JPH054356Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The present invention relates to a data network using communication lines, and in particular to a protocol suitable for a lower-level data network with a small number of connections and a small amount of data exchanged. .

(Prior Art) A data network for a process is known, for example, from Yokogawa Technical Report Vol. 1.26 (1982) p. 198. In such a data network, a token passive method is adopted as a protocol.

This method allows a large number of connected stations to be connected and also ensures immediacy of communication.

(Problems that the invention attempts to solve) However, the conventional communication system has the following problems.
That is, since the management of tokens is complicated, the configuration is complicated and expensive. Therefore, in view of the fact that it cannot be adopted in small-scale data networks due to the heavy burden, and there is no problem even if the immediacy of communication is sacrificed,
A simple data network was desired.

This invention solves these problems,
The purpose is to provide an inexpensive data network for small scale use.

(Means for Solving the Problems) The present invention that achieves the above purpose includes a transmitting/receiving circuit that sends and receives data to and from other stations via a communication line, and a line that determines whether the communication line is busy or idle. When the line monitoring means determines that the communication line is free, it transmits a record consisting of its own station's identification code (i) and fixed length data to other stations at a predetermined bit rate via the transmitting/receiving circuit. In this data network, each station is equipped with communication command means for storing records sent from transmitting station (j) in memory during a call, and the following components are added to each station.

That is, a buffer memory for file storage is provided which has a record length determined corresponding to the fixed length of the data and stores a predetermined number (k) of records to which codes corresponding to the identification codes of each station are assigned.

Next, as a timer, if the identification code of the own station is (1) and the identification code of the record being received is (k), the identification code is regarded as (0), and the identification code of the record being received is The code is (i-1)
is started after the end of the record and the first
a first timer that measures the time (T1), and a second timer that is activated after the end of the record if the identification code of the record being received is not (i-1) and measures the second time (T2); , a third timer is provided that is activated after the end of the record and measures a third time (T3) if an error occurs during reception.

Furthermore, the first timer uses the above timer.
Transmission management means transmits its own record after the second timer times out, and when the second timer times out, the identification code (j) of the received record is regarded as the identification code (j+1), and (j+1) becomes (i).
If it is equal to, start the first timer and (j+1)
If different from (i), the air station processing means starts the second timer, and if a timeout occurs in the third timer, the identification code (j) of the record before the reception error occurs is regarded as the identification code (j + 2), and ( If (j+2) is equal to (i), start the first timer and (j+2) is equal to (i).
Error handling means is provided for starting a second timer if the error is different.

In addition, a predetermined time (k x T2) when starting up your own station.
If the communication line is free, it is assumed to be the identification code (0) and the second timer is started, and if there is communication within this time, the identification code (j) is read and (j) becomes (i).
If (j) is equal to (i), the first timer is started, and if (j) is different from (i), the second timer is started.

Then, the setting time of each timer (T1<T3<
T2), T1 is made shorter than the transmission time of one record, and the line monitoring means clears each timer.

(Function) The buffer memory stores each station's identification code (1≦i≦
k) has a record storage space in one-to-one correspondence, and can support up to k connected stations.

At startup, the initial processing means is used.

If the identification codes between stations are consecutive, the first
This is handled by a timer and transmission management means.

If the identification codes between stations are not consecutive, the second timer and empty station processing means are used to deal with the case.

When an error occurs, the third timer and error processing means are used to deal with it.

(Example) The present invention will be explained below using the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, one station consists of the following components. 10 is a transmitting/receiving circuit that sends and receives data to and from other stations via a communication line; 20 is a line monitoring means that determines whether the communication line is busy or idle; 30 is a communication command that operates based on information from the line monitoring means 10; When the means determines that the communication line is free, it transmits a record consisting of its own station's identification code (i) and fixed length (L) data to the other station at a predetermined bit rate (pbps) via the transmitting/receiving circuit. With,
During a call, records sent from transmitting station (j) are stored in memory. Note that the identification codes i and j are natural numbers, and are smaller than k written next. That is, 1
The selection is made so that ≦i≦k, 1≦j≦k, and the same identification code is not given.

40 has a record length determined corresponding to the fixed length (L) of communication data, and a predetermined number (k) assigned with a code corresponding to the identification code of each station.
A buffer memory for storing files that stores records, and has a capacity of at least L×k. still,
It is desirable that k is 100 or less.

41 indicates that the identification code of the record being received is (i-
1), a first timer that is started after the end of the record and measures a first time (T1);
It is good to save communication time by making T1 smaller than the transmission time of one record (p×L), and preferably about 10% to 50%. In addition, when the identification code of the own station is (1) and the identification code of the record being received becomes (k), the identification code is regarded as (0). 42, the identification code of the record being received is (i
−1), a second timer that is started after the end of the record and measures a second time (T2);
Preferably, T2 is about twice T1.
43 is a third timer that is activated after the end of the record when an error occurs during reception and measures a third time (T3), and preferably T3 is about 1.5 times T1. This result (T1<T3<T2)
has been established.

50 is a transmission management means that transmits the record of the own station after the first timer 41 times out.
Note that the transmission may be made before the first timer 41 times out. 60 is the second timer 4
When timeout 2 occurs, the identification code (j) of the received record is regarded as the identification code (j+1),
If (j+1) is equal to (i), the first timer 41 is started, and if (j+1) is different from (i), the second timer 42 is started.

Reference numeral 70 denotes an initial processing means used when starting up the own station. If the communication line is free for a predetermined time (k×T2), it regards the identification code as (0) and starts the second timer 42. If there is communication within this time, it reads the identification code (j), and if (j) is equal to (i), it starts the first timer 41. If (j) is different from (i), it starts the second timer 42.
The timer 42 is started.

80 is the identification code of the record before the reception error occurred when a timeout occurs in the third timer 43.
Considering (j) as the identification code (j+2), (j+2)
is equal to (i), starts the first timer 41 (j
+2) is an error handling means that starts the second timer 42 if it is different from (i).

The operation of the device configured in this way will be described next. FIG. 2 is a waveform diagram illustrating the operation of the device shown in FIG. 1. The identification code of each station in the diagram is #1,
Assume that #2 and #4 are used and #3 is multiplied.

First, #1 station transmits one record to the communication line. Then, after the communication ends, #2 station starts the first timer 41.
and the #4 station starts the second timer 42.

Station #2 transmits one record of its own station by the transmission management means 50 after T1 has elapsed. Therefore, the #4 station resets the second timer 42 and starts the second timer 42 again after the communication ends. Similarly, the #1 station starts the second timer 42 after the communication ends.

Station #1 detects the timeout of the second timer 42, and uses the vacant station processing means 60 to set the identification code to #3 and starts the second timer 42 again.
Station #4 detects the timeout of the second timer 42 and uses the air station processing means 60 to assign the identification code to #3.
Then, the first timer 41 is activated. #2
The station waits for the next communication to take place after the transmission is completed.

Station #4 transmits one record of its own station by the transmission management means 50 after T1 has elapsed. If k=4, the #1 station learns from the transmission management means 50 that it should transmit next, and starts the first timer 41 after the communication ends. If k>4, #1 station and #2 station update their identification codes one by one and continue to operate the second timer 42 until k is reached. Station #4 has the ability to perform the next communication after the transmission is completed.

According to the above configuration, one communication cycle T is given by the following equation.

T=(k-n)×T ₂ +k×T ₁ +L×p×n Here, n indicates the number of active stations, which is 3 here.

Next, let's talk about when an error occurs.

If an error occurs during reception, the third timer 43 is started after the end of the record and measures a third time (T3). When a timeout occurs in the third timer 43, the error processing means 80 regards the identification code (j) of the record before the occurrence of the reception error as the identification code (j+2), and if (j+2) is equal to (i), the first starts the timer 41, and (j+2) becomes
If it is different from (i), the second timer 42 is activated. still,
Since time T3 is set between times T1 and T2, if there is a station that has processed normally, communication will be performed before error processing, so error processing will be interrupted and normal processing will return.

The startup process is performed as follows.

If the communication line is idle for a predetermined period of time (k×T2), the initial processing means 70 regards the identification code as (0) and starts the second timer 42, and if there is communication within this period, the identification code ( Read j) and (j) becomes (i)
If (j) is equal to (i), the first timer 41 is started, and if (j) is different from (i), the second timer 42 is started.

In this way, the initiating station participates in the communication.

(Effects of the invention) As explained above, the invention has the following effects.

Since the configuration of each station is simple, an inexpensive data network can be constructed.

Each station consists of three timers, line monitoring means 20, and a simple sequence circuit, making it easy to integrate into LSI and suitable for mass production.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG. 2 is a waveform diagram illustrating the operation of the device shown in FIG. 10... Transmission/reception circuit, 20... Track monitoring means,
30...Communication command means, 40...Buffer memory, 41, 42, 43...Timer, 50...Transmission management means, 60...Air station processing means, 70...Initial processing means, 80...Error processing means.

Claims (1)

[Scope of claim for utility model registration] A transmitting and receiving circuit that sends and receives data to and from other stations via a communication line, track monitoring means that determines whether the communication line is busy or free, and this line monitoring means determines whether the communication line is free. If it is determined that there is a station, a record consisting of the own station's identification code (i) and fixed length data is transmitted to the other station at a predetermined bit rate via the transmitting/receiving circuit, and at the same time, during a call, the record sent from the transmitting station (j) is transmitted. In a data network in which each station is provided with a communication command means for storing the data in a memory, the data network has a predetermined record length corresponding to the fixed length of the data, and has a predetermined record length assigned with a code corresponding to the identification code of each station. Buffer memory for file storage that stores number (k) of records; if the identification code of the own station is (1) and the identification code of the record being received is (k), the identification code is set to (0). and a first timer that is started after the end of the record and measures the first time (T1) when the identification code of the record being received is (i-1); (i-1), the second timer is started after the end of the record and measures the second time (T2); if an error occurs during reception, the second timer is started after the end of the record and measures the third time. (T3), a transmission management means that transmits the own record after the first timer times out, and when the second timer times out, the identification code (j) of the received record is changed to the identification code ( j+1)
An empty station processing means that starts the first timer if (j+1) is equal to (i) and starts the second timer if (j+1) is different from (i); Time (k x T2) If the communication line is idle, it is assumed to be the identification code (0) and the second timer is started, and if there is communication within this time, the identification code (j) is read and (j ) is equal to (i), the first timer is activated, and if (j) is different from (i), the second timer is activated; The record's identification code (j) is regarded as the identification code (j+2), and if (j+2) is equal to (i), the first timer is activated, and if (j+2) is different from (i), the second timer is activated. Each station is provided with an error handling means, and the set time of each timer is (T1<T3<T2)
A simple data network characterized in that T1 is smaller than the transmission time of one record.