The present invention relates to a data transmission device that implements a transmission procedure based on a procedure having an F-bit checkpointing function.

[Prior Art] FIG. 3 is a block diagram showing a conventional data transmission device.
37) is a data transmission device, and (7) is a partner terminal connected to the data transmission device (37) via a line (8).

This data transmission device (37) is a line interface section (hereinafter referred to as line 1) that transmits and receives data signals on the line (8).
/F unit) (5), a buffer memory (2) that stores transmitted and received data, a link level processing unit (3g) that implements link level procedures with the other terminal (7), and implements packet level procedures. It is composed of a packet level processing section (3).

Next, the operation will be explained. When transmitting data, after the packet level processing unit (3) generates transmission data (39) on the buffer memory (2), the link level processing unit (3)
8) is notified of the transmission data (39). The link level processing unit (38) transmits the transmission order number N of the transmission data (39).
5 (17) and the expected reception number NR (15), and send data (39)! I-frame as a field (41
) and sends it to the other party's terminal (7).

When receiving data, ■ frame (42
) is received and stored in buffer memory (2). The link level processing unit (38) checks the transmission order number N5 (17) and expected reception number NR (16) of the ■frame (42), and converts one field data of this I frame (42) into reception data (40). The packet level processing unit (3) is notified as follows.

Figure 4 shows the link level processing unit (3) when receiving data.
8) explains the detailed operation of ■Frame (43
), the received data (
When the transmission data (45) is generated from the packet level processing unit (3) that received the received frame (44), it updates the expected reception number NR of the ■ frame (46) and transmits it.
43) Confirm the response.

On the other hand, after receiving the ■ frame (47), the received data (48) is output to the packet level processing unit (3), and if no transmission data is generated from the packet level processing unit (3) within the response transmission time (T2). , if above! RR frame with updated expected reception number NR as a response to frame (47) (
49) and confirm the response.

Figure 5 shows the maximum outstanding I-frame number (N3
) is 4, the detailed operation of the link level processing unit (38) during data transmission is explained.
If this occurs, ■ After sending frames (51a) to (51d), R containing the expected reception number NR indicating response confirmation is sent.
After receiving the R frame (52), the transmitted data (50a) of the ■ frame (51a) ~ (51d) ~
(50d) can be released from the buffer memory (2). In addition, it is possible to transmit I frames (53a) to (53d) as many as the maximum outstanding number (N3), and similarly, I frames (53a) to (53d) including the expected reception number NR (
54), the transmitted I frame (53a) ~
The transmission data (50e) to (50h) of (53d) can be released from the buffer memory (2), and then the transmission data (50h) can be released from the buffer memory (2).
0i) can be transmitted as an I frame (55).

[Problems to be Solved by the Invention] Since the conventional data transmission device is configured as described above, when a large amount of data is continuously transmitted, the number of frames that can be transmitted continuously without confirming the response is limited to , up to the maximum number of outstanding I frames (N3), and upon receiving a ■ frame or RR frame indicating a response confirmation from the other terminal, it becomes possible to release the buffer memory for the transmission data of the first I frame transmitted, and the next I frame transmission becomes possible.

However, when a large amount of transmission data occurs, the free space in the transmission data storage buffer memory decreases, so it is necessary to release the transmission data memory buffer. If you send an I frame with OFF, it indicates a response acknowledgment! Since the reception of frames and RR frames depends on the operation of the other terminal, there is a problem in that the buffer memory becomes busy.

Also, when transmitting data is generated, all ! When transmitting frames, there were problems such as the number of response frames increased and the data transmission efficiency of the line deteriorated, and the link level processing unit increased redundant response frame processing, reducing link level processing efficiency. .

This invention was made with the aim of solving the above-mentioned problems, and it is possible to reduce buffer memory without deteriorating line data transmission efficiency or link level processing efficiency due to an increase in redundant response frames. prevent,
An object of the present invention is to obtain a data transmission device that quickly releases a busy state.

[Means for Solving the Problems] A data transmission device according to the present invention includes a buffer memory monitoring unit that monitors the usage status of a data storage buffer memory and determines whether the buffer memory is in a busy state or a ready state;
The apparatus further includes a link level processing section that controls the P bit of the transmitted l frame according to the busy state and ready state of the buffer memory.

[Function] The data transmission device according to the present invention uses a buffer memory monitoring unit to monitor the usage status of the buffer memory, and when in the ready state, reduces the number of response frames to transmitted l frames to improve line usage efficiency and link level processing efficiency. In addition, during a busy state, increase the number of response frames to the transmitted l frame to free up the buffer memory in use and promote the transmission of generated transmission request data, thereby preventing the buffer memory from decreasing and canceling the busy state. is possible.

[Example] An example of the present invention will be described below with reference to the drawings. 1st
In the figure, (1) is a data transmission device, and this data transmission device (1) includes a buffer memory (2) that stores transmitted data and received data, and a packet level processing unit (2) that implements packet level procedure processing of transmitted and received data. 3) Link level processing unit (4) that implements link level procedure processing
, line 1/F section (5) that realizes data transmission and reception to the line
, a buffer memory monitoring unit (6) that constantly monitors the usage status of the buffer memory (2), determines whether the buffer memory is in a busy state or has returned to a ready state, and notifies the link level processing unit (4); It is made up of. (7)
is a partner terminal communicating with the data transmission device (1), and both (1) and (7) are connected via a line (8).

(9) to (14) show the flow of communication data and control data between the packet level processing unit (3), link level processing unit (4), buffer memory monitoring unit (6), and partner terminal (7). , (9) are control data indicating the occurrence of buffer busy, (10) are control data indicating buffer busy recovery, (11) and (12) are packet level processing unit (3
) to the link level processing unit (4),
(13) and (14) indicate l frame data sent from the data transmission device (1) to the partner terminal (7), and (15)
, (16), (17) are l frames (13), (14)
P bit information, expected reception number NR, transmission sequence number NS
shows.

Next, the operation will be explained with reference to FIG. The buffer memory (2) is configured as a collection of fixed-length data buffers, and is classified into unused buffers, packet-level processing data buffers, link-level processing data buffers, and line transmission/reception data buffers depending on the data content. The number of corresponding data buffers is displayed in the buffer management table.

The buffer memory monitoring unit (6) regularly refers to the management table of unused buffers to check the usage status of the buffers, and when the number of unused buffers falls below a certain number, sets the buffer status to a busy status. The occurrence (9) is notified to the link level processing unit (4).

When the link level processing unit (4) is in the buffer busy state, the link level processing unit (4) receives the transmission data (11) from the packet level processing unit (3).
) occurs, an l frame (13) with the P bit (15) turned on is transmitted to the other party's terminal (7).

Further, when the number of unused buffers exceeds a certain level, the buffer memory monitoring unit (6) sets the buffer state to a ready state and notifies the link level processing unit (4) of buffer busy recovery (1o). If transmission data (12) is generated when the buffer is in a ready state, the link level processing unit (4) transmits an l frame (14) with the P bit (15) turned off to the partner terminal (7).

FIG. 2 is an explanatory diagram of data transmission and reception operations when the buffer state is in the ready state and in the busy state. When the buffer memory (2) is in the ready state, the transmission data (18
) occurs, the link level processing unit (4) transmits an l frame (20) with the P bit off to the partner terminal (7),
If transmission data occurs within (T2) seconds at the other party's terminal (7), delivery of the l frame (20) can be confirmed by the NR of the l frame (21).

Further, when transmission data (23) is generated from the packet level processing unit (3) that has received the reception data (22), an l frame (24) is transmitted from the link level processing unit (4). After transmitting l frame (24), if no transmission data is generated in (T2) seconds at the other end terminal (7), (
After T2) seconds have elapsed, the RR frame (25) is received, and delivery can be confirmed by the NR of the RR frame (25).

In this way, when the buffer memory (2) is in the ready state, the number of packets for delivery confirmation is reduced, and communication can be realized with low line usage efficiency and link level processing efficiency.

Next, if the buffer memory (2) becomes busy, the buffer memory monitoring unit (6) will switch to the link level processing unit (
4) is notified of the busy occurrence (26), and after that,
Transmission data generated from the packet level processing unit (3)
27) is sent as an l frame (28) with the P bit turned on, and the other terminal (7) receives the l frame (28).
follows the link-level procedure to create an RR frame (28) with the F bit on for one frame (28) with the P bit on.
29) at the earliest possible timing, and this RR
The NR of frame (29) confirms the delivery of frame (28), and the buffer memory (2) can be released quickly.

In addition, when transmission data occurs continuously, among the generated transmission data (30a), (30b), and (30c),
The first transmission data (30a) and (30b) are transmitted as P and off l frames (31a) and (31b),
The last transmission data (30c) is transmitted as an l frame (31C) with the P bit on, and the last l frame to be transmitted continuously
By setting the P bit on only in frame (31c), all l frames (31a), (31b), (31c)
The delivery is confirmed using the RR frame (32) with the F bit on, and the buffer memory (2) is released. Similarly, when transmitting the outstanding number of l frames, only the last frame is transmitted with the P bit turned on.

When the buffer memory (2) returns to the ready state,
The buffer memory monitoring unit (6) is connected to the link level processing unit (4).
) is notified of busy recovery (33), and after that,
Returning to the operation when the buffer memory (2) is in the ready state, when transmission data (34) is generated from the packet level processing unit (3), one frame (3
5), and after (T2) seconds have elapsed at the other end terminal (7), the RP frame (36) is transmitted.

[Effects of the Invention] As described above, according to the present invention, a buffer memory monitoring unit that monitors the usage state of the buffer memory is provided, and the P bit control of the link level procedure is performed by identifying the ready state and busy state of the buffer state. Since it is configured to use , it is possible to achieve communication with high line usage efficiency and link-level processing efficiency when in the ready state, and to speed up the release of the transmission buffer memory and facilitate communication to release the busy state during the busy state. This has the effect of providing a data transmission device with good communication quality.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a data transmission device according to an embodiment of the present invention, and FIG. 2 shows when the data transmission device according to the present invention is used and the buffer state is in the ready state.
FIG. 3 is a block diagram showing the configuration of a conventional data transmission device; FIG. 4 is an explanatory diagram of data reception; and FIG. 5 is an explanatory diagram of data transmission. . In the figure, (1) is a data transmission device, (2) is a buffer memory, (3) is a packet level processing unit, (4) is a link level processing unit, (5) is a line interface, (
6) is the buffer memory monitoring unit, (7) is the other party terminal, (8
) is a line. In addition, in the figures, the same reference numerals indicate the same or equivalent parts. Agent: Patent Attorney Masuo Oiwa (and 2 others) Figure 2: Explanation diagram of data transmission/reception operations according to this invention Figure 4: Explanation of data reception operations Figure 4: Explanation of data transmission operations Procedural amendment (self-motivated) November 5, 1939 Day

Claims (1)

[Claims] In a data transmission device connected to a partner terminal via a line, a line interface unit that transmits and receives data signals on the line, a packet level processing unit that implements a packet level procedure, and a battery memory for data storage;
a buffer memory monitoring unit that monitors the usage status of the battery memory; and a buffer memory monitoring unit that determines whether the status of the buffer memory is busy or ready;
The above link level procedure is realized, and a response frame is requested from the other terminal by transmitting the transmission data as an I frame with the P bit on, and when in the ready state, the transmission data is transmitted as an I frame with the P bit off, and a response is sent. 1. A data transmission device comprising a link level processing unit that realizes communication in which frame transmission is left to the other terminal.