JPH0662469A - Preferential transmission processing system - Google Patents

Abstract

PURPOSE:To improve the throughput by preferentially transmitting data, whose degree of importance is high, within a limited transmission speed at the time of using the data communication to participate in the processing of a computer in a remote place or controlling and monitoring an apparatus in a remote place. CONSTITUTION:This system consists of a central processing unit 2, a communication control processing device 1, and a modem 3. The communication control processing device 1 consists of a transmission control part 4, a preferential transmission scheduler part 5, a pool buffer 6, and a reception buffer 7. Transmission data is scheduled in the communication control processing device 1 to transmit transmission data from data having a high priority level.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a priority transmission processing system, particularly when it is involved in processing of a computer at a remote place by using data communication, or when controlling and monitoring equipment at a remote place.
The present invention relates to a priority transmission processing method that enables priority transmission of highly important data within a limited transmission rate range.

[0002]

[Prior Art] The Electric Cooperative Research Society September 1991 2
The “Electrical Cooperation Research Vol. 47 No. 2” published daily lists the following as means for improving control and response and speeding up monitoring data.

A. Shorten the transmission data length. For this data length, long data is divided and transmitted depending on the transmission rate, expected value of response, and the like.

B. Data having a low transmission level and a long transmission data length are divided as described above and transmitted at regular intervals. See the description such as "low-speed low-cycle measurement data" in the above cited document.

C. High-level data link control procedure Asynchronous balanced mode (hereinafter abbreviated as HDLC-ABM)
Set the number of outstanding frames to "1".

D. The priority of editing and transmission processing is set for each transmission data type.

A central processing unit (hereinafter C
When priority processing is performed within PU (abbreviated as PU), it is impossible to register a plurality of transmission data in a communication control processing device (hereinafter referred to as CCP). For example, if two pieces of transmission data are registered in the CCP in descending order of priority,
When the 3rd transmission data is generated in the CPU while the 1st data is being transmitted, and this has a higher priority than the 2nd transmission data, the 2nd transmission data has not yet been transmitted. Despite this, the third data cannot pass the second transmission data.

In addition, since the protocol is restricted such that the number of outstanding frames is fixed to 1, the transmission efficiency is lowered depending on the protocol.

Particularly, when the transmission speed is low, the frequency of reception from the partner station is high, or the reception data length is long, it appears briefly.

[0010]

When HDLC-ABM is used and the number of outstanding frames is set to "1", the next transmission cannot be performed until "RR response" or "I frame" is received after data transmission. Transmission efficiency decreases.

The application program of the CPU is
Since the priority is compared and the transmission data is registered in the CCP for each data transmission, not only the CPU load becomes heavy, but also an extra space is generated between the transmission data.

To solve the above problems, preferentially transmit data of high importance in the system, aiming at high transmission efficiency, improvement of throughput, and reduction of CPU load.

[0013]

Means for Solving the Problems The next transmission data is scheduled in the CCP every time data transmission is completed. A pool buffer is provided in the CCP to facilitate the scheduling. When it occurs, by registering it in this, the CCP automatically sends out transmission data with a high priority.

When an overtaking occurs between transmission data of the same type in the CCP, the transmission of the transmission data of lower priority is locked.

[0015]

The flow of transmission data is shown in FIG. CPU is C
When registering the transmission data in the CP, the priority transmission level and the data type are added, and the CCP performs the scheduling based on the priority transmission level, so that the transmission data having the higher priority is transmitted.

[0016] Also, overtaking between transmission data of the same type by using the data type at the time of pool buffer registration (before and after data)
Is detected, transmission lock of transmission data with a low priority transmission level is performed.

Incidentally, long transmission data is divided into appropriate data lengths as in the conventional case, so that an opportunity to transmit transmission data of higher importance can be obtained.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a block diagram of an HDLC type remote monitoring control device to which the present invention is applied. This device is CPU2, CC
It is composed of P1 and modem 3. The inside of the CCP 1 is composed of a transmission control unit 4, a priority transmission scheduler unit 5, a pool buffer 6 and a reception buffer 7.

When transmitting, the CPU 2 stores the edited transmission data in the pool buffer 6 of the CCP 1. At this time, the priority transmission level and the data type are added. However, since the priority transmission level and the data type are excluded when transmitting to the line, transparency can be maintained. If the transmission data length exceeds a certain range, it is stored in the pool buffer 6 after division.

The transmission controller 4 supports a transmission protocol and performs a data link with a partner station. In this embodiment,
HDLC-ABM is used as a transmission protocol.

When the CPU 2 stores the transmission data in the pool buffer 6, the priority transmission scheduler section 5
Scheduling is performed based on the added priority transmission level, and transmission data to be transmitted next is determined. However,
If the transmission control unit 4 is not transmitting at the time when the transmission data is stored in the pool buffer 6, the transmission is immediately performed. If a plurality of transmission data exist in the pool buffer 6 at the time when the transmission is completed, the transmission control unit 4 next transmits the transmission data determined by the priority transmission scheduler unit 5.

The following rules are applied to the scheduling performed by the priority transmission scheduler section 5.

A. The priority transmission levels are compared, and the transmission data with the highest level is given the highest priority.

B. In case of the same priority transmission level, the first-come-first-served priority is given.

C. When overtaking occurs between transmission data of the same data type, the transmission of the transmission data with the lower priority transmission level is locked. (Deleted from the pool buffer 6.) In the present invention, the transmission data generated by the CPU 2 is immediately registered in the pool buffer 6 of the CCP 1, and the priority transmission scheduler unit 5 registers a plurality of transmission data at the same time for scheduling. Is possible. As a result, the number of outstanding frames of HDLC-ABM can be set to 2 or more. That is, a plurality of pieces of transmission data can be sent without waiting for confirmation of a response from the partner station, so that transmission efficiency can be improved.

When overtaking occurs between transmission data having the same data type and different priority transmission levels, transmission of transmission data having a low priority transmission level is locked. For example,
If you want to send the same data periodically and also when the data changes, by setting the priority of the "transmission on change" to a higher priority than the "periodical transmission", the "transmission on change" Priority is sent. The "periodic transmission" overtaken at this time locks the transmission to prevent the front and back of the data.

FIG. 3 shows an embodiment of priority transmission processing.

In this figure, the priority transmission levels are from level 1 to level 8, level 1 is the highest level, and the higher the number, the lower the level. Further, as the data type, a total of seven types a to g are used.

The time chart shows the passage of time from left to right in the figure, and shows how individual transmission data is generated, is registered in the pool buffer, and is transmitted to the line.

In the figure, the transmission data of data type d and level 4 is delayed in the pool buffer until the transmission of other high level data is completed.

Further, when the transmission data of data type e and level 5 is registered in the pool buffer, there is transmission data of the same data type and lower in level than the data already registered in the pool buffer. Data is being deleted from the pool buffer.

[0032]

According to the present invention, since scheduling is performed in the communication control processing device, there is no limitation that a specific transmission protocol must be used, and by using a transmission protocol having high transmission efficiency, priority transmission processing can be performed. It is possible to achieve both high transmission efficiency.

By providing a pool buffer in the communication control processing unit and performing scheduling, the load on the central processing unit is reduced.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a priority transmission processing method that is an example of the present invention.

FIG. 2 is a transmission data flow chart showing a flow of transmission data in the present invention.

FIG. 3 is a priority transmission processing time chart showing an embodiment of the present invention.

[Explanation of symbols]

1 ... Communication control processing unit (CCP), 2 ... Central processing unit (C)
PU), 3 ... Modem, 4 ... Transmission control unit, 5 ... Priority transmission scheduler, 6 ... Pool buffer, 7 ... Reception buffer.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Ken Saito 5-2-1 Omika-cho, Hitachi-shi, Ibaraki Hitachi Ltd. Omika factory

Claims (2)

[Claims] 1. In a system for performing data communication by connecting one or more communication control processing devices to a central management device, a plurality of transmission data generated in the central processing device and assigned different priorities. Is a method in which the communication control processing unit automatically performs scheduling based on the priority order and sends the data in descending order of priority. In the scheduling, the communication control processing unit receives transmission data from the central processing unit. A priority transmission processing method, which is carried out every time, and when the transmission of the transmission data currently being transmitted ends, the transmission of the transmission data having the highest priority among the transmission data waiting to be transmitted next is started. 2. The scheduling according to claim 1, wherein when the transmission data of high priority overtakes the transmission data of low priority that has occurred immediately before by scheduling, if the corresponding two transmission data are of the same type, the partner station Priority transmission processing method characterized by locking the transmission of low priority transmission data in this event in order to prevent the reception data from lagging behind.