JPH0619810A - Duplex device - Google Patents

Abstract

PURPOSE:To exactly diagnose a communication control part and to securely switch a control right to a standby-side even if abnormality occurs in the communication control part. CONSTITUTION:Communication control means 23 and 43 executing the data transmission control of a token path system are provided in the communication control parts 20 and 40, and loop back diagnosis control means 24 and 44 executing loop back diagnosis in accordance with an instruction from CPU 10 and 30 are provided for the communication control means 23 and 43. Counters 13 and 33 which are started when loop back starts and are reset when loop back diagnosis terminates are provided for CPU 10 and 30 and time setting means 14 and 34 setting different time-up time when a system is in a control state and in a standby state are provided for the counters 13 and 33. When the counters 13 and 33 are time up, a signal for duplex control is inverted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a duplication device having a duplication structure of a computer system. More specifically, each computer system is connected to a communication line (network) via a communication control device. The present invention relates to a duplexer that carries out communication (data transmission) by using communication lines by carrying communication rights (tokens) with each other, and relates to a duplexer capable of correctly diagnosing a communication control device.

[0002]

2. Description of the Related Art In a distributed control system required to have high reliability, a computer system in charge of control calculation and a communication control device connected between these computers and a communication line have a dual structure. In case of failure, the redundant configuration is adopted so that the other can back up.

FIG. 2 is a conceptual diagram of the structure of a conventional duplexer of this type. In the figure, FC1 and FC2 are computer systems having a redundant configuration, and correspond to, for example, distributed control stations. BS is a communication line to which a plurality of other computer systems are connected. This communication line may also be duplicated for the purpose of improving reliability. CA1 and CA2 are communication control devices for connecting each computer system to a communication line BS and performing token path communication control.

In such a device, in order to maintain high reliability, failure detection by self-diagnosis is important. For such self-diagnosis, for example, a system in which one computer system diagnoses a failure in the other computer system is adopted. In the communication control device CA, it is also necessary to diagnose whether the transmission / reception function is normal. In that case, a so-called loop for transmitting a communication frame addressed to its own device and receiving it for checking. Back diagnosis is commonly done.

[0005]

However, in a method in which one computer system performs a failure diagnosis of the other computer system, it is difficult to determine which computer system is the cause when an error occurs. There are challenges. Also, when performing loopback diagnosis, both the control side and the standby side should be able to perform their own loopback diagnosis, but in a system that is executing communication control of the token pass system, the transmission right is required unless a token is acquired. Not to
If the control side fails, the token cannot be passed to the standby side, and the standby side diagnosis may fail.

The present invention has been made in view of the above circumstances, and is performed in each of the communication control device on the control side and the communication control device on the standby side in a duplicated computer system for performing token path data transmission. It is an object of the present invention to provide a highly reliable duplexer so that a failure diagnosis can be correctly detected by loopback diagnosis.

[0007]

SUMMARY OF THE INVENTION The present invention which achieves such an object has a computer system including a communication control unit coupled to a communication line and a CPU as a duplicated configuration, and a duplicated control system having mutually exclusive relations. Based on a signal for, one computer system is a control side, the other computer system is a duplexing device to perform the operation as a standby side, in the communication control unit, token path data transmission control Communication control means to perform and CP to this communication control means
A loopback diagnosis control means for executing a loopback diagnosis according to an instruction from U is provided, and the CPU has a counter that starts at the start of the loopback and is reset at the end of the loopback diagnosis, and this counter is in a control state. Time setting means for setting a different time-up time depending on time and when in the standby state is provided, and when the counter times out, it is determined that the communication control unit has failed and if it occurs on the control side. The duplexer is characterized in that the signal for the duplex control is inverted.

[0008]

The loopback control means causes the communication control unit to execute the loopback diagnosis according to the instruction from the CPU side.
The counter starts at the start of the loopback diagnosis and is reset by the success (end) of the loopback diagnosis.
If the loopback diagnostic is run several times and it does not succeed, the counter times out.

When the counter times out, the CPU determines that the communication control section is abnormal, inverts the signal for duplex control, and switches the computer system on the standby side until then to the control side.

[0010]

Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a conceptual diagram showing the construction of an embodiment of the present invention. In the figure, BS is a communication line for data transmission of the token path system, and only one communication line is shown here, but it may be a duplex configuration. FC1 and FC2 are
In the redundant computer system connected to the communication line BS, one of them is in a control state in which one is engaged in control, and the other is in a standby state in which it stands by in case one fails. Although not shown here in the communication line BS,
In addition to this, other computer systems are connected, and the communication right (token) is sequentially carried between the computer systems to carry out communication control of the token path system for data transmission by sequentially carrying around with each computer system. There is.

In each computer system having a duplicated configuration, 10 and 30 are CPUs that perform various controls and calculations, commands for loopback diagnosis, and 20 and 40 are communication control units that are connected to a communication line BS. The data transmission control of the token pass method is performed. These communication control units 20,
In 40, 21 and 41 are connected to a driver, 22 and 42 are connected to a receiver, and 23 and 43 are connected to a driver / receiver,
Communication control means for controlling data transmission using the communication line BS in accordance with the token pass system, and 24 and 44 are loopback diagnostics for executing loopback diagnostics according to instructions from the CPUs 10 and 30 corresponding to the communication control means 23 and 43. It is a control means.

In each CPU, reference numerals 11 and 31 are CPU control means as a whole, and a function of outputting a ready signal RDY indicating that the CPU is in an operating state or outputting a command for loopback diagnosis. Is equipped with. 12, 3
Reference numeral 2 denotes a gate circuit, each of which has its own output signal as its own input signal, and has a ready signal output from the corresponding CPU control means as another input, and each has an exclusive relationship. Is configured to output switching signals IOCE1 and IOCE2.

Reference numerals 13 and 33 are counters that are characteristic of the present invention, and are configured to be started at the start of loopback and reset at the end of loopback diagnosis.
Reference numerals 14 and 34 denote time setting means for setting the time-up time in the counters 13 and 33 so that the time-up time differs depending on whether the switching signal IOCE1 (IOCE2) for duplex control is active or inactive. Set to. That is, for example, when the switching signal IOCE1 for duplex control is active and the control right exists in itself (in the control state), when the control right does not exist in itself (IOCE1 is in Set a shorter time than (when active and waiting).

The time-up signals from the counters 13 and 33 are applied to the corresponding CPU control means 11 and 31. Then, each of the CPU control means 11 and 31 receives the time-up signal from the corresponding counter, determines that the communication control unit on its own side is abnormal, and sets the ready signal RDY output by itself as an inactive signal. It is configured to do.

Next, the operation of the apparatus configured as described above will be described by dividing it into a normal operation and an operation when the communication function fails. (Normal operation) Duplicated computer system FC1,
In FC2, each gate circuit 12 and 32 is a CPU
The flip-flop driven by the ready signal RDY output from the control means is constituted, and the ready system RDY output from the CPU control means becomes active early, and the computer system side activates the duplexing control switching signal IOCE. Then, the control state is entered. here,
The switching signals IOCE1 and IOCE2 for duplex control are
Since they are mutually exclusive, the other computer system side is in a standby state.

In normal time, the two computer systems F
The C1 and FC2 are equalized in their databases by separate means (not shown) and are operating in synchronization with each other, and the loopback diagnosis is also activated at the same time. Now
For example, assuming that FC1 is the control side computer system and FC2 is the standby side computer system, the time setting means 14 knows the state because the duplexing control switching signal IOCE1 is active, and the counter 13
For this, the time-up time T1 is set. Further, the time setting means 24 on the standby side uses the duplex control switching signal IO.
Since CE2 is inactive, it knows that it is on the standby side and sets the time-up time T2 in the counter 33. Here, the time-up times T1 and T2 set in each counter are T1 <T2
(Standby side is longer than control side).

When the communication control unit 20 receives the token while the computer system FC1 is in the controlled state, the loopback operation is performed when the loopback diagnosis control means 24 instructs to execute the loopback diagnosis. At the same time, the counter 13 starts the count-up operation. The result of executing the loopback diagnosis is transmitted to the CPU 11. Here, if no error is detected, the counter 1
3 is reset before the time is up.

Subsequently, the control-side communication control unit 20 passes the token to the standby-side communication control unit 40, and this time, the loop-back diagnosis is similarly performed in the standby-side communication control unit. If the computer system in the control state becomes abnormal for some reason, the ready signal RDY output from the CPU control means becomes inactive, the state of the duplex control switching signal IOCE is inverted, and the standby side is until then. The control right is transferred to the computer system that matches.

(Operation When Communication Function Fails) In this case, the communication control means in the control side computer system executes loopback diagnosis, but no reply is returned and the failure of diagnosis is repeated. For this reason, the counter 13 time-ups when the predetermined set time T1 has elapsed. CPU control means 1 which receives the time-up of the counter 13
1 determines that the communication control unit 20 is abnormal, sets the ready signal RDY inactive, sets the state of the duplex control switching signal IOCE1 to inactive (inverted), and the computer system FC2 side that was on the standby side up to that point Transfer control to.

(Influence on standby side when control side failure) If the communication control section 20 is abnormal, for example, if the driver 21 has a failure, if the failure is immediately after the loopback diagnosis. , The diagnosis of itself succeeds, but the token cannot be passed to the computer system FC2 side in the standby state, and the loopback diagnosis on this side fails.

However, on the control side, the driver 21 is out of order in the next loopback diagnosis.
Subsequent loopback diagnostics will repeatedly fail. Here, since the control-side counter 13 is set with the time-up time T1 that is shorter than the time-up time T2 set in the standby-side counter 33, the control-side counter 13 times up first. . Therefore, even if the communication control unit on the control side has a failure, the computer system F that has been in a standby state until then is not affected by the failure.
The control right can be reliably switched to the C2 side.

The time-up times T1 and T2 set in each counter according to the control state / standby state are T1.
While maintaining the relationship of <T2, the time required for the loopback diagnosis, the processing time of the CPU, and the like are selected.

[0023]

As described above in detail, according to the present invention, in a duplexer having a communication control unit for performing token pass data transmission, it is possible to accurately diagnose each communication control unit. Even if an abnormality occurs in the communication control unit, the control right can be reliably switched to the standby side, and a highly reliable duplexer can be realized.

[Brief description of drawings]

FIG. 1 is a structural conceptual diagram showing an embodiment of the present invention.

FIG. 2 is a conceptual diagram of a configuration of a conventional device.

[Explanation of symbols]

 BS communication line FC1, FC2 Duplicated computer system 10,30 CPU 20,40 Communication control unit 21,41 Driver 22,42 Receiver 23,43 Communication control means 24,44 Loopback diagnosis control means 11,31 CPU control means 13 , 33 counter 14, 34 time setting means

Claims (1)

[Claims] 1. A computer system including a communication control unit and a CPU coupled to a communication line has a redundant configuration, and one computer system is controlled by one of the computer systems on the basis of signals for redundant control that are mutually exclusive. A duplication device in which the other computer system operates as a standby side, in the communication control unit, communication control means for performing token pass data transmission control, and instructions from the CPU to this communication control means. A loopback diagnosis control means for executing loopback diagnosis according to the above is provided, and the CPU is provided with a counter that starts at the start of loopback and is reset at the end of loopback diagnosis, and a counter when the counter is in a control state and a standby state. And a time setting means for setting a different time-up time depending on the time Then, when it is judged that the communication control unit is out of order and the error occurs on the control side, the signal for the above-mentioned duplication control is inverted.