JP5884368B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device.

  Conventionally, an image forming apparatus including a plurality of processing apparatuses has been proposed. FIG. 18 shows a simplified diagram of a conventional image forming apparatus. In the example of FIG. 18, there are an engine processing device 4100, a conveyance processing device 4200, an image forming processing device 4210, and a fixing processing device 4220 as a plurality of processing devices. In this technique, protection target data (running history information and user personal information) acquired by each of the plurality of processing devices 4200, 4210, and 4220 is transmitted via communication lines 41100, 42001, 42101, and 42201, and an EEPROM 4101 (nonvolatile memory). Remember me. Of the plurality of processing apparatuses in the image forming apparatus, the processing apparatus having the EEPROM 4101 is a main processing apparatus (engine processing apparatus 4100), and the other processing apparatuses are sub processing apparatuses (conveying processing apparatus 4200, image forming processing apparatus 4210). , Fixing processing device 4220).

  In Patent Document 1, when an abnormality occurs in the main processing device 4100, the protection target data stored in the EEPROM 4101 is transferred to the FROM 4221 of the sub-processing device (for example, the transport processing device 4200) that is operating normally. A technique for evacuating to (nonvolatile memory) via a communication line 42001 has been proposed.

  Communication lines 42001, 42101, and 42201 from the sub-processing devices 4200, 4210, and 4220 are connected to the communication line 41100. Accordingly, when the communication line 41100 is short-circuited due to an abnormality in the main processing apparatus, there is a problem that the normally-processed transfer processing apparatus 4200 cannot access the EEPROM 4101.

  According to the present invention, there is provided an electronic apparatus capable of saving data to be protected more appropriately than before when the main processing apparatus becomes abnormal.

The present invention is an electronic apparatus including a main processing device that stores data to be protected and a plurality of sub-processing devices capable of communicating with the main processing device, wherein the main processing device and the plurality of the plurality of the processing devices The determination means for determining whether each of the sub-processing devices is normal or abnormal, and the determination means indicate that the main processing device and the one or more sub-processing devices are abnormal, and the one or more sub-processing devices are normal. Communication blocking means for blocking the communication between the one or more sub-processing devices determined to be abnormal and the main processing device when determined, and the one or more determined to be normal When the communication is cut off by the selecting means for selecting any one of the sub-processing devices and the communication cut-off means, the main processing device stores the sub-processing device selected by the selection means. Keep Possess a storage control unit for storing the target data, wherein the sub-processing unit is a plurality, each the plurality of the sub-processing unit has available communication means and said storage means, said communication interrupting means The determination means determines that the main processing device is abnormal, at least one of the plurality of sub processing devices is abnormal, and at least one of the sub processing devices is the sub processing device. When it is determined that the processing device is normal, communication between the communication unit and the storage unit included in the at least one sub-processing device determined to be abnormal is also blocked, and the communication blocking unit is Each of the one or more sub-processing devices includes a blocking signal transmission unit, and the blocking signal transmission unit included in the sub-processing device selected by the selection unit includes the main processing unit. By sending a blocking signal for, to provide an electronic apparatus, characterized by blocking the communication of the is determined to be abnormal said one or more of the the sub-processing unit and the main processor.

  With the electronic device of the present invention, when the main processing apparatus becomes abnormal, the data to be protected can be saved more appropriately than before.

1 is a diagram illustrating a hardware configuration of an image forming apparatus according to an embodiment. The figure which showed the main processing apparatus and sub-processing apparatus of a present Example. The figure which showed the function structural examples, such as the main processing apparatus of a present Example. 1 is a diagram illustrating a functional configuration example of an image forming apparatus according to an embodiment. FIG. 3 is a diagram illustrating a main processing flow of the image forming apparatus according to the present exemplary embodiment. The figure which showed an example of the table of a present Example. The figure which showed the interruption | blocking signal etc. of a present Example. The figure which showed the interruption | blocking signal etc. of another embodiment. FIG. 10 is a diagram illustrating a main processing flow of an image forming apparatus according to another embodiment. The figure which showed the main processing apparatus of another embodiment, etc. The figure which showed the function structural example of the image forming apparatus of another embodiment. The figure which showed the power supply etc. of a present Example. FIG. 5 is a diagram illustrating a processing flow of an image forming apparatus according to another embodiment. The figure which showed the priority etc. of a present Example. The figure which showed the function structural examples, such as the main processing apparatus of another embodiment. The figure which showed the function structural example of the image forming apparatus of another embodiment. FIG. 5 is a diagram illustrating a processing flow of an image forming apparatus according to another embodiment. The figure which showed the conventional main processing apparatus and the sub-processing apparatus.

<Embodiment 1>
In the present embodiment, the electronic device has a plurality of processing devices, and is activated when power is supplied to perform predetermined processing. In the following description, it is assumed that the electronic device is an image forming apparatus. Examples of the image forming apparatus include a printer, a facsimile, a copying apparatus, a plotter, and a complex machine of these. Further, in the following description, in each embodiment, in the description of the functional configuration example and the processing flow, the same reference numerals and the same step numbers are added to the same processes, and the duplicate description is omitted.
[Hardware configuration]
FIG. 1 shows an example of the overall functional configuration of the image forming apparatus 1 of this embodiment. The image forming apparatus according to the present exemplary embodiment includes a plurality of processing devices. The plurality of processing devices include a controller processing device 700, an engine processing device 100, a reading processing device 600, a writing processing device 500, a paper conveyance processing device 200, an image forming processing device 210, a fixing processing device 220, and a power processing device. 300.

  The controller processing device 700 sets an image forming operation received from the user by the operation processing device 750. Specifically, the controller processing device 700 is responsible for image formation, user interface and mode setting, and processing of applications such as copying and printers. The controller processing device 700 includes a CPU (Central Processing Unit) 701, a FROM (flash memory) 702, an SRAM (Static Random Access Memory) 703, and an NVRAM (Non Volatile RAM) 706.

  The CPU 701 performs predetermined processing based on the processing program. The FROM 702 stores a processing program in a fixed manner. The SRAM 703 temporarily stores various information. The NVRAM 706 stores setting information for all the operating conditions of the image forming apparatus 1.

  Further, the LAN interface 780, the HDD 770, the fax unit 760, and the operation processing device 750 are connected to the controller processing device 700. The LAN interface 780 transmits and receives information from an external communication device (not shown) via a LAN or the like via a network. The HDD 770 stores predetermined (processing target) data.

  The controller interface processing device 400 serves as an interface between the engine control device 100, the conveyance control device 200, the image formation control device 210, and the fixing control device 220, and is connected to each other via a PCI bus. The controller processing device 700 receives an image forming operation from the operation processing device 750 and an image forming operation from an external device via the LAN interface 780, executes the image forming operation, and sends the created image to the engine processing device 100. Transmit via the PCI bus.

  A PSU (Power Supply Unit) 300 receives AC power from an external power source (outlet), converts the AC power into DC power, and supplies the DC power to each processing apparatus. Further, the AC power is not converted into a DC power but is used for the heater 810, and the fixing heat is generated in the heater 810.

  1 includes a solenoid 802, a clutch 804, a motor 806, a sensor 808, a heater 810, and the like. The conveyance processing apparatus 200 is connected to various electrical components 800 related to paper conveyance. For example, detection of JAM when a paper jam occurs can be detected by the CPU 202 reading the value of the sensor 808.

  The image forming processing device 210 is connected to various electrical components 800 related to image forming. If an error occurs in the sensor 808 or the like in the process of attaching toner to a drum or paper, the CPU 212 detects the error. I can do it.

  The fixing processing device 220 is connected to various electrical components 800 related to fixing, and heat or pressure is applied by a heater 810 or the like in order to fix the toner attached to the paper. The CPU 222 can detect the fixing temperature of the heater 810 and the presence / absence of a paper jam.

  The reading processing device 600 reads symbols and characters formed on a document set by a user. The writing processing device 500 forms an image on a photosensitive drum (not shown) with a laser beam.

  As described above, each of the engine processing apparatus 100, the conveyance processing apparatus 200, the image forming processing apparatus 210, the fixing processing apparatus 220, and the controller interface processing apparatus 400 includes the CPU 102, the CPU 202, the CPU 212, the CPU 222, and the CPU 402. The CPU 102, CPU 202, CPU 212, CPU 222, and CPU 402 have a built-in RAM that temporarily stores various types of information. In addition, the engine processing apparatus 100, the conveyance processing apparatus 200, the image forming processing apparatus 210, the fixing processing apparatus 220, and the controller interface processing apparatus 400 each have a FROM 103, a FROM 201, a FROM 211, a FROM 221, and a FROM 401 that store processing programs fixedly. Have.

The engine processing apparatus 100 has an EEPROM 101 that is a nonvolatile memory. The EEPROM 101 stores protection target data. Here, the protection target data is each processing device (in the example of FIG. 1, the engine processing device 100, the transport processing device 200, the image forming processing device 210, the fixing processing device 220, the controller interface processing device 400, the writing processing device 500). , Reading processing device 600, controller processing device 700, etc.), personal information of the user, unique information of image forming device 1, adjustment values, management information, machine information, and the like.
<Specific processing flow>
Next, a specific processing flow of the image forming apparatus 1 of the present embodiment will be described. FIG. 2 shows a functional configuration example of a main part of the image forming apparatus 1 of the present embodiment. In the following, as shown in FIG. 2, for simplification of explanation, a plurality of processing apparatuses constituting the image forming apparatus 1 are referred to as an engine processing apparatus 100, a conveyance processing apparatus 200, an image forming processing apparatus 210, a fixing processing apparatus 220 To do. In the following description, a processing device that stores data to be protected is referred to as a “main processing device”, and other processing devices are referred to as “sub processing devices”. In this example, since the engine processing apparatus 100 stores the protection target data in the EEPROM 101, the engine processing apparatus 100 is referred to as a “main processing apparatus”. The main processing device and the sub processing device are collectively referred to as a processing device. The engine processing apparatus 100 may be referred to as the main processing apparatus 100. The conveyance processing device 200, the image forming processing device 210, and the fixing processing device 220 will be described as “sub-processing devices”. The conveyance processing device 200, the image forming processing device 210, and the fixing processing device 220 may be referred to as the sub processing device 200, the sub processing device 210, and the sub processing device 220, respectively.

  The engine processing apparatus 100 includes an EEPROM 101 and a CPU 102. The conveyance processing apparatus 200 includes a FROM 201 and a CPU 202. The image forming processing device 210 includes a FROM 211 and a CPU 212. The fixing processing device 220 includes a FROM 221 and a CPU 222. The storage means of the main processing device 100 is the EEPROM 101, and the storage means of the sub processing devices 200, 210, and 220 are the FROMs 201, 211, and 221.

  In addition, the CPU 102 of the main processing device 100 and the CPUs 202, 212, and 222 of the sub processing devices 200, 210, and 220 respectively acquire protection target data such as travel history information that indicates its travel history. Then, the CPU 202 of the transfer processing device 200 transmits the acquired protection target data to the main processing device 100 via the communication line 2001. Further, the CPU 212 of the image forming processing device 210 transmits the acquired protection target data to the main processing device 100 via the communication line 2101. Further, the CPU 222 of the fixing processing device 220 transmits the acquired protection target data to the main processing device 100 via the communication line 2201. The CPU 102 of the main processing apparatus 100 receives the protection target data transmitted from each of the sub processing apparatuses 200, 210, and 220 via the communication line 1100 and stores the protection target data in the EEPROM 101. Further, the CPU 102 of the main processing device 100 transmits the data to be protected acquired by the CPU 102 to the EEPROM 101 via the communication line 1100 and stores it.

  FIG. 3 shows a functional configuration example of the CPU 102 of the main processing apparatus 100 according to the first embodiment and functional configuration examples of the CPUs 202, 212, and 222 included in the sub processing apparatuses 200, 210, and 220, respectively. The CPU 102 of the main processing apparatus 100 includes a communication unit 1001 and an abnormal signal transmission / reception unit 1002. Each of the sub-processing devices CPU 202, 212, and 222 includes a communication unit 1001, an abnormal signal transmission / reception unit 1002, a communication cutoff signal transmission unit 1004, a selection unit 1006, and a storage control unit 1008.

  The communication unit 1001 of the main processing device 100 communicates with the EEPROM 100 of the main processing device 100. In the communication, for example, protection target data acquired by the main processing apparatus 100 (protection target data acquired by the CPU 102 and protection target data transmitted from the sub processing apparatuses 200, 210, and 220) are stored in the EEPROM 101. Further, the communication unit 1001 of the main processing device 100 communicates with the communication unit 1001 of each of the sub processing devices 200, 210, and 220 to acquire, for example, protection target data of the sub processing devices 200, 210, and 220. . Other means will be described later.

FIG. 4 schematically shows the components of the entire image forming apparatus 1. In the example of FIG. 4, the abnormal signal transmission / reception means 1002 included in each of the CPUs 102, 202, 212, and 222 are collectively referred to as determination means 10020. Further, the communication cutoff signal transmitting means 1004 included in each of the CPUs 202, 212, and 222 of the sub-processing devices 200, 210, and 220 are collectively referred to as a communication cutoff means 10040. The selection means 1006 included in the CPUs 202, 212, and 222 of the sub-processing devices 200, 210, and 220 are collectively referred to as the selection means 10060. The storage control means 1008 included in the CPUs 202, 212, and 222 of the sub-processing devices 200, 210, and 220 are collectively referred to as storage control means 10080. FIG. 5 shows a main processing flow of the image forming apparatus of this embodiment.
<< Regarding Determination Unit 10020 (Processing in Step S1) >>
First, the determination unit 10020 will be described. As described above, the determination unit 10020 is a group of the abnormal signal transmission / reception units 1002 included in the CPUs 102, 202, 212, and 222. The abnormal signal transmission / reception means 1002 detects whether or not there is an abnormality in the processing apparatus (main processing apparatus 100, sub-processing apparatus 200, 210, 220) on which the abnormal signal transmission / reception means 1002 is mounted. When the abnormality signal transmitting / receiving unit 1002 detects the abnormality, it transmits an abnormality signal indicating the abnormality to a processing device other than its own processing device. The abnormal signal transmitting / receiving unit 1002 receives an abnormal signal transmitted from a processing device other than its own processing device. Each processing apparatus can determine whether another processing apparatus (processing apparatus other than itself) is abnormal by receiving the abnormal signal.

  That is, the abnormal signal transmitting / receiving unit 1002 of the main processing device 100 detects whether or not the main processing device 100 is abnormal, and when it is detected that the abnormality is detected, the abnormal signal is sent to all the sub-processing devices. Send to. Further, the abnormal signal transmission / reception means 1002 of the main processing apparatus 100 receives the abnormal signals transmitted from all the sub-processing apparatuses 200, 210, and 220. When the abnormal signal transmitting / receiving unit 1002 of the main processing device 100 receives the abnormal signal, it determines that the sub-processing device that has transmitted the abnormal signal is abnormal.

  Further, the abnormal signal transmission / reception means 1002 of the sub-processing device 200 detects whether or not the sub-processing device 200 is abnormal. When it is detected that the abnormality is detected, the abnormal signal is sent to the main processing device 100 and , To the sub-processing devices 210 and 220 other than itself. The abnormal signal transmitting / receiving unit 1002 of the sub-processing device 200 receives an abnormal signal transmitted from the main processing device 100 and the sub-processing devices 210 and 220 other than itself. When the abnormal signal transmitting / receiving unit 1002 of the sub-processing device 200 receives the abnormal signal, it determines that the main processing device 100 or the sub-processing device that has transmitted the abnormal signal is abnormal. The same applies to the processing of the abnormal signal transmission / reception means 1002 of the other sub-processing devices 210 and 220. In this way, the determination unit 10020 determines whether each of the main processing device and the plurality of sub processing devices is normal or abnormal (step S1).

By the way, generally, when a certain processing apparatus transmits an abnormal signal, there may actually be a cause of abnormality in a processing apparatus other than the processing apparatus. For example, it is assumed that the abnormal signal transmitting / receiving unit 1002 included in the fixing processing device 220 detects an abnormal temperature of the heater 810 (see FIG. 1) connected to the fixing processing device 220. Then, it is assumed that there is the following cause in the abnormality of the heater.
“The CPU 102 of the engine processing apparatus 100 has run out of control and cannot be controlled.”
“A function of the fixing processing device 220 has failed”
“The image forming apparatus 210 performed an unexpected operation.”
Therefore, in the present embodiment, a table as shown in FIG. 6 is held in advance in all the abnormal signal transmitting / receiving means 1002. The table shown in FIG. 6 is a table in which a processing device that has transmitted an abnormal signal is associated with a processing device that may be abnormal. In the first embodiment, when the abnormal signal transmission / reception unit 1002 detects an abnormality, the processing apparatus having the possibility of abnormality is recognized with reference to the table of FIG. As described above, when the abnormality signal transmission / reception means 1002 included in the fixing processing apparatus 220 detects an abnormality in the heater 810, the abnormality signal transmission / reception means 1002 refers to the engine processing apparatus 100 (the main processing apparatus 100). ), It is determined that there is a possibility of abnormality in the image forming processing device 210 and the fixing processing device 220, and it is determined that the transport processing device 100 is normal.

The abnormal signal transmitting / receiving unit 1002 of the fixing processing device 220 determined to be abnormal transmits an abnormal signal indicating that it is abnormal to the conveyance processing device 100 determined to be normal. The conveyance processing apparatus 200 that has received the abnormality signal recognizes that there is a possibility of abnormality in the engine processing apparatus 100, the image forming processing apparatus 210, and the fixing processing apparatus 220. As described above, in this embodiment, it is assumed that the “processing device having an abnormality” includes not only “a processing device that actually has an abnormality” but also “a processing device that may be abnormal”. In this example, the determination unit 10020 determines that only the transfer processing device 200 is normal.
<< Communication blocking means 10040 (step S4) >>
Next, the communication blocking means 10040 will be described. As described above, the communication cut-off means 10040 is a collection of the communication cut-off signal transmission means 1004 included in the CPU of each sub-processing device. When the determination unit 10020 determines that the main processing device 100 is abnormal and one or more sub-processing devices are normal (Yes in step S2), the communication unit 1001 of the main processing device 100 communicates with the EEPROM 101. Shut off. (Step S4). In this example, it is determined that the engine processing device 100 (main processing device) is abnormal, the image forming processing device 210 and the fixing processing device 220 (one or more sub-processing devices) are determined abnormal, and the conveyance processing device 200 (one or more). In step S2, “Yes” is determined.

  Next, two reasons for blocking the communication in step S4 will be described. As a first reason, in step S7 to be described later, the protection target data stored in the main processing device 100 determined to be abnormal is stored in the sub processing device (here, the transport processing device 200) determined to be normal. ) And stored in the FROM 201. That is, the storage control unit 2006 of the transport processing apparatus 200 requests (accesses) the protection target data from the EEPROM 101 and acquires the protection target data stored in the EEPROM 101.

  Here, if the processing for requesting data to be protected is performed without interrupting the communication between the communication unit 1001 of the main processing device 100 determined to be abnormal and the EEPROM 101, it is abnormal from the communication unit 1001 of the main processing device 100. There is a possibility that the communication signal is transmitted to the communication line 1100 and the communication line 1100 is short-circuited. This is because if the communication line 1100 is short-circuited, the storage control unit 2006 of the transfer processing device 200 cannot appropriately access the EEPROM 101.

  The second reason is that, as described above, the communication unit 1001 of the main processing device 100 transmits the data to be protected acquired by the main processing device 100 to the EEPROM 101 for storage, but it is abnormal. This is because there is a possibility that the protection target data that is abnormal may be transmitted from the determined communication means 1001 of the main processing apparatus 100. If it is determined that the main processing apparatus 100 is abnormal for these two reasons, the communication between the communication means 1001 in the main processing apparatus 100 and the EEPROM 101 is cut off.

  Next, communication interruption by the communication interruption means 10040 will be described with reference to FIG. FIG. 7 shows a main part of the first embodiment, showing the main processing device 100 and the sub-processing device (conveying processing device 200) determined to be normal, and the image forming processing device 210 and fixing that are determined to be abnormal. Description of the processing device 220 is omitted. In the example of FIG. 7, a communication line 1100 for communication means 1001 in the CPU 102 to communicate with the EEPROM 101 (for transmitting data to be protected) is provided. Further, a communication line 2001 is provided for communication means 1001 in the CPU 202 to communicate with the communication means 1001 in the CPU 102 and the EEPROM 101.

  In the example of FIG. 7, the main processing apparatus 100 is provided with a switch 1120. The switch 1120 is provided in the middle of the communication line 1100. The switch 1120 can be opened and closed. The switch 1120 is opened and closed when a communication cut-off signal is transmitted. For example, when the transmitted communication cut-off signal is a Low signal, the switch 1120 is opened and the communication line is cut off. When the transmitted communication cutoff signal is a high signal, the switch 1120 is closed and the communication line is in a communicable state.

  Further, a cutoff signal line 2002 through which a communication cutoff signal transmitted from the communication cutoff signal transmission unit 1004 of the CPU 202 passes is provided. Then, the communication cutoff signal transmission unit 1004 included in the sub-processing device determined to be normal (in this example, the transport processing device 200) transmits a communication cutoff signal to the switch 1120, opens the switch 1120, and opens the CPU 102. Communication between the communication means 1001 and the EEPROM 101 can be cut off. The communication cutoff signal is also input to the CPU 102, and the CPU 102 can recognize that the communication cutoff signal has been transmitted.

As described above, the main processing apparatus 100 is abnormal by providing the switch 1120 in the main processing apparatus 100 capable of forcibly blocking or non-blocking communication between the communication means 1001 in the CPU 102 and the EEPROM 101. Even if it is determined, communication between the communication means 1001 in the CPU 102 and the EEPROM 101 can be forcibly cut off. When the blocking is performed, the storage control unit 1008 of the conveyance processing apparatus 200 determined to be normal is in a state in which communication with the EEPROM 101 is possible.
<< Regarding Selection Unit 10060 (Step S6) >>
Next, the selection unit 10060 will be described. As described above, the selection means 10060 is a collection of the selection means 1006 included in the CPU of each sub-processing device. The selection unit 10060 selects a sub-processing device to be stored from one or more sub-processing devices determined to be normal (step S6). Here, since the sub-processing apparatus determined to be normal is only the transport processing apparatus 200, the selection unit 1006 selects the sub-processing apparatus to be stored as the transport processing apparatus 200. A case where there are two or more sub-processing devices determined to be normal will be described in a fourth embodiment.
<< Storage Control Unit 10080 (Step S7) >>
Next, the storage control unit 10080 will be described. As described above, the storage control unit 10080 includes the storage control unit 1008 included in the CPU of each sub-processing device. In this embodiment, the storage control unit 10080 stores the protection target data stored in the main processing device in the storage target sub processing device selected by the selection unit 10060 (the sub processing device determined to be normal). Transfer and store (save) (step S7). In this example, the conveyance processing apparatus 200 is the only sub-processing apparatus determined to be normal. The storage control unit 1008 of the conveyance processing apparatus 200 determined to be normal transmits a request signal for requesting the protection target data to the EEPROM 101, and acquires the protection target data stored in the EEPROM 101. . Then, the storage control unit 1008 stores the data in the FROM 201 included in the processing apparatus (conveyance processing apparatus 200) in which the storage control unit 1008 is provided. In this manner, the protection target data saving process (protection target data backup process) of the storage control unit 1008 is completed.

  When the migration storage process of the protection target data is completed, the communication cutoff signal transmission unit 1004 of the transport processing apparatus 200 determined to be normal returns the blocked location (step S8). Specifically, the communication cutoff signal transmission unit 1004 transmits a communication cutoff signal (High signal) for closing the opened switch 1120 to the switch 1120. Thereby, the blocked | interrupted location can be returned. Then, a service person or the like performs replacement work for the main processing device 100 or the sub processing device in which an abnormality has occurred.

In the case of the image forming apparatus 1 (electronic device) according to the first embodiment, even if, for example, the communication line 1100 between the CPU 102 and the EEPROM 101 is short-circuited due to an abnormality of the main processing apparatus 100 (Yes in step S2). The communication between the CPU 102 and the EEPROM 101 can be appropriately cut off (step S4). Then, the protection target data is stored in the FROM of the sub-processing device determined to be normal (steps S6 and S7). Therefore, even if it is determined that the processing apparatus 100 is abnormal, the protection target data can be appropriately saved and protected. Further, even if the main processing apparatus determined to be abnormal is replaced, the possibility that the protection target data can be restored can be increased.
[Embodiment 2]
Next, the image forming apparatus 1-2 according to the second embodiment will be described. In the second embodiment, a sub-processing device (in the first embodiment, the image forming processing device 210 and the fixing processing device 220) that is determined to be abnormal by the determination unit 10020 will be described. FIG. 8 illustrates a functional configuration example of a main part of the image forming apparatus 1-2 according to the second embodiment. In FIG. 8, compared to FIG. 7, an image forming processing device 210, switches 2003, 2103, and the like are added. A communication line 2101 and a blocking signal line 2102 are provided from the CPU 212 of the image forming processing device 210. The communication unit 1001 of the CPU 212 communicates with the CPU 102 and the EEPROM 101 using the communication line 2101.

  In FIG. 8, the switch 2003 is provided in the middle of the communication line 2001, and the switch 2103 is provided in the middle of the communication line 2101. Each of the switches 2003 and 2103 can be opened and closed. The switch is opened and closed by transmitting a communication cutoff signal.

  Further, a cutoff signal line 2002 is provided for the communication cutoff signal transmitted from the communication cutoff signal transmission unit 1004 of the CPU 202 to reach and open and close the switches 1120 and 2103. Further, a cutoff signal line 2102 is provided for the communication cutoff signal transmitted from the communication cutoff signal transmission means 1004 of the CPU 212 to reach and open and close the switches 1120 and 2003.

  FIG. 9 shows a processing flow of the image forming apparatus 1-2 according to the second embodiment. 9 is compared with FIG. 5, step S2 and step S4 are replaced with step S11 and step S12, respectively. In step S11, it is determined whether or not the result of the determination process by the determination unit 10020 in step S1 is that the main processing device and the one or more sub processing devices are abnormal and the one or more sub processing devices are normal. In this example, the main processing device 100 and the two sub processing devices (image forming processing device 210, fixing processing device 220) are abnormal, and one sub processing device (conveying processing device 200) is normal. S11 is determined as Yes.

  Next, the communication blocking unit 10040 blocks communication between the communication unit 1001 of the main processing device 100 and the EEPROM 101, and communication unit of the sub-processing device (image forming processing device 210, fixing processing device 220) determined to be abnormal. Communication between 1001 and the EEPROM 101 is cut off (step S12). Specifically, the communication cutoff signal transmission unit 1004 included in the sub-processing device determined to be normal (in this example, the transport processing device 200) transmits a communication cutoff signal to the switch 1120 and the switch 2103. Then, the switch 1120 and the switch 2103 are opened. By opening the switch 1120 and the switch 2103, the communication between the communication unit 1001 of the main processing device 100 and the EEPROM 101 is cut off, and the communication of the sub processing device (the image forming processing device 210 and the fixing processing device 220) determined to be abnormal is performed. Communication between the means 1001 and the EEPROM 101 can be cut off. In addition, the communication cutoff signal transmission unit 1004 of the sub-processing devices 210 and 220 determined to be abnormal does not transmit a communication cutoff signal because it may transmit an abnormal communication cutoff signal.

  Next, two reasons for blocking the communication in step S12 will be described. As a first reason, in step S7 to be described later, the protection target data stored in the main processing device 100 determined to be abnormal is stored in the sub processing device (here, the transport processing device 200) determined to be normal. ) And stored in the FROM 201. That is, the storage control unit 2006 of the transfer processing device 200 requests (accesses) the EEPROM 101 and acquires the protection target data stored in the EEPROM 101.

  Here, if the processing for requesting protection target data is performed without interrupting communication between the communication means 1001 of the sub-processing device determined to be abnormal and the EEPROM 101, the communication means 1001 of the sub-processing device determined to be abnormal This is because an abnormal communication signal (such as abnormal travel history information) is transmitted to the communication line 1100 and the storage control unit 2006 of the transport processing device 200 cannot properly access the EEPROM 101.

  The second reason is that, as described above, the communication means 1001 of all the sub-processing devices transmits and stores the travel history information acquired by the main processing device 100 to the EEPROM 101, which is abnormal. This is because there is a possibility that abnormal travel history information may be transmitted from the communication means 1001 of the sub-processing device that is determined to be. If it is determined that one or more sub-processing devices are abnormal due to these two reasons, the communication between the communication means 1001 and the EEPROM 101 in the sub-processing devices 210 and 220 determined to be abnormal is interrupted.

  As described above, by providing the switches 2003 and 2103 capable of blocking or non-blocking communication between the communication means 1001 and the EEPROM 101 in each of the sub-processing devices 200 and 210, the sub-processing device determined to be abnormal. Communication between the communication means 1001 200 and 210 and the EEPROM 101 can be forcibly cut off. That is, the interruption of the communication means that the communication from the communication unit 1001 of each of the main processing device 100 and the sub processing devices 200 and 210 determined to be abnormal is interrupted. When the interruption is performed, only the storage control unit 1008 of the conveyance processing apparatus 200 determined to be normal is in a state where the EEPROM 101 can be accessed.

  Further, the communication cut-off signal may cut off communication between all the sub-processing devices other than the self-processing device and the main processing device.

  Since the processes in steps S6 and S7 are the same as those in the first embodiment, description thereof is omitted. In step S8, the communication cutoff signal transmission unit 1004 of the sub-processing device 200 determined to be normal transmits a communication cutoff signal to the switches 2103 and 1120 opened in step S4, thereby the switches 2103 and 1120. Close the switch.

In the case of the image forming apparatus 1 (electronic device) according to the second embodiment, when it is determined that the main processing device, one or more sub-processing devices are abnormal, and one or more sub-processing devices are normal ( In step S11, the communication between the communication unit 1001 of the main processing device 100 and the EEPROM 102 and the communication between the communication unit 1001 of one or more sub-processing devices determined to be abnormal and the EEPROM 102 are blocked (step S12). Thereafter, the protection target data is stored in the FROM of the sub-processing device determined to be normal. Therefore, even if one or more sub-processing devices are determined to be abnormal and, for example, the communication lines 1100, 2101 and 2201 are short-circuited, the protection target data can be appropriately protected.
[Embodiment 3]
Next, the image forming apparatus 1-3 of Embodiment 3 will be described. The main processing apparatus 100 of the image forming apparatus 1-3 has power supply means (for example, 5V power supply). The power supply means supplies power to the EEPROM 101 to operate the EEPROM 101. If the main processing apparatus 100 becomes abnormal, for example, the harness may be disconnected. In this case, the power is not properly supplied to the EEPROM 101, and there is a case where malfunction occurs such that the data to be protected in the EEPROM 101 is erased or converted into different data. Therefore, in the third embodiment, even when the main processing apparatus 100 becomes abnormal, if there are one or more normal sub-processing apparatuses, the power supply means included in the normal sub-processing apparatus supplies power to the EEPROM 101. To do.

  FIG. 10 illustrates a functional configuration example of the CPU 102 of the main processing device 100 and the CPUs 202, 212, and 222 of the sub processing device according to the third embodiment. In the example of FIG. 10, the CPU 102 of the main processing device is the same as that in the first embodiment. In the example of FIG. 10, the functional configuration example of the CPUs 202, 212, and 222 of the sub-processing device is different from that of FIG. 3 in that a power cutoff signal transmission unit 1010 and a power supply control unit 1012 are added. FIG. 11 shows a functional configuration example of the image forming apparatus 1-3 according to the third embodiment. Compared with FIG. 4, it is different in that a power shut-off means 10100 is added. The power cut-off means 10100 is a collection of power cut-off signal transmission means 1010 included in the CPUs of the sub-processing devices.

  FIG. 12 shows a functional configuration example of a main part of the image forming apparatus 1-3 according to the third embodiment. In the following description, the determination result of the determination unit 10020 determines that the main processing device 100, the image forming processing device 210, and the fixing processing device 220 are abnormal and the conveyance processing device 200 is normal, as in the first and second embodiments. The case will be described. The communication line 2001, the cutoff signal line 2002, the power supply line 2005, and the GND line 2004 are connected to the port 230 included in the transport processing apparatus 200 and the port 130 included in the main processing apparatus 100. Although not shown, the communication line 2001, the cut-off signal line 2002, the power supply line 2005, and the GND line 2004 are similarly sent from the CPUs of other sub-processing devices (the image forming processing device 210 and the fixing processing device 220). Are wired and connected to the port 130.

  Further, the main processing apparatus 100 is provided with a power supply means 120 and a GND 130. In the example of FIG. 12, the power supply means 120 is a 5V power supply 120. The power from the 5V power source 120 is supplied to the EEPROM 101 through the power line 1102. The EEPROM 101 operates by supplying the power. A switch 1122 is provided in the middle of the power line 1102. The switch 1122 can be opened and closed. When the switch 1122 is open, the supply of power from the 5V power source 120 to the EEPROM 101 is cut off. When the switch 1122 is closed, the power from the 5V power source 120 is supplied to the EEPROM 101.

  Further, power from the power outlet 302 is supplied to the PSU 300. Power is supplied from the PSU 300 to each processing apparatus. In the example of FIG. 12, for simplification of the drawing, it is described that power is supplied only from the PSU 300 to the transport processing device 200 and the main processing device 100. The image processing apparatus 210 and the fixing processing apparatus 220) are also supplied with power. In each processing apparatus, 5 V power is supplied from the PSU 300 via the 5 V power line 303 and grounded via the GND line 304.

  FIG. 13 shows a processing flow of the image forming apparatus 1-2 according to the third embodiment. FIG. 13 shows a processing flow of the image forming apparatus 1-2. Compared to FIG. 5, the difference is that the processing of step S14 and step S16 is added. When the processes of steps S1 and S2 are completed, the process proceeds to steps S4 and S14. Since the process of step S4 is as described above, the description thereof is omitted. In step S14, the power shutoff means 10100 shuts off the power supply from the power supply control means 1012 of the main processing apparatus 100 to the EEPROM 101 (step S14).

  In the example of FIG. 12, as the power shut-off means 10100, the power shut-off signal transmitting means 1010 of the sub-processing apparatus (in this example, the transport processing apparatus 200) determined to be normal sends a power shut-off signal to the switch 1122. Send. The power cutoff signal is a signal for cutting off or not cutting off the power supply from the 5V power source 120 to the EEPROM 101. The switch 1122 is opened by the power shutoff signal. Then, the supply of the 5V power source 120 to the EEPROM 101 is cut off. By this interruption, malfunction of the EEPROM 101 can be prevented. In the description of FIG. 12, the communication cutoff signal (signal input to the switch 1120) and the power cutoff signal (signal input to the switch 1122) are transmitted through the same cutoff signal line 2002 for simplification of the drawing. In practice, the communication cutoff signal line for the communication cutoff signal and the power cutoff signal line for the power cutoff signal are provided separately.

  In step S6, a sub-processing device to be stored is selected. Then, the power supply control unit 1012 included in the selected sub-processing device (in this example, the transport processing device 200) supplies power to the EEPROM 101 (step S16). By supplying the power, normal power is supplied to the EEPROM 101, the EEPROM 101 operates properly, and the protection target data in the EEPROM 101 is appropriately protected. The power supply control means 1012 may supply power to the EEPROM 101 by citing the power supply of the PSU. Further, a 5V power supply 120 may be installed in each sub-processing device, and the power supply control unit 1012 may supply the EEPROM 101 with the power of the installed 5V power supply 120. And the process of step S7 and step S8 is performed.

According to the image forming apparatus 1-3 of the third embodiment, when the main processing apparatus 100 becomes abnormal, the power supply to the EEPROM 101 in the main processing apparatus 100 is shut off (step S14). Then, the power supply means of the sub-processing device determined to be normal supplies power to the EEPROM 101. Therefore, even when the main processing apparatus 100 becomes abnormal, the protection target data stored in the EEPROM 101 can be appropriately protected without causing the EEPROM 101 to malfunction.
[Embodiment 4]
Next, an image forming apparatus 1-4 according to Embodiment 4 will be described. In the first and second embodiments, the case where there is one sub-processing device determined to be normal (that is, only the conveyance processing device 200 is normal) has been described. However, there may be two or more sub-processing devices that are determined to be normal. In the fourth embodiment, even when there are two or more sub-processing devices determined to be normal, the selection unit 10060 can appropriately select a sub-processing device to be stored.

  In the fourth embodiment, priorities of a plurality of sub-processing devices are determined in advance. For example, in the example of FIG. 14, the image processing unit 210, the transport processing device 200, and the fixing processing device 220 are prioritized. The priority order may be determined according to the amount of storage capacity of the FROM included in each sub-processing device, for example. In the example of FIG. 14, the storage capacity of the FROM 211 of the image forming apparatus 210> the storage capacity of the FROM 201 of the conveyance processing apparatus 200> the storage capacity of the FROM 221 of the fixing processing apparatus in the large storage capacity of the FROM. The table shown in FIG. 14 is stored in advance in the FROM of each sub-processing device.

  In step S2 of FIG. 3, it is assumed that the determination unit 10020 determines that the image forming processing device 210 and the fixing processing device 220 are normal. In this case, the selection unit 10060 selects the sub-processing device to be stored as the image forming processing device 210 with reference to the priority order of FIG. Based on this priority order, the selection unit 10060 selects the sub-processing device to be stored, so that the protection target data can be protected more appropriately.

  Further, when there are two or more sub-processing devices determined to be normal, one sub-processing device may be selected at random from the two or more sub-processing devices without using the priority order.

According to the image forming apparatus of the fourth embodiment, even when it is determined that there are a plurality of normal sub-processing devices, it is possible to appropriately select the storage-target sub-processing device and appropriately protect the protection target data. I can do it.
[Embodiment 5]
Next, the image forming apparatus 1-5 of Embodiment 5 will be described. The determination unit 10020 according to the first embodiment has been described as including the abnormal signal transmission / reception unit 1002 included in each of the main processing device and the sub processing device as illustrated in FIG. However, when the main processing device or the sub processing device becomes extremely abnormal, the abnormal signal transmitting / receiving unit 1002 of the main processing device or the sub processing device that has become extremely abnormal may not be able to transmit an abnormal signal. is there. In the image forming apparatus 1-5 of the fifth embodiment, the main processing apparatus 100 or the sub-process appropriately determined to be abnormal even if the processing apparatus becomes extremely abnormal such that it cannot transmit the abnormal signal. The device can be determined.

  FIG. 15 illustrates a functional configuration example of the CPU 102-4 of the main processing apparatus 100 according to the fifth embodiment and functional configurations of the CPUs 202-4, 212-4, and 222-4 of the sub processing apparatus. Compared with FIG. 3, the abnormality signal transmitting / receiving unit 1002 is different from the normal signal transmitting / receiving unit 1020. Further, the determination unit 10200 of the fifth embodiment includes a normal signal transmission / reception unit 1020 provided in each of the CPUs of the main processing device 100 and the sub processing devices 200, 210, and 220.

  When it is determined that the processing apparatus on which the normal signal transmission / reception means 1020 is mounted is normal, the normal signal transmission / reception means 1020 indicates that the normal signal transmission / reception means 1020 is normal with respect to other processing apparatuses every predetermined time. The normal signal shown is transmitted. In more detail, the transmission of the normal signal is to write a normal signal into an arbitrary register in the FROM of another processing apparatus, and the normal signal is, for example, H′20. Further, the normal signal transmitted from the normal signal transmitting / receiving means 1020 included in the other processing apparatus is received.

  That is, the normal signal transmitting / receiving unit 1020 of the main processing device 100 sends a normal signal to all the sub-processing devices 200, 210, and 220 every predetermined time when it is determined that the main processing device 100 is normal. To send. The normal signal transmission / reception means 1020 of the main processing device 100 receives normal signals from the sub processing devices 200, 210, and 220. Further, the normal signal transmitting / receiving means 1020 of the sub processing device 200 sends a normal signal to the main processing device 100 and the sub processing devices 210 other than itself when the sub processing device 200 is determined to be normal. , 220 transmits a normal signal. Further, the normal signal transmitting / receiving means 1020 of the sub-processing device 200 receives normal signals from the main processing device 100 and the sub-processing devices 210 and 220 other than itself. The same processing is performed for the normal signal transmission / reception means 1020 of the sub-processing devices 210 and 220.

  Then, each of the main processing device 100 or the sub processing devices 200, 210, and 220 determines that the processing device that has not transmitted the normal signal is abnormal. In addition, when a processing device that is determined to be abnormal is detected, the processing device that may be abnormal may be determined using the table shown in FIG.

In the case of the image forming apparatus 1-5 according to the fifth embodiment, the determination unit 10200 can determine the processing apparatus that has been determined to be abnormal even when the abnormality is so great that an abnormal signal cannot be transmitted. I can do it.
[Embodiment 6]
Next, the image forming apparatus 1-6 of Embodiment 6 will be described. In the fourth embodiment, the case where there are two or more sub-processing devices determined to be normal has been described. In the first embodiment, it has been described that the communication cut-off signal is preferably transmitted by the communication cut-off signal transmission unit 1004 of the sub-processing device determined to be normal. In the sixth embodiment, even when there are two or more sub-processing devices determined to be normal, any one communication cutoff signal among the two or more sub-processing devices determined to be normal The transmission unit 1004 transmits a communication cutoff signal. Any one of them is selected by the selection means 10060.

  If there are two or more sub-processing devices determined to be normal, if each of the communication cut-off signal transmitting means 1004 included in the two or more sub-processing devices transmits a communication cut-off signal, it is normal. The storage control unit 10080 of the sub-processing device determined to be unable to access the EEPROM 101 arises. For example, when the sub-treatment devices determined to be normal are the conveyance processing device 200 and the image forming processing device 210, the communication cutoff signal transmission means 1004 of each of the conveyance processing device 200 and the image forming processing device 210 blocks communication. Suppose a signal is transmitted. In this case, both the communication between the storage control unit 1008 of the transport processing device 200 and the EEPROM 101 and the communication between the storage control unit 1008 of the image forming processing device 210 and the EEPROM 101 are blocked. As a result, neither the transfer processing device 200 nor the image forming processing device 210 can acquire the protection target data in the EEPROM 101.

  Therefore, in the sixth embodiment, when there are two or more sub-processing devices determined to be normal, the communication cutoff signal transmission unit 1004 of any one of the sub-processing devices selected by the selection unit 10060 Send a signal. Moreover, it is preferable that the cutoff signal lines (2002 and 2102 in FIG. 8) from the sub-processing device are connected so that they can be transmitted to the CPU of the sub-processing device other than itself. With this configuration, when the CPU of the sub-processing device receives the communication cut-off signal, it can recognize that the sub-processing device other than itself has transmitted the communication cut-off signal. As a result, it is possible to prevent the communication cut-off signal from being transmitted from the communication cut-off signal transmitting means 1004 in its own CPU.

According to the image forming apparatus of the sixth embodiment, when there are two or more sub-processing devices determined to be normal, the cutoff signal 1004 of any one sub-processing device is transmitted. Accordingly, it is possible to avoid the problem that any of the two or more sub-processing devices determined to be normal cannot access the EEPROM 101.
[Embodiment 7]
Next, the image forming apparatus 1-7 of Embodiment 7 will be described. FIG. 17 shows a processing flow of the image forming apparatus 1-7 according to the seventh embodiment. In FIG. 17, compared to FIG. 3, step S <b> 7 is replaced with step S <b> 30, and steps S <b> 31, 32, and 34 are added.

  After the processing of step S6 is completed, in step S30, the storage control unit 10080 of the transport processing device 200 (sub-processing device determined to be normal) stores the protection target data in the FROM 201 of the transport processing device 200. However, backup information is also stored together with the protection target data. The backup information is information indicating that it is stored in the FROM 201.

  Then, after the end of step S8, the service processor or the like replaces the main processing device 100 determined to be abnormal or the sub-processing device determined to be abnormal, but the service man or the like replaces the main process after the replacement. All H′FFs (all bits are “1”) are written in the EEPROM 101 of the apparatus. That is, “0” and “1” are written as protection target data in the EEPROM 101 before the replacement, whereas all “1” are written in the EEPROM 101 after the replacement. Therefore, the CPUs of all the sub-processing devices 200, 210, and 220 can recognize whether or not the EEPROM 101 has been replaced by communicating with the EEPROM 101 (step S31).

  If the storage control unit 10080 of all the sub-processing devices 200, 210, and 220 recognizes that the EEPROM 101 has been replaced (Yes in step S31, that is, if all the bits of the EEPROM 101 are “1”), Each of the storage control means 10080 of all the sub-processing devices confirms whether backup information is stored in its own FROM (step S32). In the above example, it is the transport processing device 200 that has the FROM storing the backup information among all the sub-processing devices. Accordingly, the storage control unit 10080 of the transport processing apparatus 200 returns the protection target data stored (backed up) in the FROM 201 of the transport processing apparatus 200 to the EEPROM 101 and stores it in the EEPROM 101. In this way, the saved protection target data can be returned to the EEPROM 101.

According to the image forming apparatus 1-7 of the seventh embodiment, backup information is stored in the FROM together with the saved protection target data. Therefore, the storage control unit 1008 of the sub-processing device provided with the FROM in which the backup information is stored causes the protection target data stored (saved) in the FROM to be stored in the EEPROM 101 (returned to the EEPROM 101). . Therefore, the saved protection target data can be stored in the EEPROM 101, and the protection target data can be appropriately protected.
[Embodiment 8]
Next, an image forming apparatus 1-8 according to the eighth embodiment will be described. In the image forming apparatus 1-7 according to the eighth embodiment, a layout of the switches 1120 and 1122 of the main processing apparatus 100 illustrated in FIG. In the eighth embodiment, in order to appropriately protect the data to be protected stored in the EEPROM 101, the distance between the switches 1120 and 1122 and the EEPROM 101 is set to a predetermined value r or less. Here, the predetermined value r is a distance that prevents other wirings, modules, and the like that affect the protection target data stored in the EEPROM 101 from being arranged around the EEPROM 101. Thus, by setting the distance between the switches 1120 and 1122 and the EEPROM 101 to be equal to or less than the predetermined value r, it is possible to avoid the problem of affecting the protection target data stored in the EEPROM 101.

According to the eighth embodiment, the protection target data can be appropriately protected by not arranging the member that affects the protection target data stored in the EEPROM 101.
[Other Embodiments]
As other embodiments, the determination means 10020, the communication interruption means 10040, the selection means 10060, the storage control means 10080, the power supply interruption means 10100, and the determination means 10200 shown in FIGS. 4, 11, and 16 are individually (for example, shown in FIG. The controller processing apparatus 700 shown in FIG.

  2, 7, 8, and 12, the case where the communication method between the main processing device 100 and another sub-processing device is serial communication has been described. As another communication method, I2C communication or the like may be used. I2C communication is communication in which data is exchanged with an SDA signal and a clock is exchanged with an SCL signal. Further, parallel communication different from I2C communication may be used.

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 100 Engine processing apparatus 101 EEPROM
102 CPU
200 Conveying processing device 201 FROM
202 CPU
210 Image forming processing apparatus 211 FROM
212 CPU
220 Fixing processing device 221 FROM
222 CPU
1001 Communication means 1002 Abnormal signal transmission / reception means 1004 Communication cutoff signal transmission means 1006 Selection means 1008 Storage control means 1010 Power supply cutoff signal transmission means 1012 Power supply means 1020 Normal signal transmission / reception means 10020 Determination means 10040 Communication cutoff means 10060 Selection means 10080 Storage control means 10100 Power-off means

JP 2006-259869 A

Claims (6)

A storage unit storing data to be protected, a main processing device having a communication unit capable of communicating with the storage unit,
An electronic device including one or more sub-processing devices,
Determining means for determining whether each of the main processing device and the one or more sub-processing devices is normal or abnormal;
When the determination unit determines that the main processing device is abnormal and at least one of the one or more sub processing devices is normal, the communication unit and the storage unit Communication blocking means for blocking the communication of,
Selecting means for selecting any one of the at least one sub-processing device determined to be normal;
When communication is interrupted by the communication interrupting means, said secondary processing apparatus selected by said selecting means, have a, a storage control means for storing the protected data in which the main processor is stored,
There are a plurality of the sub-processing devices, and each of the plurality of sub-processing devices has communication means capable of communicating with the storage means,
In the communication blocking means, the determination means determines that the main processing device is abnormal, at least one of the plurality of sub processing devices is abnormal, and among the plurality of sub processing devices, When it is determined that at least one of the sub-processing devices is normal, communication between the communication unit and the storage unit included in the at least one sub-processing device determined to be abnormal is also cut off.
The communication blocking means is
Including a blocking signal transmission means included in each of the one or more sub-processing devices,
The one or more sub-processes determined to be abnormal by the cutoff signal transmitting unit included in the sub-processing device selected by the selection unit transmitting a cutoff signal to the main processing unit. An electronic apparatus that cuts off communication between the apparatus and the main processing apparatus . A storage unit storing data to be protected, a main processing device having a communication unit capable of communicating with the storage unit,
An electronic device including one or more sub-processing devices,
Determining means for determining whether each of the main processing device and the one or more sub-processing devices is normal or abnormal;
When the determination unit determines that the main processing device is abnormal and at least one of the one or more sub processing devices is normal, the communication unit and the storage unit Communication blocking means for blocking the communication of,
Selecting means for selecting any one of the at least one sub-processing device determined to be normal;
Storage control means for storing the protection target data stored in the main processing device in the sub-processing device selected by the selection means when communication is cut off by the communication blocking means;
The main processing device has power supply means for supplying power to the storage means,
Each of the one or more sub-processing devices has power supply means capable of supplying power to the storage means,
In the electronic apparatus, when the determination unit determines that the main processing device is abnormal and at least one of the one or more sub processing devices is normal, the main processing device A power cutoff means for shutting off the supply of the power to the storage means by the power supply means included in the apparatus;
When the power supply is cut off by the power cut-off means, the power supply means included in the sub-processing device selected by the selection means supplies the power to the storage means. that electronic devices be. 3. The electronic device according to claim 1, wherein a member that affects the protection target data stored in the storage unit is not disposed around the storage unit. The selecting means selects one of the at least one sub-processing device determined to be normal based on a predetermined priority order of the one or more sub-processing devices. The electronic device according to any one of claims 1 to 3, wherein The determination means includes
A normal signal transmission / reception means included in each of the main processing device and the one or more sub processing devices,
The normal signal transmitting / receiving means included in the main processing device transmits a normal signal to the one or more sub processing devices every predetermined time when the main processing device is normal,
The normal signal transmitting / receiving means included in the one or more sub-processing devices transmits the sub-processing device to the main processing device and the sub-processing devices other than the self every predetermined time when the sub-processing device is normal.
The electronic device according to any one of claims 1-4, wherein not transmitting a normal signal the main processor or the sub-processing unit, characterized in that it is determined to be abnormal. It said storage control means, the protection storage unit having stored object data, according to claim 1-5 electronic device according to any one, characterized in that to back up the information also stored indicating that is the storage.

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