JP2002077970A - PHS system - Google Patents

Abstract

(57) [Summary] [Problem] In a conventional PHS system, when a failure occurs in a control system, whether the system operation is continued as it is or not.
Although there is a problem in that only one of the preset control methods can be performed among the switching of the control system, there is a problem that it is inconvenient. However, according to the present invention, according to the importance of the sub-control device controlled by the control system, And a PHS system capable of efficiently operating the system. A maintenance terminal (5) has a main controller (MCP) (3).
a and the MCP 3b correspond to each communication control device (CCP) 2 controlled by each MCP 3 and have parameters indicating processing at the time of failure occurrence according to the importance of the sub control device (SCS) 1 controlled by the CCP 2. This is a PHS system in which, when a failure occurs in the CCP2, the MCP3 performs the degeneration operation or the switching of the control system according to the set parameters.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PHS system having a redundant control system, and more particularly to a PHS system capable of efficiently operating the system.

[0002]

2. Description of the Related Art A PHS system includes a sub-controller (SC) for directly performing wireless communication with a PHS terminal carried by a user.
A control system for controlling S (Sub Control Station) is provided. The control system controls the sub-control device according to various parameters set from the outside.

Recently, there is a duplex system in which two sets of control systems are provided for each sub-control device in order to operate the system stably. In such a duplex system, usually, one control system performs control and the other is on standby.

[0004] In a conventional duplex system, when a failure occurs in the operating control system, there are two ways to cope with it. A first method is a method in which a control system in which a failure has occurred outputs an alarm and continues system operation as it is, and a sub-control device controlled by the control system is a degraded operation. The second method is a standby method. This is a method of switching control to a middle control system, and has been adapted to any of the methods set in the control system in advance.

[0005] In a private PHS system, the sub-control device includes interface boards such as a 2 Mbps dedicated line, a 1.5 Mbps dedicated line, digital data, and an analog PBX. In particular, some sub-control devices having a 2 Mbps dedicated line play an important role of supplying a clock.

[0006] Further, as a conventional mobile telephone system,
JP-A-10-257548 published on September 25, 1998
No. "Wireless telephone system". According to this conventional technology, permission conditions such as the number of permitted location registrations and the permitted time are set in the radio line control device in advance for each specific area corresponding to the service zone of the radio base station, and when the location registration from the radio telephone is performed, This is a wireless telephone system that permits location registration when the set permission conditions are met, and can restrict use of the wireless telephone under specific conditions.

However, in the conventional PHS system, when a failure occurs in the control system, the system operation is continued as it is or the control system is switched. There was a problem that it was only possible to deal with this, which was inconvenient.

For example, if the sub-controller supplying the clock continues to operate the system as it is in the event of a control system failure, it may lead to a total system down. In the case of a sub-control device having many interface boards, there is a problem that the communication may be disabled.

In addition, in the case of a sub-controller that is not so important, there is a problem that if the control system is switched each time due to a failure in the control system, the load on the entire system increases.

The present invention has been made in view of the above conventional example, and when a failure occurs in a control system, the failure is dealt with in accordance with the importance of a sub-control device controlled by the control system, thereby improving the efficiency of the system. It is an object of the present invention to provide a PHS system capable of achieving a safe operation.

[0010]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems of the prior art, the present invention provides a plurality of sub-controllers for performing wireless communication with a PHS terminal, and two sub-controllers are provided for each sub-controller. A communication control device for controlling the sub-control devices; a first main control device for controlling one of the two communication control devices provided for each of the sub-control devices; A second main controller that controls the other of the two communication controllers; and a maintenance terminal that sets parameters for the first main controller and the second main controller. A PHS system controlled by any one of the second main control devices, wherein a maintenance terminal communicates a first main control device and a second main control device with each other by each main control device. Set a parameter indicating the processing method when a failure occurs in the control device The first main controller and the second main controller operate according to parameters set corresponding to the communication controller when a failure occurs in one of the communication controllers. The PHS system is a main control device that performs a process of degeneration operation or control system switching, and when a failure occurs in the operating communication control device, the importance of the sub control device controlled by the communication control device is low. In such a case, the control is continued as it is in the degenerate operation, and if the importance of the sub-control device to be controlled is high, the control is switched to the other main control device and the control is performed by the fault-free communication control device. Thus, abnormal operation of the sub-control device can be prevented, influence on the entire system can be suppressed, and efficient operation of the system can be achieved.

[0011]

Embodiments of the present invention will be described with reference to the drawings. Note that the function realizing means described below may be any circuit or device as long as the function can be realized, and some or all of the functions may be realized by software. is there. Further, the function realizing means may be realized by a plurality of circuits, or the plurality of function realizing means may be realized by a single circuit.

A PHS system according to the present invention has a duplicated control system, and a sub-control device (SCS) for controlling in advance.
Depending on the degree of importance, switching or degeneration is set for each control system, and if a failure occurs in the control system, control is switched to the other control system according to the setting, or degraded operation is performed. This allows efficient operation of the control system.

Next, a PHS system according to an embodiment of the present invention will be described. First, a configuration of a PHS system (this system) according to an embodiment of the present invention is shown in FIG.
This will be described with reference to FIG. FIG. 1 is a configuration block diagram of a control system of a sub control device (SCS) in a PHS system according to an embodiment of the present invention. Here, for the sake of simplicity, a case will be described in which there are two sub-control devices.

As shown in FIG. 1, the configuration of this system is almost the same as that of the conventional system, and includes sub-control devices (SCS) 1a and 1b for performing radio communication with a PHS terminal (not shown), and sub-control devices 1a and 1b. 1b equipped with a control system for controlling
S) 4 and a maintenance terminal 5 for setting parameters for the integrated device 4.

Further, the integrated device 4 includes communication control devices (CCP) 2a and 2c for controlling the sub-control device 1a, communication control devices 2b and 2d for controlling the sub-control device 1b, and communication control devices 2a and 2b. Main controller (MCP) 3a to control
Main controller 3b for controlling communication controllers 2c and 2d
It is composed of The main control device 3 controls the communication path and the exchange of the entire integrated device 4. Also,
The main controller 3a and the main controller 3b are connected by a LAN line, and exchange data such as a control system switching instruction.

The integrated device 4 has a duplicated control system. Here, a system composed of a main control device 3a, a communication control device 2a, and a communication control device 2b is set to "0".
The system configured by the main control device 3b, the communication control device 2c, and the communication control device 2d is referred to as "system 1". Normally, in accordance with an instruction from the maintenance terminal 5, either the control system 0 or the control system 1 is selected and the sub control device 1 is selected.
a, the control operation of the sub-control device 1b is performed, and the other control system is on standby. The operating system is referred to as “active system”, and the standby system is referred to as “standby system”.

The maintenance terminal 5 is connected to a main controller 3a for controlling the system 0 and a main controller 3b for controlling the system 1 to set parameters and control information. As a feature of this system, the maintenance terminal 5 sets, as a parameter, a response method at the time of occurrence of a failure for each communication control device 2 in a nonvolatile memory (not shown) of the main control device 3a and the main control device 3b. In particular, in the present system, in accordance with the importance of each sub-control device 1, the main control device 3 is preliminarily set in the main control device 3 how to cope when a failure occurs in the communication control device 2 that controls the sub-control device 1. It is something to keep.

More specifically, referring to FIG. 1, in the present system, as in the prior art, as a method of coping with the occurrence of a fault in the communication control device 2, an alarm for notifying the occurrence of a fault is output and the operation is continued as it is. There are “degeneration” in which the sub-control device controlled by the communication control device 2 is in a degraded operation, and “switching” in which a failure occurs in the communication control device 2 and switches to a standby control system.

When the importance of the sub-control device 1 is high, the maintenance terminal 5 of the present system provides the main control device 3 with "a communication control device 2 for controlling the sub-control device 1". When the importance of the sub-control device 1 is not so high, “degeneration” is set in the main control device 3 corresponding to the communication control device 2 that controls the sub-control device 1. It is supposed to.

That is, if a failure occurs in the communication control device 2 for supplying a clock or controlling the high-priority sub-control device 1 having a large number of interface boards, the operation is continued and the sub-control device 1 becomes abnormal. Since the operation may adversely affect the entire system, the communication control device 2 that controls the sub-control device 1 with high importance is
When a failure occurs, the control system is switched immediately.

On the other hand, if a fault occurs in the communication control device 2 for controlling the sub-control device 1 having a low importance, the system load is increased each time the system is switched. The communication control device 2, which controls the sub-control device 1 that has little effect on the entire system even if it occurs, continues to operate even if a failure occurs, and the controlled sub-control device 1 is degraded operation. .

Then, the user inputs such settings to the maintenance terminal 5, and the maintenance terminal 5 sets the non-volatile memory (not shown) of each MPC 3 corresponding to the communication control device 2. .

A specific setting example will be described with reference to FIG. FIG. 2 is an explanatory diagram showing a setting example of switching or degeneration in the main control devices (MCPs) 3a and 3b. As shown in FIG. 2, the main control device 3a stores a response to the occurrence of a failure corresponding to the 0-system communication control device 2a and the communication control device 2b, and the communication control device 2a controls the sub-control device to be controlled. Since the importance of 1a is not so high and the influence of the abnormality control is small, "degenerate" is set, and the communication control device 2b has a high importance of the sub-control device 1b to be controlled, and the abnormality control is performed. In such a case, "switching" is set because it greatly affects the entire system.

Similarly, the main controller 3b stores a response to the occurrence of a failure corresponding to the communication controller 2c and the communication controller 2d of the first system, and the communication controller 2c for controlling the sub controller 1a. Is set corresponding to the communication control device 2d that controls the sub-control device 1b.

In this system, the user operates the maintenance terminal 5
When the sub-controller 1a inputs an instruction of "degenerate" and the sub-controller 1b inputs "switching", the maintenance terminal 5 controls each of the sub-controllers 1 with respect to the main controller 3a and the main controller 3b. The setting of “reduction” or “switching” is performed for each communication control device 2 that performs communication.

Next, the operation of the present system will be described with reference to FIG. FIG. 3 is a flowchart showing the processing of the main control device 3a when the system 0 is operated as the active system in the system in which the settings shown in FIG. 2 are made. That is, in the main control device 3a, it is a flowchart diagram in a case where the communication control device 2a is set to “degenerate” and the communication control device 2b is set to “switch”.

As shown in FIG. 3, when the system 0 is operated as the active system, the main control device (MCP) 3a monitors whether a failure has occurred in the communication control device (CCP) 2 (100). If a failure has occurred, it is determined whether the failure occurred is the communication control unit (CCP) 2a or 2b (10).
2) If the communication control device (CCP) 2a is used, an alarm for notifying that "a failure has occurred in the communication control device 2a" is output to the maintenance terminal 5 (104), and the sub control device (SCS) 1a is degraded. (106).

In this state, since the normal control of the communication control device 2a is not guaranteed, the operation of the sub-control device 1a is not guaranteed. However, since the sub-control device 1a is not so important, the influence on the entire system is small. Help me.

Then, the main control device (MCP) 3a determines whether or not the communication control device (CCP) 2a has been restored.
When the operation is restored, the sub control device 1a is set to the normal operation (11
0), and return to the process 100.

In the case where the failure occurred in the communication control device (CCP) 2b in the process 102, the main control device (MCP) 3a sends the "communication control device 2b
Alarm is output to notify that a failure has occurred
0).

Then, the main controller (MCP) 3a outputs a control switching request to the main controller (MCP) 3b (122), and upon receiving a control switching response from the main controller 3b, the main controller 3a Main controller (MCP) 3
The control is shifted to b (124). As a result, from system 0 to system 1
The control is switched to the system, the system 1 is operated as the active system,
The system is a standby system.

When the control is switched to the first system, the sub-controller 1
The control of a is performed by the communication control device 2c, and the control of the sub-control device 1b is performed by the communication control device 2d. However, since the communication control devices 2c and 2d do not have any failure, the normal operation is guaranteed.

According to the PHS system according to the embodiment of the present invention, communication control devices (CCP) 2a, 2b for controlling sub-control devices (SCS) 1a, 1b, and communication control device 2
0, which is composed of a main controller (MCP) 3a for controlling the a and 2b, communication controllers (CCP) 2c, 2d for controlling the sub controllers (SCS) 1a, 1b, and a communication controller 2
and a main control device (MCP) 3b for controlling the main control device 3c and the main control device 3b. The main control device 3 controls the main control device 3a and the main control device 3b. For each communication control device 2, if the importance of the sub-control device 1 controlled by the communication control device 2 is low, "degenerate" is set to continue operation in the event of a failure, and the importance is set. If it is higher, "switching" for switching the control system is set, and if a failure occurs in the communication control device 2, the degeneration operation or the switching of the control system is performed according to the set data. At the time of occurrence of the fault 2, the response can be changed according to the importance of the sub-control device 1 to be controlled, and there is an effect that efficient system operation can be achieved.

[0034]

According to the present invention, a plurality of sub-control devices for performing radio communication with a PHS terminal, two communication control devices provided for each sub-control device for controlling the sub-control devices, A first main control device that controls one of two communication control devices provided for each control device, and a second main control device that controls the other of the two communication control devices provided for each sub-control device. And a maintenance terminal for setting parameters to the first main control device and the second main control device, and controlled by either the first main control device or the second main control device. Is performed, and the maintenance terminal is
The first main control device and the second main control device can be set with parameters indicating a processing method when a failure occurs in the communication control device controlled by each main control device. 2 is a PHS system that performs a degeneration operation or a control system switching process according to parameters set corresponding to the communication control device when a failure occurs in any of the communication control devices. If a failure occurs in the operating communication control device and the importance of the sub-control device controlled by the communication control device is low, the control is continued as degraded operation and the sub-control device is controlled. When the importance of the device is high, the control is switched to the other main control device and controlled by the communication control device without trouble, thereby preventing the abnormal operation of the sub control device and suppressing the influence on the entire system. Bets can be, there is an effect capable of reducing the efficient operation of the system.

[Brief description of the drawings]

FIG. 1 is a configuration block diagram of a control system of a sub control device (SCS) in a PHS system according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a setting example of switching or degeneration in main control devices (MCPs) 3a and 3b.

FIG. 3 is a flowchart illustrating a process of a main control device (MCP) 3a when the system 0 is operated as an active system in the system in which the settings shown in FIG. 2 are made.

[Explanation of symbols]

1 ... sub-control unit (SCS) 2 ... communication control unit (CC)
P), 3: Main controller (MCP), 4: Integrated controller (CS), 5: Maintenance terminal

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification code FI Theme coat ゛ (Reference) H04Q 3/545 H04B 7/26 K 5K069 11/04 H04Q 11/04 LF term (Reference) 5B034 BB02 BB16 5K019 BA45 CA05 CC05 EA26 EA27 EA28 5K026 AA09 BB04 FF01 GG18 KK02 5K042 AA06 AA08 CA02 DA32 JA03 NA00 NA03 5K067 AA26 AA33 BB04 DD28 DD57 EE02 EE10 EE16 EE23 LL13 5K069 AA10 HA01 HA01

Claims (1)

[Claims] A plurality of sub-controllers for performing wireless communication with a PHS terminal; two communication control units provided for each of the sub-controllers for controlling the sub-controllers; And a second main control unit for controlling one of the two communication control units provided for each of the sub-control units. A control device, and a maintenance terminal for setting parameters to the first main control device and the second main control device, wherein one of the first main control device and the second main control device A PHS system in which control is performed, wherein the maintenance terminal has a failure in the first main control device and the second main control device in a communication control device controlled by each main control device. Parameter that indicates the processing method of The first main control device and the second main control device are configured to correspond to the communication control device when a failure occurs in any of the communication control devices. A PHS system, which is a main control device that performs a degeneration operation or a control system switching process according to the following.