JPS59204341A - Communication system - Google Patents

Abstract

PURPOSE:To equalize traffic among stations connected to a common transmission line by allowing each station to control the transmission of data packets according to the in-use state of the transmission line and the traffic of the station. CONSTITUTION:Packet transmission control circuits 57 are provided to respective stations ST in a system which performs communication among plural stations ST connected to the common transmission line. Each ST monitors a signal on the transmission line all the time by its signal detecting circuit 47 and sends out its detection signal to a circuit 57 and a transmission control circuit 41. The circuit 57 judges the in-use state of the transmission line from the detection signal and varies the delay time of data packet transmission according to the traffic of the ST and the priority level of information. This information is sent to a CPU54, and data packets stored in a transmitting buffer 40 through the circuit 41 under the control of the CPU54 are sent out to the transmission line through a parallel-series converting circuit 44 and a transmitting circuit 45.

Description

[Detailed Description of the Invention] Industrial Application Field The present invention connects a plurality of stations through a common transmission path, and when a station sends out information, if there is no signal on the transmission path, the information is immediately sent to the transmission path. related to communication systems.

Conventional configuration and its problems FIG. 1 shows an example of the configuration of a conventional communication system.

In FIG. 1, 1 and 2 are terminal devices, 3 is a transmission line, 4 to 8 are taps, 10 to 14 are stations, and 20 to 27 are terminal devices such as computers, facsimiles, telephones, etc. These terminal devices 20-27 can communicate with each other via station controllers 10-14 to which they are connected.

FIG. 2 shows an example of a frame structure of a data packet in a conventional communication system. In FIG. 2, 30 is a start delimiter, 31 is a receiving address, 32 is a source address, 33 is a control section, 34 is information, 35 is a frame check section, and 36 is an end pre-limiter.

FIG. 3 shows an example of the configuration of a transmission/reception control section of a stage generator in a conventional communication system. 40 is a transmission buffer, 41
4 is a transmission control circuit, 42 is a frame check code creation circuit, and 4 is a transmission control circuit;
3 is a delimiter addition circuit, 44 is a parallel-serial conversion circuit, 45 is a transmitting circuit, 46 is a receiving circuit that performs synchronization and waveform shaping, 47 is a signal detection circuit, 48 is a collision detection circuit,
49 is a serial-parallel converter circuit, 50 is a de-IJ miter and address decoder, 51 is a frame inspection circuit,
52 is a reception control circuit, 63 is a reception buffer, 54 is Cp
U, 55 is a timer, and 66 is a DMA controller.

Communication between these stations 10-14 is performed as follows. Now, the station 10 is the terminal device 20
When the CRU 54 receives a transmission request from the terminal device 26 connected to the station 14, the DMA controller 66 transfers the information from the terminal device 20 to the transmission buffer 4o, and then issues a transmission request to the transmission control circuit 41. Enter the sending state. Station 10 enters transmitting state
The signal detection circuit 47 monitors the signal on the transmission path, and if there is no signal, the information (hereinafter referred to as data packet) packetized by the frame check code creation circuit 42 and delimiter addition circuit 43 is sent to the parallel-serial conversion circuit 4.
4, the signal is subjected to parallel-to-serial conversion and transmitted to the transmission line via the transmitting circuit 45.

If a signal is detected on the transmission path, the data packet is sent out after waiting for the signal to disappear on the transmission path.

By the way, each station monitors the transmission path with its own signal detection circuit 47, and sends out data packets as soon as the signal disappears. Therefore, if multiple stations simultaneously receive a transmission request from a terminal device and transmit data, When packets are transmitted, data packets collide on the transmission path.

A station that is transmitting a data packet monitors collisions on the transmission path using a collision detection circuit 48, and when a collision is detected, it stops transmitting the data packet, waits for an appropriate period of time that varies depending on the station, and then restarts the transmission. Send data packets. In this way, the above operation is repeated until the transmission is successful.

On the other hand, Stashore 1 which is not transmitting data packets
1 to 14 also monitor the signal on the transmission path by the signal detection circuit 47, and compare the receiving address of the data packet received by the decoder 60 with the address of the own station. If the address matches the address of the own station, the reception control circuit 5 is notified of the reception of the data packet. While the reception control circuit 52 stores the received data packet in the reception buffer 53, the frame check circuit 61 performs an error check on the received data packet. If an error is detected, the data packet is discarded.

If there is no error, the reception control circuit 52 notifies the CpUE 54 that the data packet has been received. CpU
54 notifies the terminal device 26 that the data packet has been received, and uses the DMA controller 56 to transfer the information stored in the reception buffer 63 to the terminal device 26.

In this way, the data packet sent from station 10 is sent to station 14, and a series of communications is completed. This communication control method is used as CSMA/CD
(Carr 1erSense Multiple
Access with Co11ision Dete
This is called the ction) method.

In such a communication system, data packets are sent as soon as there is no signal on the transmission path, so as the amount of traffic in the entire communication system increases, collisions between data packets increase. This results in the disadvantage that the transmission efficiency of the system is reduced.

As a method for improving this drawback, a method has been proposed in which when a station sends out a data packet, the sending of the data packet is controlled according to the usage status of the transmission path. In this type of system, when each station detects that the transmission path is frequently used, it packetizes the information transferred from the terminal device and immediately issues a transmission request to the transmission control circuit 41. The amount of traffic in the system is adjusted by issuing transmission requests.

By the way, this method does not take into account the traffic volume of each station itself, so every station performs the same transmission control depending on the usage status of the transmission path, resulting in variations in the traffic volume between stations. However, this method has the disadvantage of causing an overflow of the stage buffer.

OBJECTS OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to perform system traffic control without causing variations in the amount of traffic between stations.

Structure of the Invention The present invention controls the transmission of data packets for each station, taking into account not only the usage status of the transmission path but also the traffic volume of the own station, thereby controlling the system traffic. .

DESCRIPTION OF EMBODIMENTS An embodiment of the present invention will be described. The present invention is not concerned with the form of the communication system, the transmission path, the number of stations and the number of terminals connected to the system. For ease of explanation, the bus-type communication system shown in FIG. 1 will be explained here as an example.

The present invention is characterized in that data packet transmission is controlled for each station based on the usage status of the transmission path and the traffic volume of its own station, and is essentially unrelated to the data packet transmission control method. . Data packet transmission control methods include a method of delaying the transmission request to the transmission control circuit 41 as described in the conventional example section, and a method of determining whether or not to issue a transmission request to the transmission control circuit 41 using random numbers, and transmitting the data packet. There are methods to statistically limit requests.

Here, explanation will be given using the former method.

FIG. 4 shows an example of the configuration of a transmission/reception control section of a station in a communication system according to the present invention. It should be noted that since most of the configuration is the same as in FIG. 3, the same components are given the same numbers and their explanations will be omitted. The difference is that a data packet sending control circuit 57 is provided. This will be explained in detail in conjunction with FIG.

Data packet transmission control is performed by changing the delay time when transmitting data packets corresponding to the data packet transmission control state of the station, which changes depending on the usage status of the transmission path and the traffic amount of the own station. Here, the following three data packet transmission control states are shown: State I: Data packet transmission promotion state ■: Normal data packet transmission state ■: Data packet transmission restriction.

Here, three states are used, but essentially there is no problem with any number of states or consecutive states. In addition, here, the usage status of the transmission path is categorized into three stages (the usage status of the transmission path is dense, normal, and sparse).
Although the traffic amount of the own station is set to three levels (the traffic amount of the own station is dog, normal, and small), there is essentially no problem with any number of levels or continuous values.

FIG. 6 shows a state transition diagram between each state. In FIG. 6, DI, D2. For D3, the transmission path usage status is dense,
Normally, when it is sparse, it becomes "1", and TI, T2, T3
becomes "1" when the traffic volume of the own station is large, normal, and small, respectively. The arrow indicates the state transition direction, and the expression on the arrow is a logical expression indicating the transition condition. When the logical expression is equal to "al", the transition is performed. Here, + is logical sum, ・ is logical product, and is negative Next, the state transition diagram shown in FIG. 6 will be explained.

First, if the station is in state engineering.

If the usage of the transmission path becomes dense, if the traffic volume of the own station is normal or small, the state will be entered in order to limit the sending of data packets, but if the traffic volume of the own station is large, then the state will be entered. In some cases, the station moves to state H and does not restrict the transmission of data packets in order to prevent buffer anomaly overflow of its own station while considering the amount of traffic in the system.

If the transmission path usage is normal and the traffic volume of the own station is high, the station will remain in a state of control to prevent overflow of the own station's buffer and promote the sending of data packets. If the traffic volume of its own station is normal or small, it enters state ■.

If the usage of the transmission path becomes sparse, the station stays in state I regardless of the traffic volume of its own station, promoting the transmission of data packets.

Next, when the station is in state 1, if the transmission path usage becomes dense, the station enters state 2 in order to limit the transmission of data packets regardless of the traffic amount of the station itself.

If the transmission path usage is normal, if the traffic volume of the own station is small, the state controller will be used to promote the sending of data packets, but if the traffic volume of the own station is normal or small, In some cases, it is returned to state ■.

If the data usage status is sparse, if the traffic volume of the own station is large or normal, it will enter state 1 to promote the sending of data packets, but if the traffic volume of the own station is small. remains in state H.

Finally, if the station is in state 111.

If the usage of the transmission path becomes dense, the station remains in state (2) in order to limit the transmission of data packets regardless of the traffic volume of the own station.

If the usage status of the transmission path is normal, if the traffic volume of the own station is large or normal, the state will be entered into state (2), but if the traffic volume of the own station is small, the state will remain in state (2).

If data usage is sparse, the station enters state I in order to promote the transmission of data packets regardless of the traffic volume of the own station.

Such state transition processing is performed by the data packet transmission control circuit 60. FIG. 6 shows an example of the configuration of the data packet sending control circuit 60.

The transmission path usage status is determined by integrating the signal obtained from the signal detection circuit 47 through the signal line 61 in the integration circuit 62, converting it into transmission path usage efficiency in the division circuit 64 via the 8-bit signal line 63, and converting the signal into an 8-bit signal. Holding circuit 66 via signal line 66
is held until the next integration period. This integration period is given by counting circuit 67 counting clock signal 68 . When the kidney number circuit 67 counts a certain number, it notifies the integration circuit 62, the division circuit 64, and the holding circuit 66 that the integration period has ended through the signal line 69, and the contents of the holding circuit 66 are rewritten.

The traffic volume of the own station is determined by counting the sum of the number of transmission requests from terminal devices connected to the station and the number of packets on the transmission buffer using a counting circuit To. The value of the counting circuit TO is inputted through the signal line 71 every time the terminal device makes a transmission request, and "1" is added to the value of the counting circuit 70, and the signal is input every time the station succeeds in transmitting a transmission path packet. A signal is input by line 72 to subtract 1" from the value of counting circuit 70.

The number of unprocessed packets of the own station held by the counting circuit 7o is transmitted to the state transition processing circuit 75 through 8-bit signal lines 73 and 74.The three-state transition processing circuit 76 divides the usage status of the transmission path into three stages. (The transmission path usage status is
After converting the traffic volume of the own station into three stages (the traffic volume of the own station is large, normal, small), the current state held by the holding circuit 76 is transferred to the 2-bit signal line. 77 and the above three pieces of information, a new state to be transitioned to is determined according to the state transition diagram shown in FIG. The contents of the holding circuit 76 are the 2-bit signal line 7
8 to the CPU 54, and the CPU 54 controls the transmission of data packets by waiting a certain period of time before issuing a transmission request to the transmission control circuit 41 according to the data packet transmission state indicated by the holding circuit 76.

In this way, the transmission of data packets is controlled based on the usage status of the transmission path and the traffic volume of its own station. At this time, each station controls the transmission of data packets by taking into account the traffic volume of its own station. It is possible to control system traffic without causing variations in the amount of traffic held by each station.

Next, another embodiment of the present invention will be described. - In the previous embodiment, similar transmission control was performed for all data packets, but it is possible to set multiple priority levels and perform transmission ratio control according to the content of the data packet information. . For example, in the case of information that requires immediacy, such as voice information, it is undesirable to delay the transmission of data packets just because the amount of system traffic increases. Therefore, we divide the information into two types: voice information and other information.For voice information, we do not delay the sending of data packets regardless of the transmission path usage status or the traffic volume of our own station, and only information other than voice information is transmitted. Depending on the usage status of the transmission path and the amount of traffic at its own station, it is possible to control the transmission of data packets, process audio information preferentially, and control system traffic as shown in the previous embodiment.

Effects of the Invention In this manner, system traffic control can be performed without varying the amount of traffic between stations.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing an example of the configuration of a conventional communication system, Fig. 2 is a diagram showing an example of the configuration of a data packet frame in the conventional communication system, and Fig. 3 is the configuration of a transmission/reception control unit of a station in the conventional communication system. Illustration showing an example, 4th
5 is a diagram showing an example of the configuration of a transmission/reception control unit of a station in a communication system according to the present invention, FIG. 5 is a diagram showing an example of a state transition diagram of a data packet transmission control state of a station according to the present invention, and FIG. FIG. 2 is a diagram illustrating a configuration example of a data sending control circuit in FIG. 67...Data packet transmission control circuit, 62.
... Integration circuit, 64 ... Division circuit, 66
...Holding circuit, 67...Counting circuit, 7
0... Counting circuit. Name of agent: Patent attorney Toshio Nakao and 1 other person No. 5
Figure 030 D2・TI “DS eT3 tl) 2-r & 6th
figure

Claims (2)

[Claims] (1) Multiple stations are connected via a common transmission path, and each station constantly monitors the signals on the transmission path, and each station sends data packets depending on the usage status of the transmission path and the amount of traffic at its own station. A communication system characterized by performing control and controlling system traffic. (2) System traffic is controlled by setting a priority level for information and controlling the transmission of data packets for each station based on the usage status of the transmission path, the traffic volume of the own station, and the priority level of the information. A communication system according to claim 1.