JP4941783B2 - Multiplexer - Google Patents

Description

The present invention relates to a multiplexing apparatus according to the electronic apparatus, particularly relates to a multiplexer which is done with the intention storage, the addition of the electronic device such as a server.

As an example of a technology related to a multiplexing device in which a plurality of electronic devices such as storage are multiplexed, for example, Patent Document 1 can be cited.
In the multiplexing device disclosed in Patent Document 1, an example of a RAID (Redundant Arrays of Annexed Disks) configuration including a plurality of disk devices is shown. The RAID is configured to be stored in the same casing as the host computer or stored in a disk casing different from the host computer.

  In this RAID, when replacing a failed disk device, hot swapping is often performed to replace the host computer or RAID device without turning off the power. For this reason, the disk housing is provided with a display means such as an LED for visually informing the operator which disk device has failed and which disk device is incorporated as RAID.

Further, in Patent Document 1, the RAID control means mounted on the host is provided with a case management bus control means. Further, the disk case is provided with case management means and disk suppression means.
Each disk device in the disk housing and the RAID control means are connected by a disk interface bus (disk I / F bus). The case management means of the disk case and the RAID control means are connected by a case management bus.
The case management means controls the lighting of the LED (display means) for each disk device by a unique ID for specifying the disk device.

  In addition, the above display means can identify a failed disk device, and can identify that an abnormality has occurred inside the disk housing, such as a power supply, fan, temperature, etc. It is realized by an element such as an LED, and is configured such that the case management means controls the display means.

Furthermore, in such a multiplexing device, when a failure occurs in one electronic device (redundant component), the system bus shared by the first electronic device (redundant component such as a control unit) that has failed first is shared. In some cases, the other electronic device (redundant component) in operation is stopped and the entire system in the multiplexing apparatus stops (hereinafter referred to as multiple failure).
For example, in Patent Document 2, when active maintenance is performed on a plurality of maintenance target components in a disk array device in order to cope with multiple failures, the information serves as an index for determining the order in which maintenance replacement of maintenance target components is performed. Component maintenance order information, which is information indicating the order in which maintenance replacement of maintenance target components is performed in accordance with the maintenance target component priority order information, is created. Further, the disk array apparatus disclosed in Patent Document 2 guides the operator of the disk array apparatus so that a plurality of maintenance target parts are arranged in the order of maintenance replacement, and the maintenance target parts are replaced in the order in which they are arranged. .

JP 9-330184 A JP 2008-191908 A

  By the way, in the related art multiplexing apparatus described above, when multiple failures occur, all the electronic devices (such as the control unit) are also stopped. Therefore, all the failure lamps corresponding to all the electronic devices are in a “failed state”. Therefore, there is a problem in that it is impossible to specify the failure location of which electronic device in the multiplexing apparatus is a true failure.

In particular, Patent Document 2 has a disadvantage that the CM that controls the active maintenance control (which is composed of a CPU, a memory, and other tables in Patent Document 2) cannot cope with a case where multiple failures occur.
That is, in Patent Document 2, since a CM (control unit) has a maintenance PC management function and a failure order table, when two or more CMs (control units) have multiple failures, the maintenance PC is restarted after the disk array device is restarted. Must be connected, and log confirmation must be performed to confirm failure order information, and the failure location cannot be identified in real time.

  Furthermore, in the related technology, it is necessary for the operator to perform the operation of isolating the fault location and separating the fault location while checking the operation by connecting each electronic device (redundant part) one by one at the time of multiple faults. There was a disadvantage that the operation rate of the multiplexing apparatus by work was lowered.

An object of the present invention is to solve the disadvantages of the above related art, multiplexing each of the device control section of the electronic devices which constitute the multiplexing device makes it possible to identify the failure location in real time even when multiple failures It is in providing a conversion apparatus .

In order to achieve the above object, in the multiplexing apparatus according to the first aspect of the present invention, at least two electronic devices including at least a device control unit, and the operating state of each electronic device are monitored, and Equivalent to the monitoring unit provided in the monitoring electronic device provided with a monitoring unit for analyzing the failure occurrence order, and other monitoring electronic devices newly provided in the electronic device independently of the monitoring unit A second monitoring unit having a function, a plurality of device display units that are provided on the electronic device side and each display an operating state of each electronic device, and a device control unit in each electronic device are connected to each other A control bus, a first monitoring bus connecting each device control unit and the monitoring unit in each electronic device, and each device control unit in each electronic device configured independently of the first monitoring bus, and Connect to the second monitoring unit A second bus and a dedicated monitoring bus consisting of monitoring the bus unit that, the failure information indicating the failure sequence from the monitoring electronic device provided therebetween with the electronic devices and the monitoring electronic device Each of the plurality of light transmission units respectively transmitting toward the corresponding display unit for each device, and provided between each of the electronic devices and the other monitoring electronic device than the other monitoring electronic device A plurality of other optical transmission units that respectively transmit failure information indicating a failure occurrence order toward the corresponding device display units, and each of the monitoring electronic devices corresponds to each of the electronic devices. has a provided each light transmitting section each failure indicator for each type a display optical signal to, and a lighting control function unit for lighting control each of said fault indicator in response to said failure occurrence order, the lighting control function unit, late the respective fault indicator Control to display in different colors according to the order, and when each electronic device is automatically restarted, the failure information is retained in the device display unit for a certain period of time It is comprised so that lighting of each said failure indicator lamp may be carried out, and the one said monitoring electronic device corresponding to the said one electronic device, the said one electronic device, the other said electronic device, and the said other electronic device The other corresponding electronic devices for monitoring are stacked in this order, and the respective light transmission units are arranged corresponding to the arrangement .

Further, in the multiplexing apparatus of the present invention as set forth in claim 2, at least two or more electronic devices provided with a device control unit and the operating state of each of the electronic devices are monitored, and a failure occurs in each of the electronic devices. A monitoring electronic device having a monitoring unit for analyzing the order, and a function equivalent to the monitoring unit provided in another electronic monitoring device newly provided in each electronic device independently of the monitoring unit A second monitoring unit having, a plurality of device display units provided on the electronic device side, each of which displays an operating state of each electronic device, and a control for connecting each device control unit in each electronic device A bus, a first monitoring bus that connects each device control unit and the monitoring unit in each electronic device, and each device control unit and each second that are configured independently of the first monitoring bus. Second monitoring connecting the monitoring unit A bus unit including a monitoring dedicated bus, and each of the electronic devices corresponding to the failure information indicating the failure occurrence order from the monitoring electronic device provided between the electronic devices and the monitoring electronic device. Each of the plurality of optical transmission units respectively transmitting toward the device display unit, and the failure occurrence order from the other monitoring electronic devices provided between the electronic devices and the other monitoring electronic devices. A plurality of other light transmission units that respectively transmit the failure information to be displayed toward the corresponding device display units, and each of the monitoring electronic devices is provided corresponding to each of the electronic devices. Each of the failure indicator lamps for inputting a display light signal to the light transmission unit, and a lighting control function unit that controls lighting of the failure indicator lamps according to the order of occurrence of the failure, and the lighting control function The unit displays each failure indicator lamp according to the failure order. Each failure display is controlled such that the failure information is held for a certain period of time in each device display unit when each electronic device is controlled to be displayed in a different color and automatically restarted. The storage electronic device dedicated to data storage is arranged corresponding to each electronic device, and the monitoring unit in the monitoring electronic device is configured to control the lighting of the storage device. The operation state is also monitored, and the failure occurrence order including the storage electronic device and each electronic device is analyzed .

Further, in the multiplexing device of the present invention according to claim 3, at least two or more electronic devices provided with a device control unit and the operating state of each of the electronic devices are monitored, and a failure occurs in each of the electronic devices. A monitoring electronic device having a monitoring unit for analyzing the order, and a function equivalent to the monitoring unit provided in another electronic monitoring device newly provided in each electronic device independently of the monitoring unit A second monitoring unit having, a plurality of device display units provided on the electronic device side, each of which displays an operating state of each electronic device, and a control for connecting each device control unit in each electronic device A bus, a first monitoring bus that connects each device control unit and the monitoring unit in each electronic device, and each device control unit and each second that are configured independently of the first monitoring bus. Second monitoring connecting the monitoring unit A bus unit including a monitoring dedicated bus, and each of the electronic devices corresponding to the failure information indicating the failure occurrence order from the monitoring electronic device provided between the electronic devices and the monitoring electronic device. Each of the plurality of optical transmission units respectively transmitting toward the device display unit, and the failure occurrence order from the other monitoring electronic devices provided between the electronic devices and the other monitoring electronic devices. A plurality of other light transmission units that respectively transmit the failure information to be displayed toward the corresponding device display units, and each of the monitoring electronic devices is provided corresponding to each of the electronic devices. Each of the failure indicator lamps for inputting a display light signal to the light transmission unit, and a lighting control function unit that controls lighting of the failure indicator lamps according to the order of occurrence of the failure, and the lighting control function The unit displays each failure indicator lamp according to the failure order. Each failure display is controlled such that the failure information is held for a certain period of time in each device display unit when each electronic device is controlled to be displayed in a different color and automatically restarted. The device display unit of the electronic device is configured by a first display unit and a second display unit that functions in the same manner as the first display unit, and the monitoring electronic The device is provided with a second failure indicator lamp provided corresponding to each electronic device and displaying and emitting light according to the monitoring result of the monitoring unit, and the light transmission unit is configured to cause the failure in the monitoring electronic device. A first optical transmission unit for other electronic devices that guides and transmits output light from the indicator light toward a first display unit equipped in one of the electronic devices, and the second failure indication in the monitoring electronic device The other electronic device is equipped with the output light from the lamp And a second light transmission unit for other electronic equipment that guides and transmits the light toward the second display unit .

According to the present invention, the failure occurrence order of each electronic device is exclusively monitored for the increase in multiple failures caused by the increase in the speed of the device control unit such as the control circuit and the storage circuit constituting the electronic device. The monitoring electronic device is equipped with a failure indicator lamp that can be operated even in the case of multiple failures. The light transmission unit that does not affect the failure is provided from this failure indicator light. The failure occurrence order is displayed on the display for each device, so that the failure occurrence order can be visually confirmed in real time for multiple failures, and the simplification and efficiency of the response when multiple failures occur It is possible to provide an excellent multiplexing device that is not available in the related art.

It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 1st Embodiment of this invention. It is explanatory drawing which shows an example of the detailed structure of the multiplexing apparatus of FIG. It is a flowchart which shows an example of the operation | movement process procedure of the whole multiplexing apparatus in 1st Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 1st monitoring part in 1st Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 2nd monitoring part in 1st Embodiment of this invention. It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 2nd Embodiment of this invention. It is explanatory drawing which shows an example of a detailed structure of the multiplexing apparatus of FIG. It is a flowchart which shows an example of the operation processing procedure of the whole multiplexing apparatus in 2nd Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 1st monitoring part in 2nd Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 2nd monitoring part in 2nd Embodiment of this invention. It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 3rd Embodiment of this invention. It is explanatory drawing which shows an example of a detailed structure of the multiplexing apparatus of FIG. It is a flowchart which shows an example of the operation | movement process procedure of the whole multiplexing apparatus in 3rd Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 1st monitoring part in 3rd Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 2nd monitoring part in 3rd Embodiment of this invention. It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 4th Embodiment of this invention. It is explanatory drawing which shows an example of a detailed structure of the multiplexing apparatus of FIG. It is a flowchart which shows an example of the operation | movement process procedure of the whole multiplexing apparatus in 4th Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 1st monitoring part in 4th Embodiment of this invention. It is a flowchart which shows an example of the operation processing procedure of the 2nd monitoring part in 4th Embodiment of this invention. It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 5th Embodiment of this invention. It is explanatory drawing which shows an example of a detailed structure of the multiplexing apparatus of FIG. It is explanatory drawing which shows an example of the whole structure of the multiplexing apparatus by 6th Embodiment of this invention. It is explanatory drawing which shows an example of a detailed structure of the multiplexing apparatus of FIG.

  Hereinafter, an example of a preferred embodiment of a “multiplexing device” of the present invention will be specifically described with reference to the drawings.

[First Embodiment]
(Basic configuration of multiplexer)
First, the basic configuration of the multiplexing apparatus will be described. FIG. 1 is an explanatory diagram showing an example of the overall configuration of the multiplexing apparatus according to the first embodiment of the present invention. FIG. 2 is an explanatory diagram showing an example of a detailed configuration of the multiplexing apparatus of FIG.
As shown in FIGS. 1 and 2, the multiplexing device 14 according to the first embodiment of the present invention basically has the same configuration as the electronic device 1 including the first control unit 1a as the device control unit. And an electronic device 2 including a second control unit 2a as a unit.

The multiplexing device 14 also includes a first monitoring unit 3a as a monitoring unit that monitors the operating states of the electronic device 1 and the electronic device 2 and analyzes the failure occurrence order of the electronic devices 1 and 2. Electronic equipment 3.
In addition to the first monitoring unit 3a, the multiplexing device 14 includes a second monitoring unit 4a that is configured independently of the first monitoring unit 3a and has a function equivalent to that of the first monitoring unit 3a. Other monitoring electronic devices 4 are provided.

  Further, the multiplexing device 14 includes a first control unit display unit “FAULT-A” that is provided on the electronic device 1 side and displays an operating state of the electronic device 1, and the electronic device 2. And a second control unit display unit “FAULT-B” as a device display unit that is provided on the side and displays the operating state of the electronic device 2.

  The multiplexing device 14 includes a system bus 12 that is a bus unit for linking the first control unit 1a in the electronic device 1 and the second control unit 2a in the electronic device 2 together. The system bus 12 is also a bus unit for monitoring the first control unit 1a and the second control unit 2a.

Further, the multiplexing device 14 is provided between the electronic device 1 and the monitoring electronic device 3, and the failure information indicating the failure occurrence order from the monitoring electronic device 3 is displayed on the first control unit display unit “ One optical transmission unit for transmission toward FAULT-A (device display unit) is provided.
This one light transmission part is comprised by the prism-like mirror 7 (monitoring part left prism-like mirror) and the prism-like mirror 8 (control part left prism-like mirror), for example.

The multiplexing device 14 is provided between the electronic device 2 and the monitoring electronic device 4, and provides failure information indicating the failure occurrence order from the monitoring electronic device 4 to the second control unit display unit “ Another optical transmission unit that transmits the signal toward “FAULT-B” (device display unit) is provided.
The other light transmission unit includes, for example, a prismatic mirror 10 (monitoring unit right prismatic mirror) and a prismatic mirror 11 (control unit right prismatic mirror).

The monitoring electronic device 3 is provided corresponding to the electronic device 1 and is a first failure indicator lamp for inputting a display light signal to the one light transmission section (the prismatic mirror 7 and the prismatic mirror 8). 1 failure indicator lamp 6 is provided.
The monitoring electronic device 3 includes a first lighting control function unit (not shown) that controls lighting of the first failure indicator lamp 6 in accordance with the order of occurrence of the failure.

The monitoring electronic device 4 is provided corresponding to the electronic device 2 and is a first failure indicator lamp for inputting a display optical signal to the other light transmission unit (the prismatic mirror 10 and the prismatic mirror 11). Two failure indicator lamps 9 are provided.
The monitoring electronic device 4 includes a second lighting control function unit (not shown) that controls lighting of the second failure indicator lamp 9 according to the order of occurrence of the failure.
Here, instead of preparing the monitoring electronic devices 3 and 4, a single monitoring electronic device may be used. In that case, the first lighting control function unit that controls lighting of the first failure indicator lamp 6 in the monitoring electronic device 3 and the second failure indicator lamp 9 in the monitoring electronic device 4 are lit on one monitoring electronic device. You may provide the lighting control function part which integrated the 2nd lighting control function part to control.

The system bus 12 (bus unit) includes a control bus 13 that connects between the first control unit 1 a in the electronic device 1 and the second control unit 2 a in the electronic device 2.
The system bus 12 (bus unit) may include a monitoring dedicated bus that connects the first control unit 1a in the electronic device 1 and the second control unit 2a in the electronic device 2 to the monitoring unit.
Examples of the monitoring dedicated bus include the first monitoring bus 15 and the second monitoring bus 16.

The first monitoring bus 15 connects the first control unit 1 a in the electronic device 1, the second control unit 2 a in the electronic device 2, and the first monitoring unit 3 a in the monitoring electronic device 3.
The second monitoring bus 16 connects the first control unit 1 a in the electronic device 1, the second control unit 2 a in the electronic device 2, and the second monitoring unit 4 a in the monitoring electronic device 4.

Furthermore, the system bus 12 (bus unit) includes a first identifier storage unit 17 that stores a first identifier for identifying the first control unit 1a or the first monitoring unit 3a.
The first identifier storage unit 17 stores a location ID [1] that is a first identifier.

The system bus 12 (bus unit) includes a second identifier storage unit 18 that stores a second identifier for identifying the second control unit 2a or the second monitoring unit 4a.
The second identifier storage unit 18 stores a location ID [2] that is a second identifier.

The first control unit 1 a and the second control unit 2 a perform control operations via the control bus 13.
The first monitoring unit 3a performs monitoring via a first monitoring bus 15 connecting the first control unit 1a, the second control unit 2a, and the first monitoring unit 3a.
Further, the second monitoring unit 4a performs monitoring via the second monitoring bus 16 connecting the first control unit 1a, the second control unit 2a, and the second monitoring unit 4a.

The first monitoring unit 3a checks whether the first control unit 1a is operating only when the second control unit 2a is operating. If the first control unit 1a is not operating, the first monitoring unit 3a first The controller 1a determines that a failure has occurred, and the first failure indicator lamp 6 is lit red, which is an example of failure information indicating the failure occurrence order (first failure occurrence).
When the first control unit 1a is in operation, the first monitoring unit 3a determines that the first control unit 1a will fail later, and sets the first failure indicator lamp 6 to the failure occurrence order (second failure occurrence) Is lit in blue as an example of failure information.
The light emitted from the first failure indicator lamp 6 is output from the display unit (“FAULT-A”) on the first control unit 1 a side via the prismatic mirror 7 and the prismatic mirror 8.

The second monitoring unit 4a checks whether the second control unit 2a is operating only when the first control unit 1a is operating. If the second control unit 2a is not operating, the second monitoring unit 4a first The controller 2a determines that a failure has occurred, and the second failure indicator lamp 9 is lit in red as an example of failure information indicating the failure occurrence order (first failure occurrence).
When the second control unit 2a is in operation, the second monitoring unit 4a determines that the second control unit 2a has failed later, and sets the second failure indicator lamp 9 in the failure occurrence order (second failure occurrence) ), Which is an example of the failure information indicating (), is left blue and the state is not changed. The reason is that when both the first control unit 1a and the second control unit 2a are operating normally, both the first failure indicator lamp 6 and the second failure indicator lamp 9 are in a blue-lit state. Because it is.
The light emitted from the second failure indicator lamp 9 is output from the display unit (“FAULT-B”) on the second control unit 2 side via the prismatic mirror 10 and the prismatic mirror 11.

(About operation procedure)
(Overall outline operation)
Next, the overall operation processing procedure in the multiplexing apparatus having the above-described configuration will be described with reference to FIGS. FIG. 3 is a flowchart showing an example of the operation processing procedure of the entire multiplexing apparatus in the first embodiment of the present invention. FIG. 4 is a flowchart showing an example of an operation processing procedure of the first monitoring unit in the first embodiment of the present invention. FIG. 5 is a flowchart showing an example of an operation processing procedure of the second monitoring unit in the first embodiment of the present invention.

  The multiplexing apparatus 14 according to the present embodiment includes two or more electronic devices 1 and 2 each including at least a device control unit (1a or 2a), and a monitoring unit that monitors an operating state of each of the electronic devices 1 and 2 ( 3a or 4a) having a function of 3a and 4a) and a monitoring electronic device (3 or 4), and each of the electronic devices 1 and 2 provided on the electronic devices 1 and 2 side, each displaying an operating state A display bus for devices (“FAULT-A”, “FAULT-B”) and a control bus 13 that connects between the device control units of the electronic devices 1 and 2, and each of the electronic devices 1 and 2. And a bus unit 12 having a dedicated monitoring bus (15 and 16) for connecting the device control units 1a and 2a and the monitoring unit (3a or 4a) in the monitoring electronic device (3 or 4). Each of the electronic devices is connected by the bus unit 12. 1,2 Target made by multiplexing.

  The entire operation processing procedure in the failure occurrence order display for a multiplexing device according to the present embodiment is as follows. First, the functions of the monitoring units (3a and 4a) in the monitoring electronic device (3 or 4) are as follows. 3a or 4a) monitors each device control unit 1a, 2a in each of the electronic devices 1 and 2 and analyzes the order of occurrence of failure in each of the electronic devices 1 and 2 (step B4 and step shown in FIG. 3). A step consisting of a first monitoring step consisting of B5 and a second monitoring step consisting of step B2 and step B3: failure occurrence order analysis step or function).

Here, when the monitoring unit (3a or 4a) detects that each of the electronic devices 1 and 2 is operating immediately after the result of analysis or immediately after power-on, the monitoring electronic device (3 Alternatively, one display light signal (blue light signal or the like) is output from one failure indicator lamp (first failure indicator lamp 6 or the like) corresponding to the one electronic device 1 included in 4) (see FIG. 3). In addition to step A8), other display optical signals from other failure indicator lamps (such as the second failure indicator lamp 9) corresponding to the other electronic devices 2 included in the monitoring electronic device (3 or 4) are provided. (Blue light signal or the like) is output (step A5 shown in FIG. 3).
As described above, when each of the electronic devices 1 and 2 is operating normally, the monitoring unit lights each failure indicator light in the same color (for example, blue) indicating the normal operation state. Try to control.
On the other hand, when multiple failures occur, following the analysis in the failure occurrence order analysis step, as a result of the analysis, the monitoring unit (3a or 4a) When the device control unit 1a in the one electronic device 1 stopped is detected, one failure indicator lamp corresponding to the one electronic device 1 included in the monitoring electronic device (3 or 4) ( One display light signal (red light signal or the like) is output from the first failure indicator lamp 6 or the like (part of step A7 shown in FIG. 3: first light output control step or function).

  Next, the one display optical signal from the one failure indicator lamp (the first failure indicator lamp 6 or the like) in the monitoring electronic device (3 or 4) is converted into one light transmission unit (the prism-like mirror 7 and The information is transmitted to one device display section (first control section display section “FAULT-A”) corresponding to the one electronic apparatus 1 through the prism-shaped mirror 8) (step shown in FIG. 3). Part of A7: first optical signal transmission step or function).

  Furthermore, as a result of the analysis, when the monitoring unit (3a or 4a) detects the device control unit 2a in the other electronic device 2 that is next stopped among the electronic devices 1 and 2, Another display different from the one display optical signal from another failure indicator lamp (such as the second failure indicator lamp 9) corresponding to the other electronic device 2 provided in the monitoring electronic device (3 or 4). A light signal (blue light signal or the like) is output (part of step A5 shown in FIG. 3: second light output control step or function).

  Thereafter, the other display light signal from the other failure indicator lamp (such as the second failure indicator lamp 9) in the monitoring electronic device (3 or 4) is transferred to another light transmission unit (the prism-like mirror 10 and Guide transmission to the other device display section (second control section display section “FAULT-B”) corresponding to the other electronic apparatus 2 through the prism-shaped mirror 11) (step shown in FIG. 3) Part of A5: second optical signal transmission step or function).

(Detailed operation)
This will be described in detail below.
When the multiplexing device 14 is started, the first control unit 1 a in the electronic device 1 and the second control unit 2 a in the electronic device 2 start control operations via the control bus 13 in the system bus 12.
The first monitoring unit 3a in the monitoring electronic device 3 starts a monitoring operation via the first monitoring bus 15 connecting the first control unit 1a, the second control unit 2a, and the first monitoring unit 3a.
Further, the second monitoring unit 4a starts a monitoring operation via the second monitoring bus 16 that connects the first control unit 1a, the second control unit 2a, and the second monitoring unit 4a (step A1, FIG. 3). Step C1 in Step 4 and Step E1 in FIG.

  When the multiplexing device 14 is started, the first control unit 1a and the second control unit 2a obtain the location ID from the first identifier storage unit 17 or the second identifier storage unit 18 in the system bus 12 (step of FIG. 3). A2).

  When the multiplexing device 14 is started, the first monitoring unit 3a acquires the location ID [1] from the first identifier storage unit 17 in the system bus 12 (step A2 in FIG. 3, step B1 in FIG. 3, FIG. 3). Step A6, Step C2 in FIG. 4, and Step C3 in FIG. 4)

  The first monitoring unit 3a checks whether or not the second control unit 2a is stopped. If the second control unit 2a is stopped, the first monitoring unit 3a repeats the stop confirmation operation of the second control unit 2a (step of FIG. 4). D1).

  The multiplexing device 14 checks whether or not the second control unit 2a is stopped by the first monitoring unit 3a, and checks the location ID when the second control unit 2a is stopped (step B4 in FIG. 3). And step B1).

The first monitoring unit 3a checks whether or not the second control unit 2a is stopped. As a result of the confirmation, when the second control unit 2a is operating, the first monitoring unit 3a further checks whether the first control unit 1a is stopped.
When the 1st control part 1a has stopped, the 1st monitoring part 3a lights the 1st failure indicator lamp 6 red.
The light emitted from the first failure indicator lamp 6 is output from the first control unit 1a side via the monitoring unit left prism mirror 7 and the control unit left prism mirror 8 (step B4 in FIG. 3, FIG. 3). Step B5, Step A7 in FIG. 3, Step D1 in FIG. 4, Step D2 in FIG. 4, Step C4 in FIG.

When the first control unit 1a is operating, the first monitoring unit 3a lights the first failure indicator lamp 6 in blue.
The light emitted from the first failure indicator lamp 6 is output from the first control unit 1a side via the monitoring unit left prism mirror 7 and the control unit left prism mirror 8 (steps B4 and B5 in FIG. 3). Step A8, Step D1, Step D2 and Step C5 in FIG. 4)

  Next, when the multiplexing device 14 is started, the second monitoring unit 4a acquires the location ID [2] from the second identifier storage unit 18 in the system bus 12 (Step A2, Step B1 and Step A3 in FIG. 3). Or step E2 and step E3 of FIG. 5).

  The second monitoring unit 4a checks whether or not the first control unit 1a is stopped. If the first control unit 1a is stopped, the second monitoring unit 4a repeats the stop confirmation operation of the first control unit 1 (step of FIG. 5). F1).

  The multiplexing device 14 confirms whether or not the first control unit 1a is stopped by the second monitoring unit 4a, and performs location ID confirmation when the first control unit 1a is stopped (step B2 in FIG. 3). And step B1) of FIG.

The second monitoring unit 4a checks whether or not the first control unit 1a is stopped. As a result of this confirmation, when the first control unit 1a is operating, it is checked whether the second control unit 2a is stopped.
When the second control unit 2a is stopped, the second monitoring unit 4a lights the second failure indicator lamp 9 in red (Step B4, Step B5, Step A4 in FIG. 3, Step F1, Step F2 in FIG. 5). And step E4).

  The light emitted from the second failure indicator lamp 9 is output from the second control unit 2a side via the monitoring unit right prism-like mirror 10 and the control unit right prism-like mirror 11 (steps B2 and B3 in FIG. 3). Step A4, Step F1, Step F2 and Step E4 in FIG. 5).

When the second control unit 2a is operating, the second failure indicator lamp 9 is lit blue.
The light emitted from the second failure indicator lamp 9 is output from the second control unit 2a side via the monitoring unit right prism-like mirror 10 and the control unit right prism-like mirror 11 (steps B2 and B3 in FIG. 3). Step A5, Step F1, Step F2 and Step E5 in FIG.

  According to the failure display operation, the control unit side that failed first is lit red, and the control unit side that was stopped later remains lit blue. For this reason, when multiple failures occur in the control unit, it is possible to visually check the failure order of the control unit later, improving the maintenance work efficiency in the case of multiple failures in the redundant device, and operating efficiency of the device. Is also improved.

  As described above, according to the first embodiment, the order of failure occurrence of each electronic device is increased with respect to the increase in multiple failures caused by the increase in the speed of the device control unit such as the control circuit and the storage circuit constituting the electronic device. Equipped with a monitoring electronic device that is dedicatedly monitored and continues to operate even in the event of multiple failures. This monitoring electronic device is equipped with a failure indicator light that can be operated even in the event of multiple failures. Since the failure occurrence order is displayed on the display unit for each device via the optical transmission part that does not affect the system, it becomes possible to visually check the failure occurrence order for multiple failures in real time. Can be simplified and more efficient

That is, the first effect is that it is easy to specify the failure order when multiple failures occur in the duplexer.
The second effect is that the duplication device has the effect of shortening the time for fault location isolation after the occurrence of multiple faults.
Furthermore, the third effect is that a stable operation is realized by reliably detecting a failure without closing the monitoring bus in the duplex device.

  Further, compared with a system in which a lamp is displayed on the failure side by an electrical signal via the system bus from the normal side, the configuration of the system bus is reduced and an effect of improving reliability can be expected.

  Furthermore, in the failure status display operation when a redundant component failure is detected, each monitoring unit automatically analyzes the order in which the failure occurred, and automatically selects and displays the failure location based on the automatically analyzed failure order information. It becomes possible to specify the failure location more accurately than the related art method.

  Further, according to the above-described effects, there is a feature of identifying the failure location in a short time and easily in the operation of isolating the failure location of the redundant part, and shortening the work time required for replacing the failed component.

  Furthermore, when the failure mode of the control unit of each control unit is not a fixed failure mode but an intermittent failure mode and the case where the control unit independently performs automatic retry / automatic restart, There is a case where the failure order cannot be specified because the control unit independently performs automatic retry / automatic restart.

Even in such a case, the failure order information can be postponed by providing the failure indicator lamp of each monitoring unit with hysteresis such as not changing the color of the lamp for a certain period of time so that the failure order can be confirmed later. It becomes possible to confirm from.
That is, in this case, when the electronic device is automatically restarted, the lighting control function unit is configured so that the failure information is held in the function display unit for a certain period of time. The lighting control may be performed.

  In addition, in the bus part of related technology that shares the control bus and the monitoring bus, there is a possibility that the monitoring mechanism may be stopped from the stop of the system bus. What is the multiple failure of redundant parts such as the control part that shares the system bus? Quite separately, there is a tendency that the monitoring mechanism stops and the failure lamp does not light up.

  On the other hand, in the present embodiment, the monitoring dedicated bus of the monitoring unit is separated independently of the control bus, so that monitoring is possible regardless of the multiple failure.

  Further, in the configuration having two monitoring mechanisms in the duplexing device, sharing the monitoring bus also suggests the possibility that both monitoring mechanisms may be stopped from the monitoring bus stop as in the case of the multiple failure. When the bus is stopped, it is conceivable that both of the monitoring mechanisms are stopped and the failure lamps of both of the monitoring mechanisms are not turned on, apart from multiple failures of redundant parts such as a control unit sharing the system bus.

  On the other hand, in this embodiment, the monitoring dedicated bus of each monitoring unit is separated from the first monitoring bus and the second monitoring bus, so that each monitoring unit can operate independently, and within the monitoring bus The number of elements of is also minimal. The above configuration simplifies the monitoring logic and minimizes the probability of the monitoring bus being stopped.

  Furthermore, it is possible to combine optical connection using a prism-shaped mirror and optical connection using a loop-shaped optical path. According to the combination, the degree of freedom in layout is increased, and various arrangement configurations can be taken.

In the present embodiment, there is no medium between the short sides of the delta shape where the short sides of the delta shape are in contact with each other, and there is an effect that the light reliably reaches the counterpart module without being diffused.
Furthermore, even when there is a light guiding path between delta and delta, the refractive index of the medium between the short side of the delta shape and the short side of the delta shape and the medium of the delta shape is (substantially) the same. It has a reliable transmission effect to the other module without diffusing light.
In this way, it can be transmitted reliably without being diffused.

Furthermore, in Patent Document 2, the bus between SVCx and CMx is not separated from the system bus, and if the system bus is stopped due to an SVCx failure or CMx failure, CMx mutual monitoring is disabled / CMx is completely stopped. There is also a problem that the system is stopped.
On the other hand, in this embodiment, the monitoring bus and the system bus are separated as a configuration, and it is unlikely that the entire system will be stopped, and the monitoring unit is separated even in the case of multiple faults in the control unit (CMx). Cross check makes it possible to specify the failure order and minimizes failure location isolation time.

In this embodiment, since the configuration is optical connection / prism transmission, the driver circuit and the receiver circuit are not necessary, and the scale of the electric circuit is minimized and the failure rate is minimized.
In addition, when an optical cable is used to transmit a state between different housings, even if a long distance transmission of several meters to several tens of meters is performed, it is not necessary to take measures against data corruption.

  In the related art, since the monitoring bus and the control bus are not separated, there is a high possibility that the system bus is stopped due to a failure of the control unit. In addition, when there is no failure order control and multiple control unit failures occur, all control units display a failure display. Furthermore, even if there is a time lag in each control unit failure due to multiple failures in the control unit and the failure order is important, if the control unit operation speed is fast, multiple failures will occur when arriving at the site. Therefore, it cannot be specified which control unit has failed first.

On the other hand, in the present embodiment, the monitoring bus and the system bus are separated as a configuration, and since the monitoring bus is duplicated, the probability that the monitoring unit is stopped due to a control unit failure is small.
Moreover, it has failure order control, and when the control unit has multiple failures, the failure order can be specified.
Furthermore, by introducing a hysteresis operation in the failure lamp control, it is possible to check the lamp later even in a system in which all control units are automatically restarted in the event of multiple failures.

  In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer. The program may be read from the storage medium and executed.

[Second Embodiment]
Next, a second embodiment according to the present invention will be described with reference to FIGS. FIG. 6 is an explanatory diagram showing an example of the overall configuration of the multiplexing apparatus according to the second embodiment of the present invention. FIG. 7 is an explanatory diagram showing an example of a detailed configuration of the multiplexing device of FIG.

  The first embodiment is different in the stacking order of the monitoring unit and the control unit, having two display units per control unit, and different in the connection structure of the first monitoring bus and the second monitoring bus. Different from the embodiment.

  Specifically, referring to FIGS. 6 to 7, the multiplexing device 41 of the second embodiment includes a first control unit 21 a in one electronic device 21, and one monitoring corresponding to the one electronic device 21. The first monitoring unit 23a in the electronic device 23, the second monitoring unit 24a in the other monitoring electronic device 24 corresponding to the other electronic device 22, and the second control unit 22a in the other electronic device 22 are stacked in this order. Has been.

In addition, the device display unit of the one electronic device 21 has one first display unit (“FAULT-A”) and one of the first display units (“FAULT-A”) functioning equivalently. The second display unit (“FAULT-C”) is used.
Similarly, the device display unit of the other electronic device 22 is configured such that the other first display unit (“FAULT-B”) and the other first display unit (“FAULT-B”) function equivalently. The second display section (“FAULT-D”).

  Further, a first failure indicator lamp 25 (corresponding to the “first failure” in the present invention) is provided in the monitoring electronic device 23 in correspondence with one electronic device 21 and emits light according to the monitoring result of the first monitoring unit 23a. Indicator light ”) and a fourth failure indicator light 28 (corresponding to the“ second failure indicator light ”in the present invention) provided corresponding to the other electronic device 22 and emitting light in accordance with the monitoring result of the first monitoring unit 23a. ).

Furthermore, a second failure indicator lamp 26 (corresponding to the “first failure” in the present invention) is provided corresponding to the other electronic device 22 in the monitoring electronic device 24 and emits light according to the monitoring result in the second monitoring unit 24a. Indicator lamp ”) and a third failure indicator lamp 27 (corresponding to the present invention“ second failure indicator lamp ”) that is provided corresponding to one electronic device 21 and emits light according to the monitoring result of the second monitoring unit 24a. ).
Here, the first failure indicator lamp 25, the second failure indicator lamp 26, the third failure indicator lamp 27, the fourth failure indicator lamp 28, and the “first failure indicator lamp” and “ Note the correspondence with the “second failure indicator”. The rank number indicating the failure indicator lamp as the subordinate concept of the embodiment does not necessarily match the rank number indicating the fault indicator lamp as the upper or middle concept defined in the claims.

When the one and other electronic devices 21 and 22 are stacked, the second display unit (“FAULT-C”) of the one electronic device 21 is arranged at the outer end of the one electronic device 21 in the stacking direction. Established.
Further, the second display unit (“FAULT-D”) in the other electronic device 22 is disposed at the outer end portion in the stacking direction of the other electronic device 22.

  In addition, the light transmission unit in the multiplexing device 41 is a first display unit provided in one of the electronic devices 21 with the output light from the failure indicator lamp (first failure indicator lamp 25) in the monitoring electronic device 23. 1st light transmission part for other electronic devices which guides and transmits toward ("FAULT-A") (first control part right prism-like mirror 29, first control part right prism-like mirror 30, first control part right A prismatic mirror 31) is provided.

  Further, the light transmission unit in the multiplexing device 41 is provided with a second output device equipped with the output light from the second failure indicator lamp (fourth failure indicator lamp 28) in the monitoring electronic device 23 in the other electronic device 22. Second light transmitting unit for other electronic devices that guides and transmits the light toward the display unit (“FAULT-D”) (second control unit left prism-shaped mirror 38, second control unit left prism-shaped mirror 39, second control The upper prism-like mirror 40) is provided.

  The light transmission unit in the multiplexing device 41 is a first display unit provided in the other electronic device 22 with output light from the failure indicator lamp (second failure indicator lamp 26) in the monitoring electronic device 24. (3rd other electronic equipment light transmission part (second control part left prism-like mirror 32, second control part left prism-like mirror 33, second control part left prism) that guides and transmits toward ("FAULT-B") Shaped mirror 34).

  Further, the light transmission unit in the multiplexing device 41 is provided with a second output device in which one of the electronic devices 21 is equipped with output light from the second failure indicator lamp (third failure indicator lamp 27) in the monitoring electronic device 24. 4th light transmission part for other electronic devices which guides and transmits toward a display part ("FAULT-C") (1st control part right prism-like mirror 35, 1st control part right prism-like mirror 36, 1st control) A subordinate prismatic mirror 37) is provided.

  Further, each of the light transmission units for other electronic devices is arranged corresponding to the arrangement of the display units, and has a loop-shaped light path in part.

Further, the system bus 20 in the multiplexing device 41 includes a control bus 42, a first monitoring bus 43, a second monitoring bus 44, a first identifier storage unit 45, and a second identifier storage unit 46.
The first monitoring bus 43 includes a first control unit 21a (device control unit) in the electronic device 21, a second control unit 22a (device control unit) in the electronic device 22, a first monitoring unit 23a, and a second monitoring unit 24a. Are connected.
The second monitoring bus 44 is a transmission path independent of the first monitoring bus 43, and the first control unit 21 a (device control unit) in the electronic device 21 and the second control unit 22 a (device control unit) in the electronic device 22. ) And the first monitoring unit 23a and the second monitoring unit 24a.

(About operation procedure)
Next, an operation processing procedure in the multiplexing apparatus 41 having the above-described configuration will be described with reference to the flowcharts of FIGS. 6 to 7 and FIGS. 8 to 10.

When the multiplexing device 41 is started, the first control unit 21 a and the second control unit 22 a start control operations via the control bus 42 in the system bus 20.
The first monitoring unit 23a starts a monitoring operation via the first monitoring bus 43 connecting the first control unit 21a, the second control unit 22a, and the first monitoring unit 23a.
The second monitoring unit 24a starts the monitoring operation via the second monitoring bus 44 connecting the first control unit 21a, the second control unit 22a, and the second monitoring unit 24a (step G1 in FIG. 8, step in FIG. 9). J1, step L1 in FIG.

  When the multiplexing device 41 is started, the first control unit 21a, the second control unit 22a, the first monitoring unit 23a, and the second monitoring unit 24a are connected to the first identifier storage unit 45 or the second identifier storage unit in the system bus 20. The location ID is acquired from 46 (step J2 in FIG. 9 and step L2 in FIG. 10).

  When the multiplexing device 41 is started, the first control unit 21a and the first monitoring unit 23a obtain the location ID [1] from the first identifier storage unit 45 in the system bus 20 (step J3 in FIG. 9).

  When the multiplexing device 41 is started, the second control unit 22a and the second monitoring unit 24a obtain the location ID [2] from the second identifier storage unit 46 in the system bus 20 (step L3 in FIG. 10).

The multiplexing device 41 confirms whether or not the first control unit 21a is stopped.
When the first control unit 21a is stopped, it is further confirmed whether or not the second control unit 22a is stopped. When the second control unit 22a is also stopped, the first control unit 21a is stopped without doing anything. (Step H1 and Step H3 in FIG. 8).

The first monitoring unit 23a checks whether or not the first control unit 21a is stopped.
When the first control unit 21a is stopped, it is further confirmed whether or not the second control unit 22a is stopped. When the second control unit 22a is also stopped, the first control unit 21a is stopped without doing anything. (Step K1 and Step K3 in FIG. 9).

  The second monitoring unit 24a checks whether or not the first control unit 21a is stopped. If the first control unit 21a is stopped, the second monitoring unit 24a checks whether or not the second control unit 22a is stopped. 2 When the control unit 22a is also stopped, it is checked whether the first control unit 21a is stopped without doing anything (step M1 in FIG. 10 and step M3 in FIG. 10).

If the first control unit 21a is not stopped, the multiplexing device 41 checks whether the second control unit 22a is stopped. If the second control unit 22a is stopped, the multiplexing device 41 displays a second failure indication. The lamp 26 and the fourth failure indicator lamp 28 are lit red.
The light emitted from the second failure indicator lamp 26 passes through the second control unit left prism-like mirror 32, the second control unit left prism-like mirror 33, and the second control unit left prism-like mirror 34, and then the second control unit 22a. Output from the side.
The light emitted from the fourth failure indicator lamp 28 passes through the second control unit left prism-shaped mirror 38, the second control unit left prism-shaped mirror 39, and the second control unit upper prism-shaped mirror 40, and then the second control unit 22a. (Step H1, Step H2 in FIG. 8 and Step G2 in FIG. 8).

If the first control unit 21a is not stopped, the multiplexing device 41 checks whether the second control unit 22a is stopped. If the second control unit 22a is not stopped, the multiplexing device 41 displays a second failure indication. The lamp 26 and the fourth failure indicator lamp 28 are lit in blue.
The light emitted from the second failure indicator lamp 26 passes through the second control unit left prism-like mirror 32, the second control unit left prism-like mirror 33, and the second control unit left prism-like mirror 34, and then the second control unit 22a. Output from the side.
The light emitted from the fourth failure indicator lamp 28 passes through the second control unit left prism-shaped mirror 38, the second control unit left prism-shaped mirror 39, and the second control unit upper prism-shaped mirror 40, and then the second control unit 22a. (Step H1, Step H2, and Step G3 in FIG. 8).

  The first monitoring unit 23a checks whether or not the second control unit 22a is stopped when the first control unit 21a is not stopped. If the second control unit 22a is stopped, a fourth failure is detected. The indicator lamp 28 is lit red.

  The light emitted from the fourth failure indicator lamp 28 passes through the second control unit left prism-shaped mirror 38, the second control unit left prism-shaped mirror 39, and the second control unit upper prism-shaped mirror 40, and then the second control unit 22a. (Step K1, Step K2, and Step J4 in FIG. 9).

The first monitoring unit 23a checks whether or not the second control unit 22a is stopped when the first control unit 21a is not stopped. If the second control unit 22a is not stopped, the fourth failure is detected. The indicator lamp 28 is lit in blue.
The light emitted from the fourth failure indicator lamp 28 passes through the second control unit left prism-shaped mirror 38, the second control unit left prism-shaped mirror 39, and the second control unit upper prism-shaped mirror 40, and then the second control unit 22a. (Step K1, Step K2, and Step J5 in FIG. 9).

The second monitoring unit 24a checks whether or not the second control unit 22a is stopped when the first control unit 21a is not stopped. If the second control unit 22a is stopped, the second failure is detected. The indicator lamp 26 is lit red.
The light emitted from the second failure indicator lamp 26 passes through the second control unit left prism-shaped mirror 32, the second control unit left prism-shaped mirror 33, and the second control unit left prism-shaped mirror 34, and then the second control unit. Output from the 22a side (step M1, step M2 and step L4 in FIG. 10).

The second monitoring unit 24a checks whether the second control unit 22a is stopped when the first control unit 21a is not stopped. If the second control unit 22a is not stopped, the second failure is detected. The indicator lamp 26 is lit in blue.
The light emitted from the second failure indicator lamp 26 passes through the second control unit left prism-shaped mirror 32, the second control unit left prism-shaped mirror 33, and the second control unit left prism-shaped mirror 34, and then the second control unit. Output from the 22a side (step M1, step M2, and step L5 in FIG. 10).

The multiplexing device 41 checks whether or not the first control unit 21a is stopped when the second control unit 22a is operating. If the first control unit 21a is stopped, the multiplexing device 41 displays the first failure indication. The lamp 25 and the third failure indicator lamp 27 are lit red.
The light emitted from the first failure indicator lamp 25 passes through the first control unit right prism-shaped mirror 29, the first control unit right prism-shaped mirror 30, and the first control unit right prism-shaped mirror 31, and then the first control unit 21a. Output from the side.
The light emitted from the third failure indicator lamp 27 passes through the first control unit right prism-like mirror 35, the first control unit right prism-like mirror 36, and the first control unit lower prism-like mirror 37, on the first control unit 21 a side. (Step H3, Step H4, and Step G4 in FIG. 8).

The multiplexing device 41 checks whether or not the first control unit 21a is stopped when the second control unit 22a is operating. If the first control unit 21a is not stopped, the multiplexing device 41 displays the first failure indication. The lamp 25 and the third failure indicator lamp 27 are lit blue.
The light emitted from the first failure indicator lamp 25 passes through the first control unit right prism-shaped mirror 29, the first control unit right prism-shaped mirror 30, and the first control unit right prism-shaped mirror 31, and then the first control unit. Output from the 21a side.
The light emitted from the third failure indicator lamp 27 passes through the first control unit right prism-like mirror 35, the first control unit right prism-like mirror 36, and the first control unit lower prism-like mirror 37, and thus the first control unit 21a. (Step H3, Step H4, and Step G5 in FIG. 8).

The first monitoring unit 23a checks whether or not the first control unit 21a is stopped when the second control unit 22a is not stopped. If the first control unit 21a is stopped, the first failure is detected. The indicator lamp 25 is lit red.
The light emitted from the first failure indicator lamp 25 passes through the first control unit right prism-shaped mirror 29, the first control unit right prism-shaped mirror 30, and the first control unit right prism-shaped mirror 31, and then the first control unit. The data is output from the 21a side (step K3, step K4, and step J6 in FIG. 9).

The first monitoring unit 23a checks whether or not the first control unit 21a is stopped when the second control unit 22a is not stopped. If the first control unit 21a is not stopped, the first failure is detected. The indicator lamp 25 is lit in blue.
The light emitted from the first failure indicator lamp 25 passes through the first control unit right prism-shaped mirror 29, the first control unit right prism-shaped mirror 30, and the first control unit right prism-shaped mirror 31, and then the first control unit. The data is output from the 21a side (step K3, step K4, and step J7 in FIG. 9).

The second monitoring unit 24a checks whether or not the first control unit 21a is stopped when the second control unit 22a is not stopped. If the first control unit 21a is stopped, the second failure is detected. The indicator lamp 27 is lit red.
The light emitted from the third failure indicator lamp 27 passes through the first control unit right prism-like mirror 35, the first control unit right prism-like mirror 36, and the first control unit lower prism-like mirror 37, on the first control unit 21 a side. (Step M3, Step M4, and Step L6 in FIG. 10).

The second monitoring unit 24a checks whether or not the first control unit 21a is stopped when the second control unit 22a is not stopped. If the first control unit 21a is not stopped, the second failure is detected. The indicator lamp 27 is lit in blue.
The light emitted from the third failure indicator lamp 27 passes through the first control unit right prism-like mirror 35, the first control unit right prism-like mirror 36, and the first control unit lower prism-like mirror 37, on the first control unit 21 a side. (Step M3, Step M4, and Step L7 in FIG. 10).

  As described above, according to the second embodiment, even when the first monitoring unit fails, the failure display operation is not interrupted by continuing the operation of the second monitoring unit. Yes.

  Further, since two failure indicator lamps are prepared in each control unit, there is a merit that the failure display operation can be continued even when one failure indicator lamp fails. Furthermore, since the display unit can be installed over the most part of the lower side of the first electronic device 21 and the upper side of the second electronic device 22, respectively, there is a degree of freedom of failure display, and therefore the variety of failure display is improved. There is an advantage that it can cope effectively.

  Other configurations, other steps or functions, and the effects thereof are the same as those in the first embodiment described above. In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer.

[Third Embodiment]
Next, a third embodiment according to the present invention will be described with reference to FIGS. FIG. 11 is an explanatory diagram showing an example of the overall configuration of the multiplexing apparatus according to the third embodiment of the present invention. FIG. 12 is an explanatory diagram showing an example of a detailed configuration of the multiplexing device of FIG.

The third embodiment is different from the second embodiment in that it has a 2 × 2 parallel structure.
Specifically, referring to FIGS. 11 to 12, the multiplexing device 67 of the third embodiment includes a first control unit 51 a in one electronic device 51 and one monitoring corresponding to the one electronic device 51. The first monitoring unit 53a in the electronic device 53 for use is arranged on the first layer.
In the multiplexing device 67, the second control unit 52a in the other electronic device 52 and the second monitoring unit 54a in the other monitoring electronic device 54 corresponding to the other electronic device 52 are arranged in the second layer. The

Accordingly, the shapes of the control bus 68, the first monitoring bus 69, and the second monitoring bus 70 of the system bus 50 are different from those of the second embodiment.
The first monitoring bus 69 has a substantially L-shaped cross section, and connects the first control unit 51a, the second control unit 52a, and the first monitoring unit 53a.
The second monitoring bus 70 is configured in a substantially L-shaped cross section whose direction is opposite to that of the first monitoring bus 69, and connects the first control unit 51a, the second control unit 52a, and the second monitoring unit 54a.
The control bus 68 is disposed obliquely between the first monitoring bus 69 and the second monitoring bus 70.

In the multiplexing device 67, the first display unit (“FAULT-A”) and the second display unit (“FAULT-C”) are configured in the first layer, and the first display unit (“FAULT-B”) and The second display unit (“FAULT-D”) is configured in the second layer.
The multiplexing device 67 further includes a second failure indicator lamp 56 and a third failure indicator lamp 57 on the second layer, and a first failure indicator lamp 55 and a fourth failure indicator lamp 58 on the first layer.

Further, the first optical transmission unit for other electronic devices in the multiplexing device 67 includes a first control unit left prism-like mirror 59.
Further, the second light transmission unit for other electronic equipment includes a loop optical path of an optical fiber in part, and includes a second control unit left light path cladding 64, a second control unit left light path core 65, and a second control unit. A left prism-like mirror 66 is provided.
The third other electronic device optical transmission unit includes a second control unit right prism mirror 60.
Further, the fourth optical transmission unit for other electronic equipment includes a loop optical path of an optical fiber in part, and includes a first control unit right light path cladding 61, a first control unit right light path core 62, and a first control unit. And a right prism mirror 63.

  The system bus 50 includes a first identifier storage unit 71 and a second identifier storage unit 72.

  Light incident on the optical path cladding and the optical path core (optical fiber) is repeatedly reflected in the optical path core, and is output as light from each control unit side prism-shaped mirror.

  Next, the operation processing procedure in the multiplexing device 67 having the above-described configuration is that an optical signal is output through an optical fiber and a prismatic mirror (steps N2 and N4 shown in FIG. 13, step Q4 shown in FIG. 14, FIG. Other than step S6) shown in Fig. 15, the second embodiment is the same as the second embodiment.

As described above, according to the third embodiment, the height of the apparatus can be kept low, and the apparatus can be reduced in thickness and size.
In the third embodiment, since failure information including the failure occurrence order is transmitted by optical fiber, each control unit and each monitoring unit are connected by optical fiber, and each control unit and each monitoring unit are connected to each other. As long as the system bus can be connected, each control unit and each monitoring unit of the duplexing device do not necessarily have to be joined vertically and horizontally (or front and back), and each control unit and each monitoring unit may be installed separately. It becomes possible.

  From the above, in the case where the system bus is optically connected instead of electrically connected in the future, the degree of freedom in layout is further increased.

  Other configurations, other steps or functions, and the effects thereof are the same as those in the second embodiment described above. In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer.

[Fourth Embodiment]
Next, a fourth embodiment according to the present invention will be described with reference to FIGS. FIG. 16 is an explanatory diagram showing an example of the overall configuration of the multiplexing device according to the fourth embodiment of the present invention. FIG. 17 is an explanatory diagram showing an example of a detailed configuration of the multiplexing device of FIG.

  The fourth embodiment is different from the second embodiment in that the storage electronic devices are further multiplexed.

  Specifically, referring to FIG. 16 to FIG. 17, the multiplexing apparatus 100 of the fourth embodiment replaces the first storage unit 85a in the storage electronic device 85 dedicated for data storage with the first control unit in the electronic device 81. The second storage unit 86a in the storage electronic device 86 dedicated to data storage is arranged in the uppermost layer so as to correspond to the second control unit 82a in the electronic device 82. Yes.

  In this case, the first monitoring unit 83a in the monitoring electronic device 83 and the second monitoring unit 84a in the monitoring electronic device 84 also monitor the operating state of the storage electronic devices 85 and 86, and the storage electronic device 85, 86 and a function of analyzing a failure occurrence order including the electronic devices 81 and 82 may be provided.

  The multiplexing apparatus 100 includes a first storage unit 85a in the storage electronic device 85 in the first layer, a first monitoring unit 83a in the monitoring electronic device 83 in the second layer, and a first control unit in the electronic device 81 in the third layer. 81a, the fourth layer includes the second control unit 82a in the electronic device 82, the fifth layer includes the second monitoring unit 84a in the monitoring electronic device 84, and the sixth layer includes the second storage unit 86a in the storage electronic device 86.

In the multiplexing apparatus 100, the first display unit (“FAULT-A”) related to one electronic device 81 is configured in the third layer, and the third display unit (related to one storage electronic device 85) ( “FAULT-E”) is configured in the first layer.
Further, in the multiplexing apparatus 100, the first display unit (“FAULT-B”) related to the other electronic device 82 is configured in the fourth layer, and the third display unit (related to the other storage electronic device 86) ( “FAULT-F”) is configured in the sixth layer.

  The multiplexing apparatus 100 further includes a first failure indicator lamp 87 and a fifth failure indicator lamp 93 on the second layer, and a second failure indicator lamp 90 and a sixth failure indicator lamp 96 on the fifth layer.

  In addition, the light transmission unit in the multiplexing apparatus 100 transmits the output light (display optical signal) from the failure indicator lamp (first failure indicator lamp 87) in one monitoring electronic device 83 to the one electronic device 81. A first optical transmission unit for other electronic devices that guides and transmits toward the equipped first display unit (“FAULT-A”) (first monitoring unit left prism-like mirror 88, first control unit left prism-like mirror) 89).

  Furthermore, the light transmission unit in the multiplexing apparatus 100 is equipped with the output light from the third failure indicator lamp (fifth failure indicator lamp 93) in one monitoring electronic device 83 in one storage electronic device 85. A fifth other electronic device light transmission unit (first monitoring unit right prism mirror 94, first storage unit right prism mirror 95) that guides and transmits to the third display unit ("FAULT-E"). Prepare.

  In addition, the light transmission unit in the multiplexing apparatus 100 has a first display provided in the other electronic device 82 with the output light from the failure indicator light (second failure indicator light 90) in the other monitoring electronic device 84. A third optical transmission unit for other electronic devices (second monitoring unit right prism-shaped mirror 91 and second control unit right prism-shaped mirror 92) that guides and transmits the component toward the unit ("FAULT-B").

  Further, the light transmission unit in the multiplexing apparatus 100 is equipped with the output light from the third failure indicator lamp (sixth failure indicator lamp 96) in the other monitoring electronic device 83 in the other storage electronic device 86. The sixth other electronic device light transmission unit (second monitoring unit left prism-shaped mirror 97, second storage unit left prism-shaped mirror 98) for guiding and transmitting toward the third display unit ("FAULT-F"). Prepare.

The system bus 99 of the multiplexing apparatus 100 includes a first monitoring bus 103, a second monitoring bus 104, a control bus 105, a first identifier storage unit 101, and a second identifier storage unit 102.
The control bus 105 connects the first control unit 81a, the second control unit 82a, the first storage unit 85a, the second storage unit 86a, the first monitoring unit 83a, and the second monitoring unit 84a.
The first monitoring bus 103 is formed independently of the control bus 105, and includes a first control unit 81a, a second control unit 82a, a first storage unit 85a, a second storage unit 86a, a first monitoring unit 83a, and a second monitoring unit. The monitoring unit 84a is connected.
The second monitoring bus 104 is formed independently of the first monitoring bus 103, and includes a first control unit 81a, a second control unit 82a, a first storage unit 85a, a second storage unit 86a, and a first monitoring unit 83a. The second monitoring unit 84a is connected.

(About operation procedure)
Next, an operation processing procedure in the multiplexing apparatus 100 having the above-described configuration will be described in detail with reference to FIGS. 16 to 17 and FIGS. 18 to 20.

When the multiplexing apparatus 100 is started, the first control unit 81a, the second control unit 82a, the first storage unit 85a, and the second storage unit 86a start the control operation and the storage operation via the control bus 105 in the system bus 99. To do.
The first monitoring unit 83a performs a monitoring operation via the first monitoring bus 103 connecting the first control unit 81a, the second control unit 82a, the first storage unit 85a, the second storage unit 86a, and the first monitoring unit 83a. To start.
Further, the second monitoring unit 84a performs a monitoring operation via the first control unit 81a, the second control unit 82a, the first storage unit 85a, and the second monitoring bus 104 connecting the second storage unit 86a and the second monitoring unit 84a. To start. (Step U1 in FIG. 18, Step V1 in FIG. 19, and Step W1 in FIG. 20)

  When the multiplexing apparatus 100 is started, the first control unit 81a and the first monitoring unit 83a acquire the location ID [1] from the first identifier storage unit 101 in the system bus 99 (step V2 in FIG. 19).

  When the multiplexing apparatus 100 is started, the second control unit 82a and the second monitoring unit 84a obtain the location ID [2] from the second identifier storage unit 102 in the system bus 99 (step W2 in FIG. 20).

  The multiplexing apparatus 100 checks whether or not the first control unit 81a is stopped. If the first control unit 81a is stopped, the multiplexing apparatus 100 checks whether or not the second control unit 82a is stopped. If the part 82a is also stopped, it is confirmed whether or not the second storage part 86a is stopped (step X1 in FIG. 18, step X3 in FIG. 18, and step X5 in FIG. 18).

  The multiplexing apparatus 100 confirms whether or not the second storage unit 86a is stopped. If the second storage unit 86a is stopped, the multiplexing apparatus 100 checks whether or not the first storage unit 85a is stopped. When the unit 85a is also stopped, it is confirmed whether or not the first control unit 81a is stopped (step X5 in FIG. 18, step X7 in FIG. 18, and step X1 in FIG. 18).

The multiplexing apparatus 100 checks whether or not the second control unit 82a is stopped when the first control unit 81a is not stopped. When the second control unit 82a is stopped, the multiplexing device 100 confirms the second failure indicator lamp. 90 is lit red.
The light emitted from the second failure indicator lamp 90 is output from the second control unit 82a side via the second monitoring unit right prism-shaped mirror 91 and the second control unit right prism-shaped mirror 92 (step of FIG. 18). X1, step X2, and step U2).

The multiplexing apparatus 100 checks whether or not the second control unit 82a is stopped when the first control unit 81a is not stopped. If the second control unit 82a is not stopped, the multiplexing device 100 confirms whether or not the second control indicator 81a is stopped. Turn 90 on blue.
The light emitted from the second failure indicator lamp 90 is output from the second control unit 82a side via the second monitoring unit right prism-shaped mirror 91 and the second control unit right prism-shaped mirror 92 (step of FIG. 18). X1, step X2, and step U3).

  The multiplexing apparatus 100 checks whether or not the first control unit 81a is stopped when the second control unit 82a is not stopped. When the first control unit 81a is stopped, the multiplexing device 100 checks the first failure indicator lamp. 87 is lit red. The light emitted from the first failure indicator lamp 87 is output from the first control unit 81a side via the first monitoring unit left prism mirror 88 and the first control unit left prism mirror 89 (step X3 in FIG. 18). Step X4 and Step U4).

  When the second control unit 82a is not stopped, the multiplexing apparatus 100 checks whether the first control unit 81a is stopped, and when the first control unit 81a is not stopped, the first failure indicator lamp 87 is lit blue. The light emitted from the first failure indicator lamp 87 is output from the first control unit 81a side via the first monitoring unit left prism mirror 88 and the first control unit left prism mirror 89 (step X3 in FIG. 18). , Step X4, and Step U5 in FIG. 18).

When the second storage unit 86a is not stopped, the multiplexing apparatus 100 checks whether or not the first storage unit 85a is stopped, and when the first storage unit 85a is stopped, the fifth failure indicator lamp 93 is lit red.
The light emitted from the fifth failure indicator lamp 93 is output from the first storage unit 85a side via the first monitoring unit right prism mirror 94 and the first storage unit right prism mirror 95 (step of FIG. 18). X5, step X6, and step U6).

If the second storage unit 86a is not stopped, the multiplexing apparatus 100 checks whether or not the first storage unit 85a is stopped. If the first storage unit 85a is not stopped, the multiplexing device 100 93 is lit blue.
The light emitted from the fifth failure indicator lamp 93 is output from the first storage unit 85a side via the first monitoring unit right prism mirror 94 and the first storage unit right prism mirror 95 (step of FIG. 18). X5, step X6, and step U7)

When the first storage unit 85a is not stopped, the multiplexing apparatus 100 checks whether or not the second storage unit 86a is stopped, and when the second storage unit 86a is stopped, the sixth failure indicator lamp 96 is used. Light up red.
The light emitted from the sixth failure indicator lamp 96 is output from the second storage unit 86a side via the second monitoring unit left prism mirror 97 and the second storage unit left prism mirror 98 (step of FIG. 18). X7, step X8, step U8).

When the first storage unit 85a is not stopped, the multiplexing apparatus 100 checks whether or not the second storage unit 86a is stopped, and when the second storage unit 86a is not stopped, the sixth failure indicator lamp 96 is used. Light up blue.
The light emitted from the sixth failure indicator lamp 96 is output from the second storage unit 86a side via the second monitoring unit left prism mirror 97 and the second storage unit left prism mirror 98 (step of FIG. 18). X7, step X8, and step U9).

  The first monitoring unit 83a checks whether or not the second control unit 82a is stopped. If the second control unit 82a is stopped, the first monitoring unit 83a repeats the operation to check whether or not the second storage unit 86a is stopped. (Step Z1 and Step Z3 in FIG. 19).

When the second control unit 82a is not stopped, the first monitoring unit 83a checks whether the first control unit 81a is stopped. When the first control unit 81a is stopped, the first failure display The lamp 87 is lit red.
The light emitted from the first failure indicator lamp 87 is output from the first control unit 81a side via the first monitoring unit left prism mirror 88 and the first control unit left prism mirror 89 (step of FIG. 19). Z1, step Z2, and step V3).

The first monitoring unit 83a checks whether or not the first control unit 81a is stopped when the second control unit 82a is not stopped. If the first control unit 81a is not stopped, the first failure indicator is displayed. The lamp 87 is lit in blue.
The light emitted from the first failure indicator lamp 87 is output from the first control unit 81a side via the first monitoring unit left prism mirror 88 and the first control unit left prism mirror 89 (step of FIG. 19). Z1, step Z2, and step V4).

When the second storage unit 86a is not stopped, the first monitoring unit 83a checks whether the first storage unit 85a is stopped.
The first monitoring unit 83a turns on the fifth failure indicator lamp 93 in red when the first storage unit 85a is stopped.
The light emitted from the fifth failure indicator lamp 93 is output from the first storage unit 85a side through the first monitoring unit right prism mirror 94 and the first storage unit right prism mirror 95 (step Z3 in FIG. 19). Step Z4 and Step V5).

The first monitoring unit 83a lights the fifth failure indicator lamp 93 in blue when the first storage unit 85a is not stopped.
The light emitted from the fifth failure indicator lamp 93 is output from the first storage unit 85a side through the first monitoring unit right prism mirror 94 and the first storage unit right prism mirror 95 (step Z3 in FIG. 19). Step Z4 and Step V6).

The second monitoring unit 84a checks whether or not the first control unit 81a is stopped.
When the first control unit 81a is stopped, the second monitoring unit 84a repeats the operation of confirming whether or not the first storage unit 85a is stopped (Step Y1 and Step Y3 in FIG. 20).

When the first control unit 81a is not stopped, the second monitoring unit 84a further checks whether the second control unit 82a is stopped.
The second monitoring unit 84a turns on the second failure indicator lamp 90 in red when the second control unit 82a is stopped.
The light emitted from the second failure indicator lamp 90 is output from the second control unit 82a side via the second monitoring unit right prism mirror 91 and the second control unit right prism mirror 92 (step Y1 in FIG. 20). , Step Y2, and Step W3).

When the first control unit 81a is not stopped, the second monitoring unit 84a checks whether the second control unit 82a is stopped.
When the second control unit 82a is not stopped, the second monitoring unit 84a turns on the second failure indicator lamp 90 in blue.
The light emitted from the second failure indicator lamp 90 is output from the second control unit 82a side via the second monitoring unit right prism mirror 91 and the second control unit right prism mirror 92 (step Y1 in FIG. 20). Step Y2 and Step W4).

If the first storage unit 85a is not stopped, the second monitoring unit 84a checks whether the second storage unit 86a is stopped. If the second storage unit 86a is stopped, a sixth failure display is performed. The lamp 96 is lit red.
The light emitted from the sixth failure indicator lamp 96 is output from the second storage unit a86 side via the second monitoring unit left prism mirror 97 and the second storage unit left prism mirror 98 (step Y3 in FIG. 20). Step Y4 and Step W5).

The second monitoring unit 84a checks whether or not the second storage unit 86a is stopped when the first storage unit 85a is not stopped. If the second storage unit 86a is not stopped, a sixth failure display is performed. The lamp 96 is lit blue.
The light emitted from the sixth failure indicator lamp 96 is output from the second storage section 86a side via the second monitoring section left prism mirror 97 and the second storage section left prism mirror 98 (step Y3 in FIG. 20). Step Y4 and Step W6).

  As described above, according to the fourth embodiment, in the duplex device in which the control unit and the storage unit are separated, the failure order information and the failure location can be displayed even when multiple failures occur. It becomes possible.

  Other configurations, other steps or functions, and the effects thereof are the same as those in the second embodiment described above. In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer.

[Fifth Embodiment]
Next, a fifth embodiment according to the present invention will be described with reference to FIGS. FIG. 21 is an explanatory diagram showing an example of the overall configuration of the multiplexing apparatus according to the fifth embodiment of the present invention. FIG. 22 is an explanatory diagram showing an example of a detailed configuration of the multiplexing device of FIG.

  The fifth embodiment is different from the third embodiment in that a monitoring unit is configured at each side end of each stacked control unit.

Specifically, referring to FIG. 21 to FIG. 22, the multiplexing apparatus 200 of the fifth embodiment includes a first control unit 111a in one electronic device 111 and a second control unit 112a in another electronic device 112. Are stacked.
In the multiplexing apparatus 200, the first monitoring unit 113a in one monitoring electronic device 113 is arranged at one end of the direction intersecting the stacking direction, and the second monitoring unit 114a in the other monitoring electronic device 114 is disposed. Is disposed at the other end portion in the direction crossing the stacking direction.

In the multiplexing apparatus 200, the first display unit (“FAULT-A”) related to one electronic device 111 is configured in the first layer, and the second display unit (“FAULT-related” related to one electronic device 111 is configured. -C ") is configured in the first layer.
Further, in the multiplexing apparatus 200, the first display unit (“FAULT-B”) related to the other electronic device 112 is configured in the second layer, and the second display unit (“FAULT-related” related to the other electronic device 112 is configured. -D ") is configured in the second layer.

The multiplexing apparatus 200 further includes a first failure indicator lamp 115 at a height position corresponding to the first layer of the monitoring electronic device 113, and at a height position corresponding to the second layer of the monitoring electronic device 113. A fourth failure indicator lamp 118 is provided.
In addition, the multiplexing apparatus 200 further includes a third failure indicator lamp 117 at a height position corresponding to the first layer of the monitoring electronic device 114, and a height corresponding to the second layer of the monitoring electronic device 114. A second failure indicator lamp 116 is provided at the position.

  In addition, the light transmission unit in the multiplexing apparatus 200 includes a first display unit (equipped in one electronic device 111) with output light from the failure indicator lamp (first failure indicator lamp 115) in the monitoring electronic device 113. A first optical transmission unit for other electronic devices (first control unit left prism-shaped mirror 119) that guides and transmits the signal toward "FAULT-A").

  Further, the light transmission unit in the multiplexing device 200 provides the second display provided in the other electronic device 112 with the output light from the second failure indicator lamp (fourth failure indicator lamp 118) in the monitoring electronic device 113. A second optical transmission unit for second electronic equipment (second control unit left prism mirror 122) that guides and transmits the unit toward the unit ("FAULT-D").

  In addition, the light transmission unit in the multiplexing apparatus 200 is configured to output light from the failure indicator lamp (second failure indicator lamp 116) in the monitoring electronic device 114 to a first display unit (equipped in the other electronic device 112). A third optical transmission device (second control unit right prism mirror 120) for guiding and transmitting toward "FAULT-B" is provided.

  Furthermore, the light transmission unit in the multiplexing apparatus 200 is configured to provide a second display in which one of the electronic devices 111 is equipped with output light from the second failure indicator lamp (third failure indicator lamp 117) in the monitoring electronic device 113. A fourth optical transmission unit for other electronic devices (first control unit right prism-shaped mirror 121) that guides and transmits toward the unit ("FAULT-C").

Furthermore, the control bus 127, the first monitoring bus 123, and the second monitoring bus 124 in the system bus 110 of the multiplexing apparatus 200 have the shortest length.
The system bus 110 includes a first identifier storage unit 125 and a second identifier storage unit 126.

  The operation processing procedure in the multiplexing apparatus 200 having the above-described configuration is the same as that in the second embodiment.

As described above, according to the fifth embodiment, the height of the device can be kept low, the size and size of the device can be reduced, and the length of the control bus can be minimized.
In the fifth embodiment, the directions of the failure indicator lights in the first monitoring unit 113 and the second monitoring unit 114 are opposite, and the positions of the first identifier storage unit 125 and the second identifier storage unit 126 are also different. Yes. For example, considering the work of replacing the second monitoring unit 114 when it fails, when using the first monitoring unit 113 built in the multiplexing device 112 operating elsewhere, it is necessary to rotate 180 degrees and mount it upside down. There is.

  Furthermore, it is possible to combine the optical connection using the prism-shaped mirror and the optical connection using the loop-shaped optical path. According to the combination, the degree of freedom in layout is increased, and various arrangements can be taken.

  Other configurations, other steps or functions, and the effects thereof are the same as those in the second embodiment described above. In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer.

[Sixth Embodiment]
Next, a sixth embodiment according to the present invention will be described with reference to FIGS. FIG. 23 is an explanatory diagram showing an example of the overall configuration of the multiplexing apparatus according to the sixth embodiment of the present invention. FIG. 24 is an explanatory diagram showing an example of a detailed configuration of the multiplexing device of FIG.

  The sixth embodiment is different from the first embodiment in that the first monitoring unit and the second monitoring unit are provided in one monitoring electronic device.

Specifically, referring to FIGS. 23 to 24, the multiplexing device 128 of the sixth embodiment includes a first control unit 131 a in one electronic device 131, a monitoring unit 133 a in the monitoring electronic device 133, and other components. The second control unit 132a in the electronic device 132 is stacked.
The monitoring unit 133a in the monitoring electronic device 133 includes a first monitoring module 147 corresponding to the first monitoring unit and a second monitoring module 148 corresponding to the second monitoring unit.
The monitoring electronic device 133 includes a first failure indicator lamp 134 and a second failure indicator lamp 137.

  The light transmission unit in the multiplexing device 128 is a first display unit (“FAULT-A”) in which the output light from the first failure indicator lamp 134 in the monitoring electronic device 133 is installed in the other electronic device 132. The optical transmission part for other electronic devices (monitoring part left prism-like mirror 135, 2nd control part left prism-like mirror 136) which guides and transmits toward is provided.

  In addition, the light transmission unit in the multiplexing device 128 outputs the output light from the second failure indicator lamp 137 in the monitoring electronic device 133 to the first display unit (“FAULT-B) provided in one of the electronic devices 131. It includes a light transmission unit for other electronic devices that guides and transmits the light (a monitoring unit right prism mirror 138, a first control unit right prism mirror 139).

  The system bus 129 of the multiplexing device 128 includes a control bus 130, a first monitoring bus 143, a second monitoring bus 144, a first identifier storage unit 145, and a second identifier storage unit 146.

  The operation processing procedure in the multiplexing device 128 having the above-described configuration is the same as that in the first embodiment.

  As described above, according to the sixth embodiment, it is possible to reduce the height and height of the apparatus by integrating a monitoring unit having a relatively small circuit scale into one module.

  Furthermore, it is possible to combine the optical connection using the prism-shaped mirror and the optical connection using the loop-shaped optical path. According to the combination, the degree of freedom in layout is increased, and various arrangements can be taken.

  Other configurations, other steps or functions, and the effects thereof are the same as those in the above-described embodiment. In the above description, the operation content of each step described above, the constituent elements of each unit, and the functions thereof may be programmed (software program) and executed by a computer.

[Other variations]
Also, although the apparatus and method according to the present invention have been described according to some specific embodiments thereof, the embodiments described in the text of the present invention can be used without departing from the spirit and scope of the present invention. Various modifications are possible.

  For example, the number, position, shape, and the like of the constituent members are not limited to the above-described embodiment, and can be set to a suitable number, position, shape, and the like in practicing the present invention. That is, in the above-described embodiment, the case where there are two control units, two electronic devices, two monitoring electronic devices, and the like has been described, but the present invention does not limit the number thereof.

  In addition, the present invention is not limited to multiplexing redundant electronic devices, but a multiplexing device using a non-redundant electronic device, a multiplexing device including a redundant configuration in part, and various multiplexing combinations of these. It may be a multiplex pattern multiplexing device. The electronic device may be various circuits.

In addition, as a multiplexing device for electronic equipment, redundant components of computers (redundant storage controllers, redundant server controllers and redundant server monitoring mechanisms), redundant various network switches, and redundant devices It may be used for a private branch exchange or the like.
For example, in a multiplexing device in which servers are multiplexed, a server, which is an example of an electronic device, includes a plurality of CPU, memory, HDD, chipset, and other main components such as circuits in one electronic device. Including the case. In a multiplexing device in which each of these servers, which are a plurality of electronic devices, is multiplexed, the multiplexing device can be controlled by a single OS (operating system) (overall control unit). In this case, when a failure occurs, one of the failed parts is disconnected and replaced with another new server, so that the failed module can be replaced and the operation can be continued.
Furthermore, the bus unit may be configured by a system bus, or may be configured by various other buses such as a monitoring bus in addition to the system bus.

  As the storage unit, a hard disk, a semiconductor memory, an integrated circuit, a magneto-optical disk, a magnetic recording medium, or the like may be used.

  Furthermore, examples of the control unit include various servers, an EWS (engineering workstation), a medium-sized computer, and a mainframe.

  In addition, terms (first display unit, second display unit, first control unit, second control unit, etc.) cited as broad terms (device display unit, device control unit, etc.) in the description are as follows: In other descriptions in the specification, terms can be replaced with broad terms. Further, in the description in the specification, each operation content processed by each step is not described in the operation description of each step, but each write process is executed in each specific storage area in a storage medium or the like. Including things.

  The scope of the invention is not limited to the illustrated example. Further, the above embodiments include various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. That is, examples include combinations of the above-described embodiments, or any of them and any of the modifications.

  The present invention can be used for applications such as general electronic devices and redundant parts of electronic computers.

1, 21, 51, 81, 111, 131... One electronic device
1a, 21a, 51a, 81a, 111a, 131a... First control unit (device control unit)
2, 22, 52, 82, 112, 132... The other electronic device
2a, 22a, 52a, 82a, 112a, 132a... Second control unit (device control unit)
3, 23, 53, 83, 113, 133 ... one of the monitoring electronic devices
3a, 23a, 53a, 83a, 113a... First monitoring unit 4, 24, 54, 84, 114.
4a, 24a, 54a, 84a, 114a ... second monitoring unit 6, 25, 55, 87, 115, 134 ... first failure indicator lamp 7, ... monitoring unit left prism mirror ( Light transmission part)
8, ... Control unit left prism mirror (light transmission part)
9, 26, 56, 90, 116, 137... Second failure indicator lamp 10,... Monitoring unit right prism mirror (light transmission unit)
11, ... Control unit right prism mirror (light transmission unit)
12, 20, 50, 99, 110, 129... System bus (bus section)
13, 42, 68, 105, 127, 130... Control bus 14, 41, 67, 100, 200, 128... Multiplexer 15, 43, 69, 103, 123, 143. .. first monitoring bus 16, 44, 70, 104, 124, 144... Second monitoring bus 17, 45, 71, 101, 125, 145... First identifier storage unit 18, 46, 72 , 102, 126, 146... Second identifier storage unit 27, 57, 117... Third failure indicator lamp 28, 58, 118. ..First control unit right prism-shaped mirror (part of the first optical transmission unit for other electronic devices)
30... First control unit right prism-shaped mirror (part of first optical transmission unit for other electronic devices)
31... First control unit right prism-shaped mirror (part of the first optical transmission unit for other electronic devices)
38... Second control unit left prism mirror (part of second optical transmission unit for other electronic devices)
39... Second control unit left prism-like mirror (part of second optical transmission unit for other electronic devices)
40... Prism-like mirror on the second control unit (part of the second optical transmission unit for other electronic devices)
61... First control unit right light path cladding (part of looped light path)
62... First control unit right light path core (part of looped light path)
64... Second control unit left light path cladding (part of looped light path)
65... Second control unit left light path core (part of looped light path)
85... One storage electronic device
85a ······· First storage section 86 ······· the other storage electronic device
86a ········· Second storage section 93 ···························································································· Part)
148... Second monitoring module (second monitoring unit)

FAULT-A, FAULT-B ··· First display (device display)
FAULT-C, FAULT-D ··· Second display (device display)
FAULT-E, FAULT-F ··· Third display (device display)

Claims (10)

Two or more electronic devices including at least a device control unit;
A monitoring electronic device provided with a monitoring unit that monitors the operating state of each electronic device and analyzes the failure occurrence order of each electronic device;
A second monitoring unit provided in another electronic device for monitoring newly provided in each electronic device independently of the monitoring unit and having a function equivalent to the monitoring unit ;
A plurality of display units for each device that are provided on the electronic device side and each display an operating state of each electronic device;
A control bus that connects between the device control units in each electronic device, and a first monitoring bus that connects each device control unit and the monitoring unit in each electronic device independently of each other. A bus unit including a dedicated monitoring bus composed of a second monitoring bus connecting each device control unit and the second monitoring unit in each electronic device ,
A plurality of lights that are provided between the electronic devices and the monitoring electronic devices and transmit failure information indicating the failure occurrence order from the monitoring electronic devices to the corresponding device display units, respectively. A communication unit is provided between each of the electronic devices and the other monitoring electronic device, and the failure information indicating the failure occurrence order from the other monitoring electronic device is directed to the corresponding device display unit. A plurality of other light transmission units that transmit
Each of the monitoring electronic devices is
Each failure indicator lamp for inputting a display optical signal to each light transmission unit provided corresponding to each electronic device,
A lighting control function unit that controls lighting of each failure indicator lamp according to the order of occurrence of the failure,
Have
The lighting control function unit
Each failure indicator lamp is controlled to be displayed in a different color according to the failure order, and when each electronic device is automatically restarted, the failure information is displayed on each device display unit. It is configured to control lighting of each of the failure indicator lamps so as to be held for a certain period of time ,
One monitoring electronic device corresponding to one electronic device, the one electronic device, another electronic device, and another monitoring electronic device corresponding to the other electronic device are stacked in this order. ,
A multiplexing apparatus characterized in that each of the light transmission units is arranged corresponding to the arrangement . Two or more electronic devices including at least a device control unit ;
A monitoring electronic device provided with a monitoring unit that monitors the operating state of each electronic device and analyzes the failure occurrence order of each electronic device ;
A second monitoring unit provided in another electronic device for monitoring newly provided in each electronic device independently of the monitoring unit and having a function equivalent to the monitoring unit ;
A plurality of display units for each device that are provided on the electronic device side and each display an operating state of each electronic device ;
A control bus that connects between the device control units in each electronic device, and a first monitoring bus that connects each device control unit and the monitoring unit in each electronic device independently of each other. A bus unit including a dedicated monitoring bus composed of a second monitoring bus connecting each device control unit and the second monitoring unit in each electronic device ,
A plurality of lights that are provided between the electronic devices and the monitoring electronic devices and transmit failure information indicating the failure occurrence order from the monitoring electronic devices to the corresponding device display units, respectively. A communication unit is provided between each of the electronic devices and the other monitoring electronic device, and the failure information indicating the failure occurrence order from the other monitoring electronic device is directed to the corresponding device display unit. A plurality of other light transmission units that transmit
Each of the monitoring electronic devices is
Each failure indicator lamp for inputting a display optical signal to each light transmission unit provided corresponding to each electronic device ,
A lighting control function unit that controls lighting of each failure indicator lamp according to the order of occurrence of the failure ,
Have
The lighting control function unit
Each failure indicator lamp is controlled to be displayed in a different color according to the failure order, and when each electronic device is automatically restarted, the failure information is displayed on each device display unit. It is configured to control lighting of each of the failure indicator lamps so as to be held for a certain period of time ,
Each storage electronic device dedicated to data storage is arranged corresponding to each electronic device,
The multiplexing device, wherein the monitoring unit in the monitoring electronic device also monitors an operating state of the storage electronic device and analyzes a failure occurrence order including the storage electronic device and the electronic devices. . Two or more electronic devices including at least a device control unit ;
A monitoring electronic device provided with a monitoring unit that monitors the operating state of each electronic device and analyzes the failure occurrence order of each electronic device ;
A second monitoring unit provided in another electronic device for monitoring newly provided in each electronic device independently of the monitoring unit and having a function equivalent to the monitoring unit ;
A plurality of display units for each device that are provided on the electronic device side and each display an operating state of each electronic device ;
A control bus that connects between the device control units in each electronic device, and a first monitoring bus that connects each device control unit and the monitoring unit in each electronic device independently of each other. A bus unit including a dedicated monitoring bus composed of a second monitoring bus connecting each device control unit and the second monitoring unit in each electronic device ,
A plurality of lights that are provided between the electronic devices and the monitoring electronic devices and transmit failure information indicating the failure occurrence order from the monitoring electronic devices to the corresponding device display units, respectively. A communication unit is provided between each of the electronic devices and the other monitoring electronic device, and the failure information indicating the failure occurrence order from the other monitoring electronic device is directed to the corresponding device display unit. A plurality of other light transmission units that transmit
Each of the monitoring electronic devices is
Each failure indicator lamp for inputting a display optical signal to each light transmission unit provided corresponding to each electronic device ,
A lighting control function unit that controls lighting of each failure indicator lamp according to the order of occurrence of the failure ,
Have
The lighting control function unit
Each failure indicator lamp is controlled to be displayed in a different color according to the failure order, and when each electronic device is automatically restarted, the failure information is displayed on each device display unit. It is configured to control lighting of each of the failure indicator lamps so as to be held for a certain period of time ,
The device display unit of the electronic device is configured by a first display unit and a second display unit that functions in the same manner as the first display unit,
The monitoring electronic device is provided with a second failure indicator lamp that is provided corresponding to each electronic device and emits light according to the monitoring result in the monitoring unit,
The light transmission part is
A light transmission unit for a first other electronic device that guides and transmits the output light from the failure indicator lamp in the electronic device for monitoring toward a first display unit equipped in one of the electronic devices;
And a second light transmission unit for other electronic devices that guides and transmits the output light from the second failure indicator lamp in the monitoring electronic device toward the second display unit provided in the other electronic device. A multiplexing device characterized by the above. The multiplexing device according to claim 3 , wherein
One electronic device, one electronic device for monitoring corresponding to the one electronic device, another electronic device for monitoring corresponding to another electronic device, and the other electronic devices are stacked in this order. ,
In stacking the one and the other electronic devices, the second display portion in the one electronic device is disposed at the outer end portion in the stacking direction of the one electronic device, and the second display in the other electronic device is performed. Part is disposed at the outer end of the other electronic device in the stacking direction,
A multiplexing apparatus comprising: a light transmission unit for each other electronic device corresponding to each display unit. The multiplexing device according to claim 3 , wherein
The one electronic device and the one monitoring electronic device corresponding to the one electronic device are arranged in the first layer, and the other electronic device and the other electronic device corresponding to the other electronic device. Electronic devices are arranged on the second layer,
A multiplexing apparatus characterized in that the light transmission sections for other electronic devices are arranged corresponding to the arrangement. The multiplexing device according to claim 3 , wherein
One electronic device and another electronic device are stacked, and one monitoring electronic device corresponding to the one electronic device and another monitoring electron corresponding to the other electronic device The device is arranged in a direction crossing the stacking direction,
A multiplexing apparatus characterized in that the light transmission sections for other electronic devices are arranged corresponding to the arrangement. The multiplexing device according to claim 3 , wherein
The multiplexing apparatus according to claim 1, wherein the other electronic device optical transmission unit includes a loop optical path. The multiplexing device according to claim 3 , wherein
The multiplexing device according to claim 1, wherein the light transmission unit for other electronic devices includes one or a plurality of prismatic mirrors. The multiplexing device according to claim 3 , wherein
The multiplexing apparatus according to claim 1, wherein the other electronic device optical transmission unit includes an optical fiber in a part thereof. The multiplexing device according to claim 4 , wherein
The first monitoring bus connects each device control unit, the monitoring unit, and the second monitoring unit in each electronic device,
The second monitoring bus connects each device control unit, the monitoring unit, and the second monitoring unit in each electronic device through a transmission path independent of the first monitoring bus. Multiplexer to do.

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